Pollution Science 101 
                                            Solutions


                                                    By Michael J. Ross

 

                                Http://MonsantoInvestigation.com

 

                                         PollutionScience.com 
 

                                           Published: August 23rd, 2025

 

                                 Last update: August 23rd, 2025 5:45 AM

 

                                                   Under Construction 

                                       
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{New} Pollution Science X - Solutions (Florida) - (Pollution Science 101 - Solutions (Florida)

July 17th, 2024

https://pollutionscience101florida.blogspot.com

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Chapters:

Chapter 1: Dyeing technology
Chapter 2: Armor technology
Chapter 3: Materials & fibers 

Chapter 4: Sustainable Paints & coatings
Chapter 5: Plastics & Polymer technology
Chapter 6: Conductivity in polymers and rubbers
Chapter 7: Strongest fibers & materials
Chapter 8: Glass technology
Chapter 9: Light Energy

Chapter 10: Tesla Coils
Chapter 11: CERN
Chapter 12: Antimatter
Chapter 13: Plasma energy 
Chapter 14: Fusion    
Chapter 15: Batteries & energy storage
Chapter 16: Magnetic energy
Chapter 17: Piezoelectric & mechanical energy
Chapter 18: Lazers 
Chapter 19: Solar, Electrical & Hydrogen power
Chapter 20: Green computing
Chapter 21: Chips, Wires & Wafers
Chapter 22: Nature & energy
Chapter 23: Wind energy
Chapter 24: Air power
Chapter 25: Transportation
Chapter 26: Alternative fuel
Chapter 27: Biofuel
Chapter 28: Sustainable Lubricants
Chapter 29: Displays
Chapter 30: Water harvesting & Carbon
Chapter 31: Refrigeration
Chapter 32: Vertical & sustainable farming methods
Chapter 33: Clean-up technology
Chapter 34: Toxic clean-up technology

Chapter 35: Adhesives 



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Intro:


Today, we have an abundance of science and technology. It seems that for many of the problems that we have as a civilization, such as war, famine, hunger, pollution and disease. That we can solve many of these concerns. In this series, we will dedicate the learning of science and technology, to many of the potential benefits of technology. This includes how these technologies can be misused in our civilization.


We can already see the amount of landfills and pollution being caused by different types of industrial activities, including the use of machinery and technology. This includes many toxic chemicals, being produced daily. Many industrial chemicals, are not often correctly disposed. These chemicals are a hazard to the environment, including in landfills. This book will talk about new and sustainable ways to replace and phase-out, many toxic and industrial chemicals.

With all of the technology that has been invented in our pasts, we must ask ourselves if it is possible to make our civilization coexist with this planet.  

 

 

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{New} Pollution Science X - Solutions (Florida) - (Pollution Science 101 - Solutions (Florida)

July 17th, 2024

https://pollutionscience101florida.blogspot.com

 

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Chapter 1: Dyeing technology 


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In this chapter, we will explain the problem with many synthetic dyes out on the market. For many of these toxic dyes that are listed, there is an environmentally friendly alternative.

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Food Dyes Linked to Cancer, ADHD, Allergies

 

2010

 

”Red 3 and Citrus Red 2 should be banned under the Delaney amendment, because they caused cancer in rats (some uses were banned in 1990), as should Red 40, Yellow 5, and Yellow 6, which are tainted with cancer-causing contaminants.


http://www.foodsafetynews.com/2010/07/popular-food-dyes-linked-to-cancer-adhd-and-allergies/#.UmH8shDNkmx

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Food Dyes Linked to Behavioral Problems

Red 40 is used mainly in junk foods. Linked to hyperactivity. Banned in Denmark,
Belgium, France, Switzerland, and Sweden being phased out in the entire EU. Made of petroleum and 2-naphthalenesulfonic acid.


http://www.inspirationgreen.com/food-dyes-linked-to-behavior-problems.html

 

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50 Jawdroppingly Toxic Food Additives to Avoid

http://mphprogramslist.com/50-jawdroppingly-toxic-food-additives-to-avoid/


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Dangerous Food Additives - AVOID!


http://www.traditionaloven.com/articles/wp-content/uploads/list_of_food_additives.pdf


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POSSIBLE CARCINOGENIC POTENTIAL OF VARIOUS MARKETED DYES

Water pollution due to effluents from textile dyeing industry is a cause of serious concern. The techniques for detection of dyes are cost intensive and futile because the dyes undergo chemical changes under environmental conditions and the transformation products may be more toxic and carcinogenic than the parent molecule. Hence instead of detecting each chemical individually it is advisable to study the toxic effect of the effluents on various living organisms.

Various techniques of toxicity and carcinogenicity measurements are discussed in this review. Remediation using physical, chemical and biological methods has also been critically reviewed.

 

http://www.ijpcbs.com/files/10-353.pdf

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How Food Companies Fool Consumers with Food Coloring Ingredients Made From Petrochemicals   



You'll notice artificial colors in foods like blueberry muffins or blueberry bagels, too. Read the ingredients on blueberry bagels at your local grocery store next time, and you'll find that there are really no blueberries but plenty of artificial blue and green colors to create the impression of little blueberry bits. They can't even put blueberries in their bagels. They have to trick you with artificial colors.
Do you know what liquid they're using to hold the color? Propylene glycol -- the same chemical you put into your RV when you want to winterize it. It is antifreeze. You're eating antifreeze and petrochemicals -- and that's just the blueberry part. We haven't even gotten to everything else, like refined sugars, chemical preservatives and refined bleached white flour, which has diabetes-causing contaminants. A blueberry bagel is no longer a blueberry bagel. When you really understand what's in the foods, it's mind blowing.


http://www.organicconsumers.org/articles/article_11042.cfm


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Pretty Scary: Heavy Metals in Face Paints

What We Found

For this report, the Campaign for Safe Cosmetics sent 10 children's face paints to an independent lab to test for heavy metals. Among our findings:

• 10 out of 10 children's face paints we tested contained low levels of lead, ranging from 0.05 to 0.65 parts per million (ppm).

6 out of 10 products contained the potent allergens nickel, chromium and/or cobalt at levels ranging from 1.6 to 120 ppm – far above the safety recommendations of industry studies.

 http://www.safecosmetics.org/article.php?id=584



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Are your child’s clothes TOXIC?

Most likely the clothes you are wearing on you back and the ones you dress your kids in have harmful toxins in them. The effects of these toxins on your children can range from hyperactivity to hormone imbalances. - See more at: http://www.mygutsy.com/are-your-childs-clothes-toxic/#sthash.lp1FtYEF.dpuf

Most likely the clothes you are wearing on you back and the ones you dress your kids in have harmful toxins in them. The effects of these toxins on your children can range from hyperactivity to hormone imbalances...


http://www.mygutsy.com/are-your-childs-clothes-toxic/

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 The 6+ Synthetic Fabrics You Most Want to Avoid, and Why 


Toxins in Your Textiles

Most synthetic fabrics, from towels to dress shirts to bed linens, are treated with chemicals during and after processing. These chemicals not only leach into the environment, leaving an impact on groundwater, wildlife, air and soil, but they also may be absorbed or inhaled directly.

• PFCs in "wrinkle-free" pants, often used for school uniforms, may cause cancer, according to the EPA.

• Acrylic fabrics are polycrylonitriles, which may be carcinogenic.

 • Nylon and polyester are made from petrochemicals, whose production creates nitrous oxide, a greenhouse gas that's 310 times more potent than carbon dioxide.



http://www.sixwise.com/newsletters/05/12/21/the-6-synthetic-fabrics-you-most-want-to-avoid-and-why.htm

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The Clothes that Kill You Slowly but Surely

Today's clothing (a $7 trillion/year industry) is manufactured using an astounding 8,000 synthetic chemicals. Nowadays, clothes also contain toxins like formaldehyde, brominated flame retardants, and perfluorinated chemicals (Teflon) to provide "non-iron" and "non-wrinkle" qualities. 

For half a century, skin and chemicals have been interacting… creating problems like infertility, respiratory diseases, contact dermatitis, and cancer. -

When toxins are absorbed through your skin — your largest organ — they bypass your liver, the organ responsible for removing toxins.

You also may not realize that your skin keeps you healthy by venting toxins… up to a pound per day.

Petrochemical fibers restrict and suffocate your skin — shutting down toxic release. Meanwhile, they contribute to your total toxic burden and may become the "tipping point" for triggering the onset of disease.

Two contributing factors are (1) toxic buildup in your body and (2) multiple chemicals that interact together to create even worse problems than the individual chemicals by themselves.

Skin rashes, nausea, fatigue, burning, itching, headaches, and difficulty breathing are all associated with chemical sensitivity. If you have mysterious health symptoms that you can't seem to get control over, it's worth checking out whether your clothes could be the problem.

http://cancerdefeated.com/newsletters/The-Clothes-that-Kill-You-Slowly-but-Surely.html


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Toxic chemicals in children's clothes, explained

 A report released this week by Greenpeace has detected a range of toxic chemicals in children's clothing, made by various manufacturers around the world. The environmental organization found the chemicals in most of the 82 items of children's apparel that it tested, bought in 25 different countries and produced by 12 major brand names, including from high-end retailers.


http://www.dw.de/toxic-chemicals-in-childrens-clothes-explained/a-17366181

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Synthetic Dyes: A look at Environmental & Human Risks

The CNN report October 2007 which Shana wrote about on Green Cotton, revealed that new testing procedures (chemical burden testing) reveal that young babies and children actually do have increased levels of chemicals in their bloodstream and skin. Because clothing comes into prolonged contact with one’s skin, toxic chemicals are often absorbed into the skin, especially when one’s body is warm and skin pores have opened to allow perspiration. We also know that some individuals have what is known as chemical sensitivity, including when exposed to garments of many types.

 Symptoms in adults for chemical sensitivity range from skin rashes, headaches, trouble concentrating, nausea, diarrhea, fatigue, muscle and joint pain, dizziness, difficulty breathing, irregular heart beat, and/or seizures.  Symptoms in children include red cheeks and ears, dark circles under the eyes, hyperactivity, and behavior or learning problems.


http://greencotton.wordpress.com/2008/06/18/synthetic-dyes-a-look-at-the-good-the-bad-and-the-ugly/






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How Leather Is Slowly Killing the People and Places That Make It

 6/03/14

• Vegetable-tanned leather utilizes tannins found in vegetables, tree bark, and other naturally plant-derived sources. These chemicals produce a soft brown leather that is ideal for leather carving and stamping but is very unstable in water. When bathed in hot water, vegetable-tanned leather will shrink and harden drastically, which is why it was once used as both an early form of plate armor as well as for book binding.
• Synthetic-tanned leather, on the other hand, uses aromatic polymers like Novolac, Neradol, and Melamine. Invented during WWII, when vegetable tannins were being rationed as part of the war effort, it's easy to spot this kind of leather by its creamy white color.
• Alum-tanned leather and Rawhide are not generally considered "tanned materials" as they both turn putrid in water. Alum leather is produced using aluminum salts mixed with natural binding agents like flour or egg yolks. Far lighter color shades are possible with Alum than vegetable tannins, though the resulting product will be far less supple. Rawhide is created by simply scraping the skin, soaking it in lime, and stretching it as it dries. The stiff, brittle result is often employed in drum heads, shoelaces, and as doggie chew toys.
• Aldehyde-tanned leather is the primary alternative to the most popular form of tanning, which uses chromium, instead leveraging glutaraldehyde or oxazolidine. Like synthetic-tanned leathers, Aldehyde leather is white in color. It is also very water absorbent, soft, and can be machine washed, making them perfect for use in chamois.
• Chromium-tanned leather is the most popular form of producing leather these days, and one of the most noxious. It relies on a toxic slush of chromium salts and tanning liquor to produce a supple and often light blue colored product. The prepared hides are first pickled in a vat of chromium until the material's pH drops to 2.8 - 3.2, then they're transferred to a secondary vat filled with tanning liquor which penetrates the leather. Once the liquor has been thoroughly and evenly absorbed, the pH of the vat is increased to between 3.8 and 4.2. This fixes the tanning material to the leather at a molecular level and helps reduce the amount of shrinkage experienced when the leather is submerged in warm water.

http://gizmodo.com/how-leather-is-slowly-killing-the-people-and-places-tha-1572678618



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Many dyes on the market can cause problems to the individual wearing these dyes. For more information view the following articles.

The DuPont Investigation - http://dupontinvestigation.blogspot.com


Pollution Science 101 - Cancer Investigated (California) - 

 
http://pollutionscience101cancerinvestigated.blogspot.com

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We need environmentally friendly paints, including dyes used for clothing, pen ink, crayons, paint for vehicles, house paint and food packaging. This includes any type of paint or dye that you can think of.


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Soil as Fabric Dye? Earth Dyeing Hits Pay Dirt

 09/01/11


 http://www.ecouterre.com/soil-as-fabric-dye-earth-dyeing-hits-pay-dirt/

 
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Natural dye

 

https://en.wikipedia.org/wiki/Natural_dye

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Making Natural Dyes from Plants

 

http://pioneerthinking.com/crafts/natural-dyes


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Information on Natural Dyes

 

http://woolery.com/dyeing/natural-dyes/information-on-natural-dyes.html


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Native Plant Dyes

http://www.fs.fed.us/wildflowers/ethnobotany/dyes.shtml




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Waterless dyeing technology is the future (we hope!)

 

April 23, 2013  

 

Dutch Company, DyeCoo, has launched a revolutionary dyeing machine that uses supercritical carbon dioxide and not a single drop of water. This new technology could not have been invented soon enough, as every two years the textile industry uses the same amount of water that’s in the Mediterranean Sea just to dye clothing. In fact, textile dyeing and treatment are responsible for 17 to 20 percent of industrial water pollution, according to the World Bank. This new dry dye method uses 50% less energy and 50% fewer chemicals, to boot!

 

 

 http://designtoimprovelife.dk/waterless-dyeing-dyecoo/

 

 

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Researchers demonstrate 'no-ink' color printing with nanomaterials

 

June 8th, 2015

http://phys.org/news/2015-06-no-ink-nanomaterials.html?utm_source=menu&utm_medium=link&utm_campaign=item-menu

 

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AirDye's Ecological Dyeing Process Makes the Future of Textiles Bright

Most of the discussion in sustainable textiles has centered around the fibers—manufacturers making a switch to organic cotton, or creating fabrics from natural, easily-renewable materials like bamboo or hemp. But very little attention has been paid to the the dyeing process, which can be a potentially devastating industry when it comes to chemicals, waste, and water usage. AirDye, a new method created by Colorep for dyeing textiles takes water almost out of the equation, using 90% less water, but also reducing the emissions and energy used by 85%, since extreme heat is needed to dry the textiles after they are soaked in dye (and most fabrics then require a post-rinse and yet another dry cycle).
AirDye's process begins with using all synthetic fibers for its material, which can be made from recycled PET bottles. Using dispersed dyes that are applied to a paper carrier, AirDye uses heat to transfer the dyes from the paper to the surface of the textiles, coloring it at the molecular level. All paper used is recycled, and dyes are inert, meaning that they can go back to their original state and be reused.

 http://www.fastcompany.com/1368576/airdyes-ecological-dyeing-process-makes-future-textiles-bright

 

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Many times we hear about people trying to reuse and recycle plastic bottles. 

With many concerns and reports about the toxins in current plastic bottles on the market. We must be cautious of trying to continue to produce and recycle toxic plastic. This includes toxic bottles that are recycled in shirts made with plastic materials.

When we recycle plastics that contain harmful plasticizers, including chemicals such as BPA, this is harmful for the environment. The world needs a form of recyclable bioplastic. 


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We still need to be cautious of trying to genetically modify algae and bacteria for dyes, and food. We must be cautious of how synthesized chemicals could interact with other synthetic chemicals, including pesticides and organisms in the wild.



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Microalgae Dyes Make for Clothes That Change Colors as They're Worn

 

 June 30, 2014

One Berlin-based design studio called Blond & Bieber (no reference to Justin) believes in the pigment power of microalgae. Co-founded by designers Essi Johanna Glomb and Rasa Weber, the studio is at the forefront of using different kinds of algae for fashion.
While the thought of wearing pond scum on your back isn't particularly appealing (if you've even thought of it), Algaemy is using European weeds to develop new types of microalgae prints. Their pigments come in shades of blue, green-brown, and red from microalgae.
While microalgae has been used for nutrition, energy and oil production, and potentially for CO₂ sequestration, Glomb and Weber's design lab focuses on the maximizing microalgae’s aesthetic potential. Recently nominated for a German Design Award, they’re launching their first limited-edition shoes with Trippen at Mercedes-Benz Fashion Week this July in Berlin.


 http://motherboard.vice.com/read/microalgae-dyes-make-for-clothes-that-change-colors-as-theyre-worn

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This Clear Solar Dye Can Turn Almost Anything Into A Solar Cell

May 16, 2020

https://www.intelligentliving.co/clear-solar-dye/



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Synthetic dyes made from sustainable chemicals

Yellow, orange, and red hues achieved with plant-derived molecules

October 12, 2019

https://cen.acs.org/environment/sustainability/Synthetic-dyes-made-sustainable-chemicals/97/i40


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New nanomaterials inspired by bird feathers play with light to create color

May 13, 2015

 Inspired by the way iridescent bird feathers play with light, scientists have created thin films of material in a wide range of pure colors—from red to green—with hues determined by physical structure rather than pigments.

 Structural color arises from the interaction of light with materials that have patterns on a minute scale, which bend and reflect light to amplify some wavelengths and dampen others. Melanosomes, tiny packets of melanin found in the feathers, skin and fur of many animals, can produce structural color when packed into solid layers, as they are in the feathers of some birds.

"We synthesized and assembled nanoparticles of a synthetic version of melanin to mimic the natural structures found in bird feathers," said Nathan Gianneschi, a professor of chemistry and biochemistry at the University of California, San Diego. "We want to understand how nature uses materials like this, then to develop function that goes beyond what is possible in nature." -



- The qualities of the material contribute to its potential application. Pure hue is a valuable trait in colorimetric sensors. And unlike pigment-based paints or dyes, structural color won't fade. Polydopamine, like melanin, absorbs UV light, so coatings made from polydopamine could protect materials as well. Dopamine is also a biological molecule used to transmit information in our brains, for example, and therefore biodegradable.

"What has kept me fascinated for 15 years is the idea that one can generate colors across the rainbow through slight (nanometer scale) changes in structure," said Shawkey whose interests range from the physical mechanisms that produce colors to how the structures grow in living organisms. "This idea of biomimicry can help solve practical problems but also enables us to test the mechanistic and developmental hypotheses we've proposed," he said.

Natural melanosomes found in bird feathers vary in size and particularly shape, forming rods and spheres that can be solid or hollow. The next step is to vary the shapes of nanoparticles of polydopamine to mimic that variety to experimentally test how size and shape influence the particle's interactions with light, and therefore the color of the material. Ultimately, the team hopes to generate a palette of biocompatible, structural color...

http://phys.org/news/2015-05-nanomaterials-bird-feathers.html#jCp


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We must question if synthetic nanoparticles are able to biodegrade properly in the wild. 

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Within colors of bees and butterflies, an optical engineer's dream is realized

 

May 15, 2015

 

Evolution has created in bees, butterflies, and beetles something optical engineers have been struggling to achieve for years—precisely organized biophotonic crystals that can be used to improve solar cells, fiber-optic cables, and even cosmetics and paints, a new Yale-led study has found.


The Yale team used high-intensity X-rays at the Argonne National Laboratory in Chicago to investigate color-producing nanostructures within hair-like structures that cover some species of butterflies, weevils and beetles, bees, and spiders and tarantulas. They found that the architecture of these nanostructures are identical to chemical polymers engineered by chemists and materials scientists, according to the report published May 14 in the journal Nano Letters.


"These biophotonic nanostructures have the same shapes commonly seen in blends of large, synthetic, Lego-like molecules called block copolymers, developed by chemists," said lead author Vinod Saranathan, former Yale graduate student and now faculty member at Yale-NUS College in Singapore.

These artificial nanostructures need to be an order of magnitude larger—such as that found in the scales of beetles and butterflies—in order to interfere with light and make saturated colors. Engineers, chemists, and physicists currently find it difficult to control the self-assembly of synthetic polymers to achieve the desired shape of molecules over a large area, Saranathan said.


Engineers, however, have had difficulty organizing these polymers in larger structures that would make them commercially feasible.

http://phys.org/news/2015-05-bees-butterflies-optical.html#jCp

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New research on molecular response to nanoparticles reveals power of nanoinformatics

 

 29 May, 2023 

 

 Researchers have discovered a new response mechanism specific to exposure to nanoparticles that is common to multiple species. By analysing a large collection of datasets concerning the molecular response to nanomaterials, they have revealed an ancestral epigenetic mechanism of defence that explains how different species, from humans to simpler creatures, adapt to this type of exposure.

 

https://www.ucd.ie/research/news/2023/newresearchonmolecularresponsetonanoparticlesrevealspowerofnanoinformatics/body,686676,en.html 

 

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Inspired by butterflies, researcher invents new paint that has no pigments

 

 Mar 10, 2023

 

It can not only keep us safe from the dangerous effects of synthetic paints but also keep buildings cooler.

 

Researchers at the NanoScience Technology Center at the University of Central Florida have invented a new paint that does not use any pigments at all. Called plasmonic paint, it uses nanoscale structural arrangements of aluminum and aluminum oxide to generate its hues. 

 

Exterior paints on the building have a topic of quite some research as scientists look for ways to keep the heat in cooler regions and out in the warmer regions of the world. Last year, Interesting Engineering reported how researchers were working to make the world’s whitest paint thinner so that lesser quantities would be required to paint surfaces.

 

Structural Color: A Sustainable Alternative

 

“The range of colors and hues in the natural world are astonishing — from colorful flowers, birds and butterflies to underwater creatures like fish and cephalopods,” Chanda says. “Structural color serves as the primary color-generating mechanism in several extremely vivid species where geometrical arrangement of typically two colorless materials produces all colors. On the other hand, with manmade pigment, new molecules are needed for every color present.”

 

Based on such bio-inspirations, Chanda’s research group innovated a plasmonic paint, which utilizes nanoscale structural arrangement of colorless materials — aluminum and aluminum oxide — instead of pigments to create colors.

 

While pigment colorants control light absorption based on the electronic property of the pigment material and hence every color needs a new molecule, structural colorants control the way light is reflected, scattered or absorbed based purely on the geometrical arrangement of nanostructures.

 

Such structural colors are environmentally friendly as they only use metals and oxides, unlike present pigment-based colors that use artificially synthesized molecules.

 

The researchers have combined their structural color flakes with a commercial binder to form long-lasting paints of all colors.

 

 https://scitechdaily.com/inspired-by-butterflies-scientist-creates-the-lightest-paint-in-the-world/

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Optical Illusion Produced by Butterflies’ Wing Scales Is Secret to Ultra-Black, Lightweight Materials

  

January 29, 2022

 

Permanent Wings: – Biologically improbable due to human bone and muscle structure (though at the same time, usually easy to rationalize at first glance due to the nature of our shoulders), and if they’re intended for actual flight, you may have to write off several laws of physics as well. Therefore, such characters are often assumed to be not entirely of this world, especially since the domain of birds shares a name with God’s kingdom: Heaven. This ties into the classic depictions of winged angels as well.

 

Some butterflies have ultra-black wings that rival the blackest materials made by humans, using wing scales that are only a fraction as thick — here’s how they do it. Set against a piece of black construction paper, the wings of the male cattleheart butterfly look even blacker than black.

 

The blackness on the wings of many male butterflies is darker than it is on their female counterparts, so one theory is it helps them show off to potential mates. The black regions always border white, colored, or iridescent patches, so the idea is they might work like a dark picture frame to make the brighter blotches pop.

 

In a study in the March 10 issue of the journal Nature Communications, Duke researchers report that ultra-black butterflies from disparate regions of the globe appear to have converged on the same trick. The secret to making blacks this dark and lightweight, they say, isn’t a surplus of melanin — the pigment responsible for a crow’s feathers or a black cat’s fur. It’s an optical illusion created by the 3-D structure of the butterflies’ wing scales.

https://science-atlas.com/biology/optical-illusion-produced-by-butterflies-wing-scales-is-secret-to/


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Nanostructures and Living Cells in Butterfly Wings Could Inspire Radiative-Cooling Materials & Advanced Flying Machines

 

January 28, 2020

 

Infrared photographs of butterflies, where brightness correlates with the capability of radiative cooling. 

 

Researchers discover that butterflies have specialized behaviors and wing scales to protect the living parts of their wings; nanostructures found in the wing scales could inspire the design of radiative-cooling materials to help manage excessive heat conditions; sensory network in the wings could inspire the design of advanced flying machines. 

https://scitechdaily.com/nanostructures-and-living-cells-in-butterfly-wings-could-inspire-radiative-cooling-materials-advanced-flying-machines/

 

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Novel nanostructures in blue sharks reveal their remarkable potential for dynamic color-change

 

July 9, 2025 

 

 

Blue shark dermal denticles. 

 

New research into the anatomy of blue sharks (Prionace glauca) reveals a unique nanostructure in their skin that produces their iconic blue coloration, but intriguingly, also suggests a potential capacity for color change.

 

The research was presented at the Society for Experimental Biology Annual Conference in Antwerp, Belgium on July 9, 2025.

 

"Blue is one of the rarest colors in the animal kingdom, and animals have developed a variety of unique strategies through evolution to produce it, making these processes especially fascinating," says Dr. Viktoriia Kamska, a post-doctoral researcher in the lab of Professor Mason Dean at City University of Hong Kong.

 

The team revealed that the secret to the shark's color lies in the pulp cavities of the tooth-like scales—known as dermal denticles— that armor the shark's skin.

 

The key features of this color-producing mechanism inside the pulp cavity are guanine crystals, which act as blue reflectors, alongside melanin-containing vesicles called melanosomes, which act as absorbers of other wavelengths.

 

"These components are packed into separate cells, reminiscent of bags filled with mirrors and bags with black absorbers, but kept in close association so they work together," explains Dr. Kamska.

 

As a result, a pigment (melanin) collaborates with a structured material (guanine platelets of specific thickness and spacing) to enhance color saturation.

 

"When you combine these materials together, you also create a powerful ability to produce and change color," says Professor Dean. "What's fascinating is that we can observe tiny changes in the cells containing the crystals and see and model how they influence the color of the whole organism."

 

https://phys.org/news/2025-07-nanostructures-blue-sharks-reveal-remarkable.html

 

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Squid and zebrafish cells inspire camouflaging smart materials

 

May 2, 2012

Researchers from the University of Bristol have created artificial muscles that can be transformed at the flick of a switch to mimic the remarkable camouflaging abilities of organisms such as squid and zebrafish.


http://phys.org/news/2012-05-squid-zebrafish-cells-camouflaging-smart.html#nRlv

 

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Breakthrough material provides tunable radar absorption, infrared thermal camouflage

12/06/2023

Researchers at Jiangsu University of Science and Technology demonstrated obscured IR signatures of objects from human hands to aircraft fuselages, exceeding current stealth technologies at only 2.77 millimeters thickness.

https://www.compositesworld.com/news/breakthrough-material-provides-tunable-radar-absorption-infrared-thermal-camouflage-


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This Common Backyard Insect Is Helping Scientists Develop Invisibility Devices

  

March 28, 2024

 

Leafhoppers, a common backyard insect, secrete and coat themselves in tiny mysterious particles that could provide both the inspiration and the instructions for next-generation technology, according to a new study led by Penn State researchers. In a first, the team precisely replicated the complex geometry of these particles, called brochosomes, and elucidated a better understanding of how they absorb both visible and ultraviolet light.

https://scitechdaily.com/this-common-backyard-insect-is-helping-scientists-develop-invisibility-devices/

 

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Scientists discover nerves control iridescence in squid's remarkable 'electric skin'

August 27, 2012 

 

 

http://phys.org/news/2012-08-scientists-nerves-iridescence-squid-remarkable.html#nRlv

 

Squid's colorful, changeable skin enables the animal—and their close relatives, cuttlefish and octopus—to display extraordinary camouflage, the speed and diversity of which is unmatched in the animal kingdom.

But how squid control their skin's iridescence, or light-reflecting property, which is responsible for the animal's sparkly rainbow of color, has been unknown.

In a new study, MBL (Marine Biological Laboratory) researchers Paloma Gonzalez Bellido and Trevor Wardill and their colleagues report that nerves in squid skin control the animal's spectrum of shimmering hues—from red to blue—as well as their speed of change. The work marks the first time neural control of iridescence in an invertebrate species has been demonstrated.

 

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This Incredible Chameleon-Like Material Changes Colour When Flexed

 

16 March 2015

 

Researchers have created a thin, flexible material that changes colour when it's stretched or bent even a tiny amount, and it has some pretty exciting potential for the future of camouflage. 

 

The 'artificial' skin was inspired by chameleons, and doesn't involve any dyes or pigments. Instead, the material has thousands of tiny features etched into its surface, which physically changes the way light is reflected depending on how it's bent. This results in an incredible colour-shifting ability as you can see below.

 

https://www.sciencealert.com/this-new-material-changes-colour-when-flexed

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Chameleon-inspired 3D printing tech uses single-ink to print infinite colors

 

Feb 19, 2024

 

The research merged bottlebrush block copolymers with additive manufacturing, attaining nano control over prints and dynamic color changes.

 

https://interestingengineering.com/innovation/chameleon-inspired-3d-printing 

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Nature's unique way of controlling color explains why birds never go gray

 

December 21, 2015

 http://phys.org/news/2015-12-nature-unique-birds-gray.html

 Using X-ray scattering at the ESRF facility in France to examine the blue and white feathers of the Jay, researchers from the University of Sheffield found that birds demonstrate a surprising level of control and sophistication in producing colours.

Instead of simply using dyes and pigments that would fade over time, the birds use well-controlled changes to the nanostructure to create their vividly coloured feathers - which are possibly used for Jays to recognise one another. The Jay is able to pattern these different colours along an individual feather barb - the equivalent of having many different colours along a single human hair.

The Jay's feather, which goes from ultra violet in colour through to blue and into white, is made of a nanostructured spongy keratin material, exactly the same kind of material human hair and fingernails are made from...

 Dr Parnell added: "This discovery means that in the future, we could create long-lasting coloured coatings and materials synthetically. We have discovered it is the way in which it is formed and the control of this evolving nanostructure - by adjusting the size and density of the holes in the spongy like structure - that determines what colour is reflected.

"Current technology cannot make colour with this level of control and precision - we still use dyes and pigments. Now we've learnt how nature accomplishes it, we can start to develop new materials such as clothes or paints using these nanostructuring approaches. It would potentially mean that if we created a red jumper using this method, it would retain its colour and never fade in the wash."

 


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World's first "aqueous solar flow battery" outperforms traditional lithium-iodine batteries

 

August 3, 2015

 The scientists that revealed the "world's first solar battery" last year are now, following some modifications, reporting its first significant performance milestone. The device essentially fits a battery and solar cell into the one package, and has now been tested against traditional lithium-iodine batteries, over which the researchers are claiming energy savings of 20 percent.


It was last October that researchers at Ohio State University (OSU) first detailed their patent-pending design for a dye-sensitized solar cell also capable of storing its own power. With three electrodes rather than the typical four, it featured a lithium plate base, two layers of electrode separated by a thin sheet of porous carbon, and a titanium gauze mesh that played host to a dye-sensitive titanium dioxide photoelectrode.
The reasoning behind the porous nature of the materials was to allow the battery's ions to oxidize into lithium peroxide, which was in turn chemically decomposed into lithium ions and stored as lithium metal. But the team has redesigned the battery so that air no longer needs to pass through it in order to function.


http://www.gizmag.com/aqueous-solar-flow-battery-osu/38748/?li_source=LI&li_medium=default-widget 

 

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Revolutionary Phase Change Nano Inks: The Future of Energy-Efficient Climate Control in Buildings & Cars

April 5, 2023

 

Phase change inks using nanotechnology have been developed to control temperature and provide passive climate control, reducing energy consumption. The versatile inks have potential applications in buildings, electronics, and clothing, and could become a sustainable solution to address climate change. 

 

World-first ‘phase change inks’ that could transform how we heat and cool buildings, homes, and cars – to achieve sophisticated ‘passive climate’ control – have been developed, with enormous potential to help reduce energy use and global greenhouse gas emissions.

 

New research published in The Royal Society of Chemistry’s Journal of Materials Chemistry A led by Dr. Mohammad Taha, documents proof-of-concept ‘phase change inks’ that use nanotechnology to control the temperature in everyday environments. They achieve this by adjusting the amount of radiation that can pass through them, based on the surrounding environment.

 

Dr. Taha said these inks could be used to develop coatings to achieve passive heating and cooling, reducing our need to rely on energy creation to regulate temperatures.

 

“Humans use a lot of energy to create and maintain comfortable environments – heating and cooling our buildings, homes, cars, and even our bodies,” Dr. Taha said.

 

Revolutionizing Energy Efficiency with Nanotechnology

 

The breakthrough was achieved by discovering how to modify one of the main components of ‘phase change materials’ – vanadium oxide (VO2). Phase change materials use triggers, like heat or electricity, to create enough energy for the material to transform itself under stress. However, phase change materials previously needed to be heated to very high temperatures for their ‘phase changing’ properties to be activated.

 

“We used our understanding of how these materials are put together to test how we could trigger the insulator to metal (IMT) reaction, where the material basically acts as a switch to block heat beyond a particular temperature – near-room temperature (30-40^oC),” Dr. Taha said.

 

Dr. Taha said the next step will involve taking the research, patented by the University of Melbourne, to production.

 

https://scitechdaily.com/revolutionary-phase-change-nano-inks-the-future-of-energy-efficient-climate-control-in-buildings-cars/

 

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Researchers show how natural materials can self-assemble into surfaces with stunning optical properties

September 15, 2015

The tulip called Queen of the Night has a fitting name. Its petals are a lush, deep purple that verges on black. An iridescent shimmer dances on top of the nighttime hues, almost like moonlight glittering off regal jewels.



Certain rainforest plants in Malaysian demonstrate an even more striking color feature: Their iridescent blue leaves turn green when dunked in water.

Both the tulip's rainbow sparkle and the Malaysian plants' color change are examples of structural color—an optical effect that is produced by a physical structure, instead of a chemical pigment.

Now researchers have shown how plant cellulose can self-assemble into wrinkled surfaces that give rise to effects like iridescence and color change. Their findings provide a foundation to understand structural color in nature, as well as yield insights that could guide the design of devices like optical humidity sensors. The researchers describe their results in a paper in The Journa lof Chemical Physics.

Starting with Twisting Cellulose

 

Cellulose is one of the most abundant organic materials on Earth. It forms a key part of the cell wall of green plants, where the cellulose fibers are found in layers. The fibers in a single layer tend to align in a single direction. However, when you move up or down a layer the axis of orientation of the fibers can shift. If you imagined an arrow pointing in the direction of the fiber alignment, it would often spin in a circle as you moved through the layers of cellulose. This twisting pattern is called a cholesteric phase, because it was first observed while studying cholesterol molecules.

Scientists think that cellulose twists mainly to provide strength. "The fibers reinforce in the direction they are oriented," said Alejandro Rey, a chemical engineer at McGill University in Montreal, Canada. "When the orientation rotates you get multi-directional stiffness."


http://phys.org/news/2015-09-natural-materials-self-assemble-surfaces-stunning.html

 

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Squid Based Material Takes 1 Second To Repair Completely

Aug 8, 2020

https://www.youtube.com/watch?v=28VvEEjkGuI

 

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We see how we can now create a viable means to have environmentally friendly types of  technology, for the use of dyeing fabrics. In the next chapters, we would like to talk about new materials and fibers that are now being invented.




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Ban on microbeads offers best chance to protect oceans, aquatic species

 

September 16, 2015 

 

 

http://phys.org/news/2015-09-microbeads-chance-oceans-aquatic-species.html?utm_source=menu&utm_medium=link&utm_campaign=item-menu

An outright ban on the common use of plastic "microbeads" from products that enter wastewater is the best way to protect water quality, wildlife, and resources used by people, a group of conservation scientists suggest in a new analysis.



These microbeads are one part of the microplastic problem in oceans, freshwater lakes and rivers, but are a special concern because in many products they are literally designed to be flushed down the drain. And even at conservative estimates, the collective total of microbeads being produced today is enormous.

In an article just published in the journal Environmental Science and Technology, scientists from seven institutions say that nontoxic and biodegradable alternatives exist for microbeads, which are used in hundreds of products as abrasive scrubbers, ranging from face washes to toothpaste. Around the size of a grain of sand, they can provide a gritty texture to products where that is needed.


Read more at: http://phys.org/news/2015-09-microbeads-chance-oceans-aquatic-species.html#jCp

 

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What’s trending in the Coatings Industry: Top 10 most-clicked news of the last quarter 

17.10.2024 

1. Cottonseed oil as a renewable source for the development of highly functional UV-curable materials
   Researchers discovered that using cottonseed oil to produce bio-based UV-curable polymer resins offers a sustainable alternative to petroleum-based materials, increasing the resulting products’ flexibility.
2. Interview: “The high pH approach is not suitable for some water-borne coatings”
   In an interview with Thomas Bernhofer, Technical Service Manager Coatings at Synthomer, our European Coatings editor Bettina Hoffmann discusses upcoming developments in water-based coatings and how external factors impact the sector’s advancement.
3. Merck signs agreement to sell surface solutions business unit to GNMI
   Merck has signed an agreement to sell its global Surface Solutions business unit to Global New Material International Holdings for EUR 665 million in cash. The company plans to use the proceeds to further strengthen its strategic core businesses.
4. Insights from David Dominguez, Briolf: The future of water-based coatings
   David Dominguez, Strategic Planning Director at Briolf, shared his insights with our editor, Bettina Hoffmann, about future developments and regulatory challenges in water-based coatings until 2030.
5. New additive process enables the production of better and more environmentally friendly chemicals of high value
   Researchers at the Center for Advanced Bioenergy and Bioproducts Innovation (CABBI) have made a breakthrough that could lead to the creation of improved and greener agricultural chemicals and everyday products.
6. Dr. Jörg Krames appointed as new President and CEO for Byk-Gardner
   The globally active measuring instrument manufacturer Byk-Gardner, based in Geretsried, Bavaria, has a new Managing Director: Dr. Jörg Krames.
7. Top 3 countries with the most companies in the Top 25 of the paint and coatings industry
   In the current ranking of the Top 25 companies in the paint and coatings industry by revenue, Germany, the Netherlands, and Denmark stand out, with Germany leading the list.
8. Alisha Bellezza (PPG): “The automotive industry is undergoing an enormous change”
   PPG Industries announced plans to build a new production facility for automotive coatings in North America, investing USD 300 million in the project. Alisha Bellezza, Senior Vice President Global Automotive Coatings, explains to our editor Vanessa Bauersachs the rationale behind this decision and the opportunities it presents.
9. Bio-based coatings: Growing market share, unclear definition
   Industry experts provide insights on the bio-based coatings market concerning market share, main drivers, and challenges. By European Coatings editor Kirsten Wrede.
10. A flexible and transparent superhydrophobic coating on cotton fabrics with high mechanical and chemical stability for underwater insulation
    Researchers have developed a coating that provides cotton fabrics with stretchable, transparent superhydrophobic properties, enhancing both mechanical and chemical stability for underwater insulation applications.

https://www.european-coatings.com/news/markets-companies/whats-trending-in-the-coatings-industry-top-10-most-clicked-news-of-the-last-quarter/

 

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Sustainable Development in the Paint and Coating Industry: New Trends in Green Chemistry, Low Pollution, and Environmental Protection

2023-04-19

https://www.echemi.com/cms/1349758.html

 

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Explore the Top 10 Paint Industry Trends in 2025

February 11, 2025

The paints and coatings industry shifts towards sustainability, eco-friendliness, and enhanced performance. From eco-conscious formulations to advanced application methods, key trends and innovations advance the concept of paint and its usage. Emerging trends in the paint industry include anti-bacterial and VOC-free paints, as well as aerospace applications and nanotechnology. The industry also expects to see advancements in smart coatings with self-healing properties, energy-efficient reflective paints, and biobased materials.

Top 10 Latest Technologies in the Paint Industry (2025)

    Anti-bacterial Paint
    Aerospace Paint
    Natural Paint Ingredients
    Self-Healing Paint
    VOC-Free Compounds
    Glow In The Dark Paints
    Advanced Paint Equipment
    Nanocoatings
    3D Color Visualization
    Fast-Drying Paints

Tree Map reveals the Impact of the Top New Trends in the Paint Industry

Based on the Paint Industry Innovation Map, the TreeMap below illustrates the impact of the Top 10 Paint Industry Trends. Startups and scaleups are improving customer experience and safety with new technologies. Antibacterial and antimicrobial paints prevent bacteria and fungi growth.

Aerospace and automotive paints offer better performance and durability. Natural ingredients, VOC-free additives, and nano coatings provide healthier alternatives to traditional paints. Active paints, including self-healing, self-cleaning, advanced tools, and glow-in-the-dark options, offer improved aesthetics and functionality.

Top 10 Paint Industry Trends in 2025

1. Anti-bacterial Paint

The paint industry sees significant innovations like anti-bacterial paints, which are playing a vital role in enhancing the quality of living spaces. These paints are formulated with antimicrobial additives that inhibit the growth of bacteria and fungi on painted surfaces, contributing to a healthier and more hygienic environment.

In today’s health-conscious world, the demand for such paints is growing due to their potential to reduce the spread of harmful microbes. Antibacterial paints offer benefits like improved indoor air quality, reduced infection risk, and enhanced painted surface longevity. These paints find applications in healthcare facilities, homes, and public spaces, where cleanliness and hygiene are paramount.

As awareness about health and hygiene continues to rise, the adoption of anti-bacterial paints is set to have a positive impact on the industry, making it the top paint industry trend in the near future.

Further, the global antimicrobial coatings market size was USD 11.39 billion in 2023 and is expected to grow at a CAGR of 13.9% from 2024 to 2030.

NanoMiix provides antimicrobial additives

Australian startup, NanoMiix, develops environment-friendly antimicrobial additives using nanotechnology. Leveraging the properties of nanosilver, copper, and zinc oxide, its products eliminate bacteria, viruses, and fungi.

Nanosilver particles compromise microbial structures by combining with cell wall proteins, entering the microbe, and disrupting DNA replication and oxygen production. This approach enhances existing products with potent antibacterial, antiviral, and antifungal properties. Moreover, its advanced nanometal additives enhance microbial protection.
Alora develops Easy-to-Clean Anti-Bacterial Paints

Alora is a startup from Singapore that manufactures easy-cleaning and eco-friendly paints for residential and commercial applications. It uses a no-odor and near-zero-VOC formula to prevent harmful chemicals and smells in the home and offer a safe environment for living.

The startup’s anti-mold technology lowers mold development on painted surfaces and anti-viral protection keeps indoor spaces clean. Alora offers anti-bacterial primers, paints, and paint kits that are healthier for families and the environment.

2. Aerospace Paint

In the paint industry, aerospace paints hold a critical role in ensuring the performance and longevity of aircraft. Aerospace coatings are meticulously formulated to meet the stringent requirements of the aviation sector.

These coatings not only provide an appealing exterior appearance but also offer essential protective functions. Companies are manufacturing coatings equipped with nano-scale additives and specialized polymers to resist wear and tear, corrosion, and extreme temperatures.

The global aircraft paint market was valued at USD 4.2 billion in 2022. It is projected to reach USD 6.4 billion by 2032, growing at a CAGR of 4.5% from 2023 to 2032.

Aerospace paints are designed to provide corrosion resistance, prevent wear and tear, and minimize drag resistance, ultimately contributing to the overall aircraft efficiency and safety.

The unique demands of the aerospace industry necessitate coatings that adhere reliably to various substrates, resist UV radiation, and maintain their properties over extended periods.

Flora Surfaces makes Sustainable Surface Solutions

US-based startup Flora Surfaces develops and manufactures high-performance sustainable materials for paints in the aerospace and automotive industries. It produces biobased polymer resins from surplus natural oils and converts them to biodegradable films and coatings for corrosion protection and restoration of objects.

The startup offers FLYCO, a single-component, solvent-based aerospace paint solution that dries in ambient conditions and creates high surface energy for top coats. The paints use proprietary hybrid polyurethane resin that hardens through internal crosslinking and eliminates the need for toxic chemicals. Flora Surfaces’ solutions enhance dirt resistance and reduce drag resistance on the aircraft surface.

Henan Holywell manufactures Hollow Glass Microspheres

Chinese startup Henan Holywell manufactures hollow glass microspheres (HGMs) for aerospace vehicle painting. It utilizes hollow, spherical, powdered, ultralight, and inorganic materials that reduce part weight, lower costs, and enhance product properties.

It provides HGM-HL, HGM-HK, and HGM-HS paint and coating series for longer surface survivability under harsh conditions. These paints offer lower thermal conductivity, higher compressive strength resistance, and high-temperature resistance that is suitable for aerospace applications. Henan Holywell caters to aircraft manufacturers and service providers, oil & gas, and automotive industries.

3. Natural Paint Ingredients

Natural ingredients play a significant role in the paint industry as a response to growing environmental concerns and the demand for sustainable solutions. Paints are traditionally composed of chemicals, solvents, and pigments.

However, the incorporation of natural ingredients has gained momentum due to their eco-friendly properties. These ingredients include plant extracts, minerals, and other biodegradable components that substitute or complement synthetic materials.

This paint industry trend reduces the environmental impact of paint production and application. Additionally, some natural ingredients contribute unique textures and colors to the paint, expanding the creative possibilities for designers and consumers.

While the integration of natural ingredients presents challenges in terms of consistency and durability, it showcases the industry’s commitment to more sustainable and health-conscious paint options.

Prespaglia provides Straw-based Construction Materials

Italian startup Prespaglia uses straw recovered from wheat waste to offer sustainable construction materials that feature thermal and acoustic insulation characteristics. The startup manufactures building materials such as bricks, thermal coats, thickening glue, and natural paints.

These natural paints offer low emissions, sound-absorbing properties, and better thermal insulation in both cold and hot weather. Prespaglia provides green building materials and solutions for interior and exterior applications to both residential as well as commercial.

neogrun manufactures Organic Finger Paints

German startup neogrun manufactures organic finger paints, modeling clay, and DIY organic painting kits for children. It leverages natural and sustainable ingredients from plants and renewable resources to develop non-toxic paints for kids and enable a safe art environment.

The solution eliminates the use of parabens, azo dyes, petrochemicals, and other allergens such as milk, nuts, fish, soy. and eggs. This keeps the paints safe for all children, making it a sustainable choice for parents. neogrun caters to both retailers and wholesalers by providing organic paint solutions to keep children and the environment safe.

4. Self-Healing Paint

The global self-healing coatings market size was estimated at USD 2432.51 million in 2023. It is projected to grow at a CAGR of 28.4% from 2024 to 2030.

Self-healing paints introduce a transformative mechanism that enables the restoration of paint surfaces to their original state. These innovative coatings contain microcapsules that release restorative agents when the paint is damaged or scratched, effectively healing the surface and minimizing the appearance of imperfections.

For example, in the automotive industry, self-healing car paints are becoming popular for their ability to recover from minor scratches and abrasions, reducing the need for frequent repainting. In the aerospace and industrial sectors, these paints contribute to enhanced durability and protection against wear and tear. Self-healing paints extend the lifespan of coatings, enhance aesthetics, and offer cost-effective solutions for maintaining surfaces in challenging environments.

Revivify offers Self-Repairing Paints for Surface Protection

Canadian startup Revivify manufactures self-healing paint and coating solutions to protect surfaces. It uses nanotechnology to develop coatings and paints to offer heat-activated applications on multiple surfaces.

The heat-activated coating uses a blend of organic and inorganic materials to offer high-temperature resistance in aerospace applications. Also, it offers salt corrosion resistance in maritime vessels and acid and alkali resistance in semiconductors. Revivify provides performance painting and coating solutions to automotive, aerospace, and maritime industries.

Coat-it provides Surface Treatment Solutions

Polish startup Coat-it offers solutions for surface treatments and protection in the automotive, transportation, energy, and construction industries. It offers paint and coatings with mechanical and anticorrosion feature enhancements such as self-healing, self-cleaning, antifouling, and superhydrophobic properties.

The startup also provides nano-additives for multiple plating applications to improve surface properties and enable protection against corrosion and other environmental factors. Coat-it caters to building and construction, furniture and lighting, and lifestyle industries by providing surface functionalization solutions.

5. VOC-Free Compounds

The global low VOC or zero VOC paints market is estimated to be valued at USD 10.45 billion in 2024. It is expected to reach USD 16.45 billion by 2031, growing at a CAGR of 6.7% from 2024 to 2031.

VOC-free compounds have emerged as a significant trend in the paint industry, addressing environmental and health concerns associated with volatile organic compounds. VOCs are chemicals emitted by conventional paints that contribute to air pollution and have adverse health effects.

VOC-free paints, also known as low-VOC or no-VOC paints, contain minimal or no VOC content, making them safer for both the environment and human health. These compounds play a vital role in promoting sustainable and eco-friendly practices within the industry.

By reducing VOC emissions, they improve indoor air quality, minimize respiratory issues, and contribute to better overall well-being. Additionally, VOC-free paints align with stringent environmental regulations and are preferred choices for environmentally conscious consumers and businesses.
Palette offers Indoor Air Purification Paints

Palette is a startup from the Netherlands that develops and manufactures eco-friendly paints for healthy indoors. It provides VOC-free, environmentally friendly paints that offer anti-bacterial, odorless, and pollutant-free applications for improving indoor air quality.

The startup utilizes a water-based solution along with eco-friendly chemicals such as titanium dioxide, castor oil, and silica to manufacture A+ grade paints. Palette offers safer painting solutions ideal for indoor applications that provide improved air quality and a pollutant-free environment.

Cover Story develops Plastic-Free Paints

Finnish startup Cover Story produces plastic-free, sustainable paints for interior and exterior applications. It uses organic paint binders based on renewable plant oil that eliminates the use of synthetic plastic-based ingredients as binders. This enables a VOC-free and odorless experience and a water-based solution with natural pigments.

The startup designs built-to-last paints and uses wind turbines for the manufacturing process to enable sustainability and recycling. Cover Story provides breathable and emission-free painting solutions for both indoor and outdoor residences and commercial properties.

6. Glow-In-The-Dark Paints

Glow-in-the-dark paints have carved out a unique role in the paint industry, driving both artistic and functional applications. Comprising phosphorescent pigments, these paints emit light after exposure to a light source. Their utility extends from decorative elements in the realm of art and design to safety-enhancing features in various industries.

In sectors such as emergency signage, aerospace, automotive, and interior decor, the luminous properties of these paints offer enhanced visibility during low-light conditions. While traditional glow-in-the-dark materials utilize radioactive compounds, modern versions employ safer and more environmentally friendly alternatives.

SplashKits provides Neon Painting Kits

US-based startup SplashKits makes painting kids for children of all ages to improve their creativity, imagination, and self-expression. The startup offers interactive kits such as neon and glow-in-the-dark paints for art and painting parties.

The kit offers a mini UV keychain that enables children to light up the paints in the dark, enabling a novel painting experience. It provides glow-in-the-dark painting series such as Glowing Jelly, Pop Dog, and Glowing Pop Art.

PM Colours offers Reactive Paint Solutions

PM Colours is a startup from the Czech Republic that provides painting solutions that react to environmental conditions such as sun, reflection, dark, and temperature. It offers paint series, such as Chameleon, which changes with motion, neon which shines in the sun, phosphorus paints that glow in the dark, and thermo which changes with temperature.

The startup offers paints and renovation sets to maintain the paints for longer periods of time. PM Colours provides painting solutions to the automotive industry and enables owners to showcase their art and uniqueness on their cars.

7. Advanced Paint Equipment

Advanced paint equipment plays a pivotal role in the modern paint industry, fostering innovation and efficiency. These advancements span various stages of the production process, from the formulation of paint components to precise mixing, blending, and application techniques.

Cutting-edge equipment ensures optimal dispersion of pigments, uniform consistency, reduced waste, and improved quality control. Additionally, it addresses environmental concerns by enabling the formulation of eco-friendly paints. This emerging paint industry trend not only streamlines manufacturing operations but also facilitates the creation of paints that align with sustainable practices.

Moreover, the spray painting machine market size was valued at USD 4.78 billion in 2023. It is expected to grow by 5.2% from 2024 to 2030, reaching nearly USD 6.82 billion.

ROICO Solutions develops Easy-To-Use Painting Tools

ROICO Solutions is a startup from Denmark that manufactures painting tools that offer easy-to-use indoor and outdoor applications. It provides collaborative robot solutions in construction to increase the productivity, efficiency, safety, and sustainability of painters and professionals.

Bobby is the startup’s cobot that enables wall and ceiling paintings efficiently and takes over tedious and demanding painting tasks. The startup’s solution is easy to set up and connects to a mobile application to place the cobot near the wall and prepare the paint. ROICO Solutions allows painters to carry out painting tasks faster and improve productivity in tedious and demanding painting tasks.

Dexter Robotics provides Surface Painting Robots

UAE-based startup Dexter Robotics offers solutions to improve glass/facade cleaning and wall paintings in tall buildings. It develops and manufactures robots capable of walking and clinging to structural surfaces for construction and maintenance needs.

The startup offers Cling Climbing and Cling Heavy Duty, surface-attaching robots with a strong holding force based on symmetric parallel kinematics. This enables high stiffness, high accuracy, and the capability to handle large loads of painting applications.

The robot is also programmable and portable to carry out custom paint jobs efficiently at heights. Dexter Robotics allows maintenance and construction industry professionals to perform dangerous tasks and jobs with ease and precision.

8. Nanocoatings

The global nanocoatings market size was valued at USD 12.86 billion in 2023. It is projected to grow at a CAGR of 16.4% from 2024 to 2030.

Nanotechnology enables the integration of nanoparticles into paint formulations, resulting in enhanced performance and functionality. These nanoparticles bring advantages such as improved UV light absorption, hardness, and even antimicrobial properties.

The role of nanocoatings in the industry extends to various applications, from automotive paints to corrosion prevention and dust-repellent coatings. Researchers and manufacturers are exploring the potential of nanoparticles to create innovative solutions that address challenges in the paint sector.

As technology advances, nanocoatings will continue to gain traction as a top paint industry trend by providing tailored functionalities that enhance durability, protection, and sustainability.
SolOr manufactures Coatings for Photovoltaic Systems

Israeli startup SolOr makes coatings for photovoltaics and building integrated photovoltaics. It utilizes colloidal quantum dots, semiconductor nanoparticles that are synthesized in the liquid phase, to manufacture coatings and paints.

These nano-paints offer customized optical properties by varying the composition and synthesis conditions. The coating allows the PV cells to enable the electrical charge to flow within the material and improve the electro-optical properties of the semiconductors. SolOr caters to smart buildings and the solar industry by providing paint solutions that capture energy from the sun to generate electricity.

Fluoink Nanotechnologies provides Antibacterial Surface Protection

Fluoink Nanotechnologies is a startup from Tunisia that provides antibacterial surface protection solutions based on nanotechnology. It uses antibacterial technology to manufacture paints and coatings to provide durable protection against bacterial growth.

The startup’s technology allows paints to kill numerous types of bacteria and offers a stable, always-on application that eliminates re-application of the coating. Fluoink Nanotechnologies’ paints find applications in private and public places such as hospitals, public transport, and agri-food industries.

9. 3D Color Visualization

In the era of digitalization, the paint industry is embracing innovative tools to enhance customer experiences and decision-making processes. One of these advancements is the integration of 3D color visualizers, which have significantly transformed the way consumers interact with paints and coatings.

These visualizers allow customers to virtually apply different colors and finishes to their living spaces, enabling them to visualize the final look before making a purchase. By providing an interactive and immersive platform, 3D color visualizers allow businesses to enhance customer experience and streamline product selection. This also allows businesses to use the visualizers for training and education for paint application techniques.

moblo offers 3D Interior Design Solutions

French startup moblo provides applications for designing interiors and furniture in 3D using augmented reality. It enables designing a 2D plan in a 3D model by deploying an intuitive interface and ready-to-use elements.

The solution also enables customizing the application material and paint to visualize the results prior to real-world application. The startup’s app places the designed furniture and selected paint inside the room and makes further customizations. moblo enables interior and exterior designers, as well as customers, to choose custom designs, improve customer satisfaction, and reduce the costs of rework.
Decofy develops Generative AI Visualization Solutions

UK-based startup Decofy offers mobile AI platforms to enable customers to decorate and personalize their interiors. It utilizes generative AI to offer DIY solutions for customers to design and shop for interior designing products such as furniture, paints, and accessories.

The AI visualization tool enables customers to preview the products in their spaces using smart video technology. Using this technology, users calculate the space and amount of material needed to complete painting tasks. Decofy caters to end users as well as painting industry professionals by providing a smart sales channel to deliver digital paint solutions.

10. Fast-Drying Paints

Fast-drying paints are formulated with rapid-drying agents and advanced technology to significantly reduce the time required for paint to dry and cure on surfaces. They enable faster completion and reduce downtime for projects of all types.

Moreover, fast-drying paints contribute to energy savings as they decrease the need for extended ventilation and heating periods. The paints are formulated in different variations including water-based and oil-based options, each with its own advantages and use cases.

Fast-drying paints are commonly used for interior and exterior projects and are ideal for painting walls, furniture, and metal surfaces.

NGNT uses Nanodiamond Technology

Swiss startup NGNT develops nanocomposite coatings using enriched nanoparticles and perhydropolysilazane (PHPS) for quick drying applications. Its NGNT Nano-Composite Coatings combine nanodiamonds and PHPS to create a flexible, diamond-armored, elastic coating with hydrophobic characteristics.

PHPS, a transparent silicon-based polymer, offers heat resistance, UV resistance, water repellency, and surface hardness. The integration of nanodiamonds and carbon nanotubes results in abrasion-resistant coating and minimal interaction with natural and chemical elements. These coatings offer slower erosion times and durability with long-lasting performance.

Hanford & Green makes Performance Paints

UK-based startup Hanford & Green provides performance paint manufacturing, as well as building and commercial decorating solutions to property owners, managers, architects, and interior designers. It offers water-based low-VOC paints using biomaster technology to provide environment-friendly and antimicrobial applications and enables easy cleaning and faster drying.

It offers an odorless multi-surface application with improved opacity that requires fewer paint coats and saves on costs. Hanford & Green provides paint and coating solutions to healthcare, education, student living, residence, and commercial spaces.

https://www.startus-insights.com/innovators-guide/paint-industry-trends/ 

 

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Cloverdale Paint and Celanese launch carbon-utilizing paint initiative

January 10, 2025


Cloverdale Paint and Celanese Corporation, a global leader in specialty materials and chemicals, have created a partnership aimed at developing sustainable paint solutions using advanced carbon capture and utilization (CCU) technology. 

This collaboration is designed to convert industrial CO2 emissions into renewable feedstocks that can be utilized in paint production.

Celanese’s CCU technology captures CO2 emissions that would typically be released into the atmosphere and employs hydrogen to transform this captured CO2 into methanol. This methanol serves as a foundational component in vinyl acetate-based emulsions, a key ingredient for manufacturing paints. 

By integrating this process, Cloverdale Paint aims to reduce reliance on fossil fuels and lower carbon emissions compared to conventional manufacturing practices.

The partnership is expected to enable Cloverdale Paint to incorporate over one million pounds of CO2 emissions annually into its product line, reflecting both companies’ dedication to sustainability and innovation.

Darrin Noble, president and chief operating officer of Cloverdale Paint, highlighted the initiative as part of the company’s broader commitment to environmental responsibility. “Our Green Guarantee reinforces our focus on sustainable materials and minimizing waste at every operational stage,” he stated. 

Kevin Norfleet, global sustainability director at Celanese, spoke about the potential impact of the partnership, noting that it exemplifies how CCU can facilitate a reduction in the carbon footprint of products while fostering a circular economic model. 

Through this initiative, Cloverdale Paint and Celanese seek to advance sustainable practices within the industry, contributing to a more environmentally conscious marketplace.

https://worldbiomarketinsights.com/cloverdale-paint-and-celanese-launch-carbon-utilizing-paint-initiative/ 

 

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Innovations in Eco-Friendly and Sustainable Exterior Paints

2024

https://wepaintsiding.com/exterior-painting/innovations-in-eco-friendly-and-sustainable-exterior-paints/
 

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How to make an Oil-Based Varnish

Aug 19, 2016 

How to prepare a very useful oil-based varnish for all kinds of wood and wood by-products, outdoors and indoors.

Tung Oil

Linseed Oil (Flaxseed oil)

Orange Essence Oil

Camellia Oil (Tea Seed Oil)

Turpentine Essence

Carnauba Wax

https://www.youtube.com/watch?v=UvCQdLWIUGo&t=1s

 

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Make Wood Stain in Any Color – 7 Easy Recipes!

July 3, 2024

Four basic DIY wood stain recipes using vinegar and steel wool or rusty nails. 

I started with 4 jars to test various types of vinegar and metal: 

Recipe 1. 1 1/2 cup of white vinegar and one steel wool pad

Recipe 2. 1 1/2 cup of balsamic vinegar and one steel wool pad

Recipe 3. 1 1/2 cup of apple cider vinegar and one steel wool pad

Recipe 4. 1 1/2 cup of white vinegar and rusty nails

You must be thinking: “Oh balsamic vinegar will be the darkest stain, due to its color! “

Before we look at all the colors in comparison, let’s look at two more variations on these 4 basic wood stains. 

Coffee or tea with the basic DIY wood stains

Recipe 5: Brew some tea or coffee at 3-4 times the strength, let cool, apply this mixture to raw wood surfaces. The coffee or tea do not add darker color to the wood stain, they add tannins to the wood which will make the stains much darker. Apply the stain after the wood dries from the tea / coffee first coat.

 

 
 

Now let’s check out all the DIY wood stains and variations in the above photo.

1. Stain #1 – #4 applied on pecan or walnut wood. This type of wood has high concentrations of tannins, so all the stains come out quite dark. No need for tea or coffee!

2. white vinegar and steel wool stain on pine: a rich brown color

3. balsamic vinegar and steel wool stain on pine: a warm gray with a gold tone

4. white vinegar and rusty nails stain on pine: a brown color lighter than the one with steel wool, i think it’s because steel wool dissolves faster, so the iron is more concentrated

5. apple cider vinegar and steel wool stain on pine: also a warm gray similar to the balsamic vinegar, more silvery gray

6. & 7. coffee and the vinegar metal stains: all the different vinegar and metal solutions produced a dark, almost black color because of the coffee

8. & 9. 50% white vinegar and steel wool stain with 50% water: both types of wood has the diluted stains on the right, and natural wood in the middle. The rich brown stain became a gray color stain after being diluted with equal amount of water.

So far we have stains in all shades of browns and grays. What about colors?
Make wood stain in any color using diluted acrylic paints! (or other water based ink or paint)

If you love colors, and you also love the grain of the wood, this method gives you the best of both worlds!

Recipe 7: Dilute the acrylic paint with a ratio of 1 part paint and 1 part water, and apply the “stain” onto the wood with a brush or a rag. The wood will be stained with the paint color, but still has the wood grain showing through!

Different brands of paints will have different consistencies. Choose exterior paints for outdoor projects. And always choose non-toxic paints!

https://www.apieceofrainbow.com/make-wood-stain/

 

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2-Ingredient DIY Butcher Block & Cutting Board Oil Conditioner

July 15, 2021

Pour 400 ml of food safe mineral oil into the cup, add chopped wax or pellet wax slowly until the oil and wax mixture reaches 500 ml. You can use 100% beeswax, or 50% beeswax and 50% carnauba wax. We like to use at least 1/3 carnauba wax .

https://www.apieceofrainbow.com/diy-butcher-block-cutting-board-oil-conditioner/

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2-Ingredient DIY Natural Wood Finish & Clear Furniture Wax

April 6, 2018

Glass jar with lid, a small pot to boil water.

1 part bees wax, 4 parts jojoba or olive oil (I used olive oil).

https://www.apieceofrainbow.com/diy-natural-wood-finish-clear-furniture-wax/

 

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5 Weird Wood Staining Techniques. Natural Wood Coloring Hacks That Really Work.

Aug 26, 2016

 

 
 

Coffee Staining

Tea Staining

Wine Staining

Beet Staining

Turmeric Staining

https://www.youtube.com/watch?v=4EmtYa93KEU&t=41s

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Most Sustainable Paints, Primers, Varnishes, Stains, and Sealers: Safe, Eco-friendly, LEED Compliant

2019

https://onecommunityglobal.org/most-sustainable-paints-stains-varnish-sealers/

Following One Community’s commitment to upholding the Highest Good, we aim to provide an open source and freely available blueprint for ecologically-sustainable and holistic development. To do so, One Community aims to provide directly applicable information about the most sustainable options for everyday materials and systems like paints, toilets, shower heads, lighting, HVAC Design, etc. This page is about our most current research on eco-paint, primer, varnish, stain, and sealer options and contains the following sections:
   

    Best and Most Sustainable Eco-friendly Paints We Could Find

        Do-it-yourself Paint Options

    Best and Most Sustainable Eco-friendly Primers We Could Find

        Do-it-yourself Primer Options

    Best and Most Sustainable Eco-friendly Varnishes We Could Find

        Do-it-yourself Varnish Options

    Best and Most Sustainable Eco-friendly Stains We Could Find

        Do-it-yourself Stain Options

    Best and Most Sustainable Eco-friendly Sealers We Could Find

        Do-it-yourself Sealer Options

    LEED Materials Points Explained



THE BEST AND MOST SUSTAINABLE & ECO-FRIENDLY PAINTS WE COULD FIND

Paint is arguably the most commonly used surface-application construction product by volume and application. It colors, protects, and textures both in and out of our homes. Unfortunately, it can also contain many ingredients like VOCs, SVOCs, urea formaldehyde, hexavalent chromium, and other hazardous chemicals that are bad for our health. This makes it especially desirable to choose products and companies that produce products that are non-toxic and sustainability-conscious. After over 20 hours of research, we’ve created the list below of the safest and most sustainable companies we could find for paint. They are listed in the order we’d recommend them based on safety, sustainability, selection, and price.

#3 :: REAL MILK PAINT

If you’re interested in a more natural and DIY-esque option, but not interested in experimenting with making paints from scratch, Real Milk Paint Co. is an excellent option. A company based around creating biodegradable and quality paints, Real Milk Paint Co. provides natural, milk-based paints in powdered form, which one mixes with water to produce a full, high quality, beautiful paint. All of these reasons combine to make Real Milk Paint Co. our #3 recommended eco-paint product.


DO-IT-YOURSELF CASEIN-BASED PAINT

Casein is the main protein in milk and is commonly used in many adhesives, paints, and other industrial products. It has been used since ancient Egyptian times, dries to an even consistency, can visually resemble oil painting more than most other water-based paints, and works well as an underpainting too. Casein paint loses its solubility with time and exposure and becomes water-resistant. It is suited most to inflexible surfaces like walls and furniture and can be buffed to a soft velvet finish when dry, or varnished for a gloss finish. Entirely natural, casein paint is an excellent option that can create a full, lasting, durable (when mixed with lime) paint, completely free of toxic chemicals and entirely sustainable.

Here is a casein paint recipe from this article at Mother Earth News. It produces about 1 quart.

INGREDIENTS

    1 gallon nonfat milk
    2 1/2 ounces “Type S” lime (dry powder available at hardware stores)
    2 1/2 cups water
    Natural earth pigment (more or less depending on desired color)
    6 cups filler (usually whiting)

DIRECTIONS

    Leave milk in a warm place for a few days to curdle. Then pour through a colander lined with cheesecloth. You should have about 2 cups of curds. The whey can be composted.
    Mix curds and lime powder in a blender. Add a little water if the mixture isn’t blending well. Strain to remove any lumps.
    Add water to the binder immediately after it is prepared.
    Dampen and crush pigments. Add them to the mixture a little at a time until desired color intensity is achieved.
    Stir in filler.

PROS FOR THIS DIY PAINT

Entirely natural and, when mixed correctly, can last indefinitely without the hazards of fungus growth, peeling, or cracking. Excess paints can be safely composted, and the freedom of DIY allows one to create the exact color your looking for.

CONS FOR THIS DIY PAINT

Mixing the paint is difficult, and requires careful precision. If not mixed correctly, the paint will dust off, peel, or crack. From Mother Earth News: “It is also important to apply thin coats and allow each coat to dry completely, because the paint will become more and more opaque as it dries. Also, in order to become an adhesive binder, casein must be combined with an alkali such as lime. You can use borax instead, but lime-casein paint is much more water resistant.”

DO-IT-YOURSELF FLOUR-BASED PAINT

Flour-based paint is also known as “wheat paint” and “ochre paint.” It is an age-old recipe originated in Sweden and is sometimes called “Swedish paint” too. From this article, “They are made from pigments (for the color), binders (to bind all the ingredients together), solvents or thinners (to dilute and make the paint easier to apply), and additives (to add specific properties to the paint, such as quicker drying, or protection against mold, etc.).”

Here is a flour-based paint recipe from this article at Mother Earth News. It produces about 1.5 quarts.

INGREDIENTS

    1 cup flour
    5 1/2 cups cold water
    1 cup screened clay filler (clay can be purchased in a wide variety of colors)
    1/2 cup additional powder filler, such as mica

DIRECTIONS

    Mix flour with 2 cups cold water, whisking to remove lumps.
    Bring 11/2 cups water to boil, then add the flour water from Step 1.
    Turn heat to low, stirring until thick paste develops. Remove from heat.
    Dilute the paste with 2 cups water, a little at a time.
    In a separate work bowl, combine clay with powder filler.
    Add filler mixture to diluted flour paste until desired consistency is achieved.

PROS FOR THIS DIY PAINT

Flour paints allow more room for error while still remaining successful. The proportions do not have to be as perfectly exact as other DIY paint methods. The completed paint can be applied to a wide range of surfaces and is a versatile paint with nice, full color.

CONS FOR THIS DIY PAINT

Flour paints are too thick for rollers, and are hard on brushes, making them difficult to apply, and expensive (as they burn through brushes). Painting them on large surfaces can be tedious, and leaves pronounced brush marks, necessitating a supplementary step of going over the paint with a wet sponge, to achieve a smoother coat. 

DO-IT-YOURSELF OIL-BASED PAINT

Oil paint is another common DIY paint option. It is a slow-drying paint that consists of particles of pigment suspended in a drying oil, commonly linseed oil. This means the paint is entirely natural and does not contain any solvents or artificial binders. Oil-based paints are a long standing option for holistic, self-sufficient paints that allow for great painting creativity and produce a nice coat ideal for exterior surfaces.

Here is an oil-based paint recipe from this article at Mother Earth News.

INGREDIENTS

Natural oil paints typically are made with linseed oil and a natural solvent, such as pure turpentine or citrus thinner. Choose raw linseed oil or linseed stand oil, which has been heated to a high temperature, making it more durable. Avoid boiled linseed oil, which can contain a variety of ingredients that speed drying time, but may be hazardous to your health.

DIRECTIONS

    Make an oil based primer like this: “Combine equal parts linseed oil and natural solvent. Then apply a thin coat, in the direction of the grain, and wipe off any excess. When the first coat is dry (about 48 hours), apply a second coat.”
    Next apply your basic oil paint: “Your surface will be ready for paint about 48 hours after the primer has dried. It is difficult to provide precise recipes for oil paints, because pigments absorb oil to varying degrees. Pour several tablespoons of linseed oil in a bowl and add pigment, a little at a time, until a doughy paste forms. Then you can add more oil just until the mixture flows. Next, add solvent until the paint reaches your desired consistency. Pour the finished mixture through a strainer to remove lumps.”

PROS FOR THIS DIY PAINT

Oil paint takes a long time to dry, and may never completely harden, which allows it to remain more elastic and change along with the natural expansion/compression of materials over the seasons and years. This helps make it longer lasting and saves money in the future. Creating your own paint is rewarding and ensures a complete knowledge of the paints ingredients, thus protecting one’s ecological integrity and health.

CONS FOR THIS DIY PAINT

Creating oil paints is difficult and essentially a free-form process, with no specific set recipe. This makes the methodology difficult to recreate on a mass scale, and prone to miscalculation and mistakes. The long drying period of the paint can be frustrating and stifle projects in situations where more traditional styles of paint would achieve the goal quite quickly.

DO-IT-YOURSELF NATURAL PRIMER OPTIONS

Here are the most popular do-it-yourself primer options we could find. They are listed in alphabetical order.

DO-IT-YOURSELF CASEIN-BASED PRIMER

Casein is the main protein in milk and is commonly used in many adhesives, paints, and other industrial products. It has been used since ancient Egyptian times, dries to an even consistency, can be used as paint and primer and visually resembles oil painting more than most other water-based paints, when used as paint. Casein Primer has a firming effect and lowers absorbency. It is suited most to inflexible surfaces like walls and furniture. Entirely natural, casein paint is an excellent option that can create a full, lasting, durable primer, completely free of toxic chemicals and entirely sustainable.

Here is a casein paint/primer recipe from this article at Mother Earth News. It produces about 1 quart.

INGREDIENTS

    1 gallon nonfat milk
    2 1/2 ounces “Type S” lime (dry powder available at hardware stores)
    2 1/2 cups water
    Eliminate this for primer: Natural earth pigment
    6 cups filler (usually whiting)

DIRECTIONS

    Leave milk in a warm place for a few days to curdle. Then pour through a colander lined with cheesecloth. You should have about 2 cups of curds. The whey can be composted.
    Mix curds and lime powder in a blender. Add a little water if the mixture isn’t blending well. Strain to remove any lumps.
    Add water to the binder immediately after it is prepared.
    Stir in filler.

PROS FOR THIS DIY PRIMER

Entirely natural and, when mixed correctly, can last indefinitely without the hazards of fungus growth, peeling, or cracking. Excess primer can be safely composted, and the freedom of DIY allows one to create the exact color your looking for.

CONS FOR THIS DIY PRIMER

Mixing the primer is difficult, and requires careful precision but not as much as when mixing as paint. If not mixed correctly, the primer will dust off, peel, or crack. From Mother Earth News: “It is also important to apply thin coats and allow each coat to dry completely, because the paint will become more and more opaque as it dries. Also, in order to become an adhesive binder, casein must be combined with an alkali such as lime. You can use borax instead, but lime-casein paint is much more water resistant.” We assume the same applies to primer.

DO-IT-YOURSELF CHALK-BASED PRIMER

Chalk-based primer (also called chalk-based paint) is another DIY option for you to take complete control of the ingredients going into the materials surrounding you. The recipe below by MyRepurposedLife.com creates a quality primer from nothing more than latex paint, Plaster of Paris, and water. Simply mixing them together in the correct amounts results in an easy, quality primer, perfect for home improvement projects.

INGREDIENTS

    1 cup latex paint
    2 TBS Plaster of Paris
    4 tsp water

DIRECTIONS

    Mix plaster and water till it’s smooth with no lumps.
    Pour your mixture into approximately 1 cup of latex paint. If you get your paste too thin, add a little more plaster. Too thick, add a little water.
    Sand your painted piece after the DIY chalky paint dries”before you add your top coat (just as you would with premium chalk paint).

PROS FOR THIS DIY PRIMER

This DIY primer is incredibly cheap, easy, and quick, and results in a high-quality finished product where you have complete control over what is in it. It can be modified to suit the needs of the user more easily than many conventional products and MyRepurposedLife.com said it stores pretty well too: “I have been known to save leftovers for up to two weeks in a container with a lid. You may need to add a little water after storing this chalky paint.”

CONS FOR THIS DIY PRIMER

DIY paint/primer recipes can be dirty and tedious, and it can be hard to perfect the mixture. Buying premixed products makes the process quicker and easier, and ensures a high quality outcome.

REAL MILK PAINT FINISH

Although they do not sell traditional varnishes, Real Milk Paint Co. has a range of finishes. These clear coats go over painted or stained surfaces to protect the coating and therefore serve a similar function to a varnish. Real Milk Paint Co. is a trusted and proven company with a remarkable commitment to sustainability combined with an innovative and creative practice – creating entirely natural, milk based paints.

DO-IT-YOURSELF NATURAL VARNISH OPTIONS

Here are the most popular do-it-yourself varnish options. They are listed in alphabetical order.

DO-IT-YOURSELF BEESWAX VARNISH

If you’re interested in a DIY alternative to commercial varnishes, beeswax-based varnishes are an excellent option. Relatively easy to produce and cheaper than buying commercial products, making DIY varnish can be a wonderful way to seal wooden components of your project. This recipe by Natural Earth Paint has only two ingredientsL: olive oil and all natural beeswax. It produces an excellent and easy-to-use product.

Here is the recipe from Natural Earth Paint:

INGREDIENTS

    4 oz olive oil
    1 oz pure beeswax

DIRECTIONS

    Fill a measuring cup with 4 oz olive oil

    Add 1 oz pure beeswax, broken into small pieces (or use beeswax pellets)

    Heat until beeswax is completely melted

    Pour into a glass container that can be covered to save excess polish (be careful because the mixture is very hot)

    Allow to cool until mixture forms a solid, much like the consistency of lip balm

    Use hands to polish the wood’s surface

    Let polish sit on wood a few hours or overnight, then wipe off excess with a clean soft cloth

PROS FOR THIS DIY VARNISH

By choosing the DIY route, one has complete control over the ingredients going into their products, and thus complete control over the chemical content of the things in one’s home or project.

CONS FOR THIS DIY VARNISH

Creating DIY varnishes takes work and attention to detail with the recipe so that you get the high-quality product that is possible. Buying commercial products ensures large quantities of high quality product, without the extra work of perfecting a DIY recipe.

DO-IT-YOURSELF NATURAL STAIN OPTIONS

Not satisfied by our selections, or hoping to go even further with sustainability? For more information on DIY Wood Stains, including an overview of the science behind wood stains, 4 excellent recipes, and a comprehensive pros and cons analysis of store bought vs DIY stains, refer to this excellent writeup by A Piece of Rainbow.

STEEL WOOL AND VINEGAR RECIPE

This write-up by A Piece of Rainbow includes four natural wood stain write-ups. These cover white, balsamic, and apple cider vinegar variations, with thorough explanations of the color differences. It also includes application tutorials, a comprehensive explanation of the science behind wood stains, and an overview of the benefits of natural versus conventional methods. They go into such excellent detail on their site that we’d rather you go there than try and reproduce their information here in a lesser form.

PROS FOR THIS DIY STAIN

DIY Wood Stains are an excellent, fulfilling to use, quality, and affordable alternative to store-bought products. Although it can be difficult to master the mixing to create the stains, a bit of persistence goes a long way. DIY options are excellent for anyone who wishes to have complete control over the ingredients that go in to their living areas.

CONS FOR THIS DIY STAIN

Mastering the mixing and application could pose some difficulty, and may be less reliable than store-bought options regarding color, durability, and quality.


DO-IT-YOURSELF NATURAL SEALER OPTIONS

Here is a natural sealer option also.

DO-IT-YOURSELF LINSEED-OIL-BASED SEALER

This recipe from hunker.com has only two ingredients – linseed oil and turpentine. Want complete control over the ingredients going into the product you are using, and thus the environment you live and breathe in? Here you go! Making DIY linseed-oil-based sealer is easy, cheap, and it works.

INGREDIENTS

    1 part linseed oil
    1 part turpentine

DIRECTIONS

    Purchase linseed oil that has already been boiled or boil it yourself. It will be ready after it reaches a full boil.
    Get a large bucket and mix the linseed oil with an equal amount of turpentine. How much you make depends on how large a surface area you need to seal.
    Apply at least two coats.

PROS FOR THIS DIY SEALER

This DIY option has less environmental impact than most conventional products and allows you complete control and knowledge of the ingredients.

CONS FOR THIS DIY SEALER

It requires more work to boil and mix your own than to buy it. 

 

 

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Transforming Waste into Art: Food Magic's Sustainable Paint Project Inspires Creative Environmental Solutions

February 29, 2024

The goal of their larger project, titled “Food Magic” is two-fold: first, to design a system that transforms food waste into paint for school audiences; and second, to raise awareness, educate, and inspire a radical rethinking of food consumption, use, and recycling within the local community.  The interdisciplinary team, led by Dr. Choi, is co-led by School of Visual Arts professor Hiromi Okumura, industrial design professor Brook Kennedy, and Sustainable Biomaterials professor Dr. Young-Teck Kim, and is composed of graduate architecture student Avery Gendell and industrial design students Farida Hanna, Camille D’Amico, and Royce Childress.  Together, the Food Magic team learned how to extract pigments from different sources of food waste like corn husks, orange peels, onion skins, and more, and process these pigments into all-natural watercolor paints.  They are now using this process to guide the design and development of their holistic system which guides users through all stages of the paint-making process from the collection of food waste through the production of usable watercolors.  

Using the paints the team produced, Professor Okumura and Avery collaboratively created the two artworks to demonstrate the overlooked value and beauty in food waste that would otherwise end up in a landfill.  As they noted in their artist’s statement, “We recognize the need for humans to return to a symbiotic relationship with the world around us.” In efforts to reflect such a need and further center the value of the natural world’s provisions, the artists painted Spirit of the Earth using only natural instruments like leaves, twigs, rocks, flowers, and seed pods... 

https://design.vt.edu/news-and-events/news/transforming-waste-into-art-food-magics-sustainable-paint-project-inspires-creative-environmental-solutions.html




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Chapter 2: Armor technology 


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Nanotechnology in the Military
 
( National Defense )
( Homeland Security )

 Armor as strong as a snail?


  http://ice.chem.wisc.edu/Small%20Science/From_Small_Science_Comes_Big_Decisions/Choices_files/Military.pdf

Sea snails and abalone are guiding scientists in their search for
strong and lightweight armor. Others besides the military, will benefit from these new nanoscience
developments: firefighters, police officers, and other emergency responders. Another method for creating super strong materials uses tungsten, not carbon, for the basic material.


Another new nano
-
Another new armor is called "smart" body armor. It weaves thin pads or cloth from  fibers that can sense the impact of a bullet or shrapnel and automatically stiffen.  This material would be even more resistant to penetration and less cumbersome than the ceramic-plate armor troops wear now.

Concerns about biochemical-warfare have resulted in exploration into nano-size umbrellas that open to seal the cloth's pores, making it impervious to airborne chemicals and pathogens. That would be much easier and
lighter than the current equipment required.



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Smart Material: Spider Silk

 

 Mar 5, 2011

 https://www.youtube.com/watch?v=nYlkJyG1Oik&list=PLQoTHqAEU9OSjWhEvxWS5PIka1lSQrEZ8&index=8

 

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Spiders sprayed with carbon nanotubes spin superstrong webs

May 06, 2015

 

 

 A team of researchers working in Italy has found that simply spraying a spider with a carbon nanotube solution can cause the spider to spin stronger webs. In their paper they have uploaded to the preprint server arXiv, the team describes their experiments with both graphene and nanotube solutions and what happened when they sprayed it on ordinary spiders.



 http://phys.org/news/2015-05-spiders-carbon-nanotubes-superstrong-webs.html?utm_source=menu&utm_medium=link&utm_campaign=item-menu

 

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Add Graphene To Spider Silk To Create The Strongest Fiber Yet

 

Web slingers get a high-tech upgrade

Posted May 7, 2015

 
http://www.popsci.com/spiders-add-graphene-silk-creating-strongest-fiber-yet

 

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 Researchers explore mechanics of silk to design materials with high strength and low density

May 15, 2015

 Scientists at MIT have developed a systematic approach to research the structure of spider silk, blending computational modeling and mechanical analysis to 3D-print synthetic spider webs.


 http://phys.org/news/2015-05-explore-mechanics-silk-materials-high.html#jCp

 


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Spider signal threads reveal remote sensing design secrets

 

December 16, 2015

When you look at a spider web in the garden, one thing is often noticeably absent: the spider. This may be because it is lurking away from the web in a 'retreat', where it can monitor web vibrations through a proxy known as a signal thread.

A new Oxford study published in Journal of the Royal Society Interface looks in more detail at the composition and structure of these signal threads, which spiders can use to tell whether they've caught new prey.

Dr Beth Mortimer from the Oxford Silk Group, based in the Department of Zoology, spoke to Science Blog about the research.


http://phys.org/news/2015-12-spider-threads-reveal-remote-secrets.html

 
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NIST develops impact-resistant material inspired by mantis shrimp exoskeleton

06/30/2025

Researchers discovered they could fine-tune the biomimetic synthetic material’s energy dissipation upon impact, informing its future potential for aerospace, space and beyond.

https://www.compositesworld.com/news/nist-develops-impact-resistant-material-inspired-by-mantis-shrimp-exoskeleton
 

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Lithium-ion batteries inspired by snail shells could prove longer-lasting

February 11, 2015

In an ongoing effort to improve the performance of lithium-ion batteries, scientists have looked to the techniques that snails use to control the growth of their shells. This biological inspiration, combined with a peptide found to bind very effectively with materials used to make cathodes, has potential for making lighter and longer-lasting batteries.


http://www.gizmag.com/lithium-ion-batteries-snail-shells/36045/

 
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Advanced composites may borrow designs from deep-sea shrimp

 

July 14, 2015 

 

 

New research is revealing details about how the exoskeleton of a certain type of deep-sea shrimp allows the animal to survive scalding hot waters in hydrothermal vents thousands of feet under water.

http://phys.org/news/2015-07-advanced-composites-deep-sea-shrimp.html?utm_source=menu&utm_medium=link&utm_campaign=item-menu




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NASA tests foldable cloth heat shield in Mars entry simulation

  

October 6, 2015

 As spacecraft for manned and planetary missions get larger, so do their heat shields – which are becoming very big indeed. To avoid the day when the shield becomes too large for any existing or planned launcher, NASA’s Ames Research Center in California is developing the Adaptive Deployable Entry and Placement Technology (ADEPT) heat shield, which uses carbon-fiber cloth and can be folded up like an umbrella. The cloth heat shield recently completed tests that simulated entering the Martian atmosphere.

http://www.gizmag.com/nasa-cloth-heat-shield-adept/39729/?li_source=LI&li_medium=default-widget

 

 
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Unique three-layered snail shell could lead to tougher body armor

 

February 1, 2010

They say life imitates art, but any scientist knows that the best designs imitate life. Researchers from the MIT Institute for Soldier Nanotechnologies (ISN) are drawing new biomimicry inspiration for body armor design from a hardy ocean snail that boasts a shell structure unlike anything else seen in nature... or in material research labs.

 http://www.gizmag.com/snail-shell-military-armor-car-panels/13989/?li_source=LI&li_medium=default-widget

 

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Limpets sink their teeth into world's strongest natural material crown

 

February 18, 2015

Spider's silk has long been the strongest natural material known to man, prompting researchers to attempt to uncover its secrets so they can replicate its remarkable properties in man-made materials. But scientists now have a new source of inspiration in the form of limpet teeth, which are made of a material researchers say is potentially stronger than spider silk, is comparable in strength to the strongest commercial carbon fibers, and could one day be copied for use in cars, boats and planes.


http://www.gizmag.com/limpet-teeth-strongest-natural-material/36162/

 

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Tiny diatoms boast enormous strength

 

February 8, 2016

Diatoms are single-celled algae organisms, around 30 to 100 millionths of a meter in diameter, that are ubiquitous throughout the oceans. These creatures are encased within a hard shell shaped like a wide, flattened cylinder—like a tambourine—that is made of silica. Researchers in the lab of Julia Greer, professor of materials science and mechanics in Caltech's Division of Engineering and Applied Science, have recently found that these shells have the highest specific strength—the strength at which a structure breaks with respect to its density—of any known biological material, including bone, antlers, and teeth.

 http://phys.org/news/2016-02-tiny-diatoms-enormous-strength.html

 
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Researchers look to the boxfish for new body armor materials

 July 29th, 2015

Researchers from the University of California, San Diego (UCSD) are taking inspiration from nature in the search for new materials that could one day be used to create more effective body armor. The study, which was supported by the US Air Force, focuses on the unique structure and strength of the hexagonally-scaled shell of the boxfish.

The idea of looking to nature for inspiration when it comes to next-gen armor isn't anything new. We've seen numerous studies over the last few years that focus on that same idea, including efforts to copy the structure of overlapping fish scales and even the properties of sea sponges to develop strong yet flexible armor.

 http://www.gizmag.com/boxfish-body-armor/38681/?li_source=LI&li_medium=default-widget

 


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Tiny sea creatures could provide inspiration for armor with built-in optical systems

 

November 25, 2015

 http://www.gizmag.com/mit-chiton-optical-armor/40590/?li_source=LI&li_medium=default-widget

A team of MIT researchers has looked closer than ever before at the unique shells of chitons, using X-rays to discover their secrets. The results reveal a no-compromise setup that provides the tiny sea creatures with both protection and optical visibility. The findings could one day inspire man-made armor with similar abilities.

Turning to nature for ideas for new materials is nothing new. In the past, researchers have looked to fish scales, boxfish shells and even sea sponges for better body armor, and we've even seen species of chiton inspiring higher-performing batteries and solar cells.

For the new MIT study, the researchers worked with a fascinating species of chiton known as Acanthopleura granulata. They have an appearance similar to the rocks amongst which they're usually found, and are small at only a few inches in diameter.

The creatures have developed a ceramic shell system that's not only flexible, being comprised of eight overlapping plates, but also provides high levels of visibility, by incorporating tiny eyes throughout. Unlike the vast majority of other living creatures, the chiton's eyes aren't made from portein, but are instead made up of the mineral aragonite – the same ceramic that makes up the rest of its shell.

 

 
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Next-generation body armor could be based on ... sponges?

 

 March 18, 2013

 http://www.gizmag.com/sponge-spicule-armor/26700/

Sponges’ “skeletons” – their internal structural elements – are made up of tiny interlinked needle-like structures known as spicules. These are hard, prickly, flexible and lightweight. As a result, they offer enough strength to provide structural support, while they bend to such an extent that they’re difficult to cut. A team of researchers from Germany’s Johannes Gutenberg University Mainz and the Max Planck Institute for Polymer Research set out to develop a material with those same qualities.
The nanoscale spicules they created incorporate a mixture of the mineral calcite, and a protein found in siliceous sponges known as silicatein-α. Each synthetic spicule is composed of a multitude of calcite “nanobricks” stacked together brick chimney-style, with a matrix of the stretchy protein holding them together.

 

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Next generation armor inspired by animal scales

 

 February 12, 2015

http://www.gizmag.com/next-generation-armor-animal-scales/36050/?li_source=LI&li_medium=default-widget

 We've seen scientists examine everything from the structure of sea sponges to the clubbing ability of mantis shrimps in the search for next generation lightweight armor systems. Researchers at Northeastern University’s College of Engineering believe that fish scales could hold the key to creating armor that's both impervious and lightweight. They eventually aim to combine the properties of fish, snake and butterfly scales into a single protective armor system.


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Future soldiers may be wearing fish-inspired body armor

 

March 16, 2015

 On most fish, their hard, overlapping scales provide considerable protection against pokes and cuts. Because those independently-moving scales are each attached to a flexible underlying skin, however, the fish are still able to easily twist and turn their bodies. Scientists from the Technion-Israel Institute of Technology and MIT are now attempting to copy that structure, to develop flexible-yet-effective armor for humans.

http://www.gizmag.com/fish-inspired-armor/36563/?li_source=LI&li_medium=default-widget

 

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Fish's piranha-proof scales could lead to tough, flexible body armor

 

 February 10, 2012

http://www.gizmag.com/arapaima-piranha-proof-scales/21419/?li_source=LI&li_medium=default-widget

 The Arapaima's "hard on the outside but pliable underneath" strategy is employed by a number of organisms, that need to be agile while remaining protected. Meyers believes the principle could find use in flexible ceramics, that could in turn be applied not only to soldiers' body armor, but also fuel cells, insulation or aerospace technology.

 Here's a question - if piranhas are so ferocious and will attack anything, why aren't they the only fish in the Amazon? Well, in some cases, it's because other fish possess bite-proof armor. The 300-pound (136-kg) Arapaima is just such a fish. In the dry season, when water levels get low, Arapaima are forced to share relatively small bodies of water with piranhas. Their tough-but-flexible scales, however, allow them to remain unharmed. A scientist from the University of California, San Diego is now taking a closer look at those scales, with an eye towards applying their secrets to human technology such as body armor.

 

 
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Super-tough glass based on mollusk shells

January 29, 2014

In the future, if you drop a glass on the floor and it doesn't break, thank a mollusk. Inspired by shellfish, scientists at Montreal's McGill University have devised a new process that drastically increases the toughness of glass. When dropped, items made using the technology would be more likely to deform than to shatter.

http://www.gizmag.com/mollusk-nacre-tougher-glass/30654/?li_source=LI&li_medium=default-widget

 

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Tough-as-nails ceramic inspired by mother-of-pearl

 

March 25, 2014

 http://www.gizmag.com/mother-of-pearl-nacre-ceramic/31367/?li_source=LI&li_medium=default-widget

Although you may know it simply as the shiny iridescent stuff on the inside of mollusk shells, mother-of-pearl (or nacre) is a remarkable material. It allows those shells, which otherwise consist almost entirely of brittle calcium carbonate, to stand up to the abuses of life in the sea. Now, a team led by the Laboratoire de Synthèse et Fonctionnalisation des Céramiques (CNRS) in Paris, has copied the structure of nacre to create a ceramic material that's almost 10 times stronger than conventional ceramics.
Natural nacre consists of layers of microscopic tablet-like blocks, that have wavy edges not unlike jig-saw puzzle pieces. This means that when the material is subjected to mechanical stress, any cracks that start to form in the boundary lines between the tablets have to follow a very circuitous route. As a result, all but the largest cracks simply just peter out.
Scientists at Montreal's McGill University recently created super-strong glass, by etching nacre boundary line-like cracks in glass microscope slides. The CNRS team, however, took a different approach with the ceramic.
They started with a ceramic powder, made up of microscopic alumina platelets. That powder was suspended in water, and the resulting solution was then frozen. The ice crystallization process caused the platelets to self-assemble into stacks, the boundaries between which were similar to the wavy boundaries between nacre tablets. A high-temperature process was then used to increase the density of the material, thus removing the water.
In lab tests of the resulting ceramic, it was found that cracks had great difficulty spreading through it – as is the case with real nacre.
Additionally, the scientists state that the process should work with any type of ceramic powder (not just alumina), and it should be easy to scale up to industrial production levels. Besides simply making existing types of ceramic items stronger, the technology could also allow them to stay at the same strength, but be made much smaller.



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Study shows how calcium carbonate forms composites to make strong materials such as in shells and pearls

January 8, 2016

Seashells and lobster claws are hard to break, but chalk is soft enough to draw on sidewalks. Though all three are made of calcium carbonate crystals, the hard materials include clumps of soft biological matter that make them much stronger. A study today in Nature Communications reveals how soft clumps get into crystals and endow them with remarkable strength.


http://phys.org/news/2016-01-calcium-carbonate-composites-strong-materials.html#nRlv

 

 
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Mantis shrimp may hold the secret to lighter, tougher body armors

 

June 9, 2012

 

 

 

The mantis shrimp is a fascinating creature that has the ability to punch its prey into submission with a club that accelerates underwater at around 10,400 g (102,000 m/s²). By studying the secrets behind this formidable weapon, a Californian researcher hopes to develop an innovative, hi-tech material that is one third the weight and thickness of existing body armor.

 

http://www.gizmag.com/mantis-shrimp-body-armor/22873/ 

 

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MIT breakthrough could lead to paper-thin bullet-proof armor

 

November 12, 2012

 Scientists have theorized that paper-thin composite nanomaterials could stop bullets just as effectively as heavy weight body armor, but progress has been hampered by their inability to reliably test such materials against projectile impacts. Researchers at MIT and Rice University have developed a breakthrough stress-test that fires microscopic glass beads at impact-absorbing material. Although the projectiles are much smaller than a bullet, the experimental results could be scaled up to predict how the material would stand up to larger impacts.
 

http://www.gizmag.com/mit-breakthrough-paper-thin-bullet-proof-armor/24971/?li_source=LI&li_medium=default-widget

 

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Engineers create new nano-fiber tougher than Kevlar

 

December 7, 2010

A new high performance fiber that is better at absorbing energy without breaking than Kevlar has been created by the U.S Department of Defence. While still under development, the material could be used in bulletproof vests, parachutes, or in composite materials for vehicles, airplanes and satellites in the future. The fiber has been engineered from carbon nanotubes spun into a yarn and held together using a polymer. The resultant material is tough and strong while still remaining flexible.

 http://www.gizmag.com/new-nano-fiber-tougher-than-kevlar/17203/?li_source=LI&li_medium=default-widget

 

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New Nanomaterial Proves Stronger Than Kevlar

 

 Mar 2, 2023 

 

Scientists at Caltech have created a unique nano-architected material that can stop microparticles traveling at supersonic speeds, outperforming Kevlar and other protective materials.

 

How it works

A nano-architected material consists of patterned nanometer-scale structures that, depending on how they are arranged, can give materials unique or surprising properties, such as exceptional lightness and resilience.

Greer’s Caltech team fabricated its nano-architected material with two-photon lithography, “a process that uses a fast, high-powered laser to pattern intricate, microscopic 3D architectures in polymer resins,” said Greer. “We then constructed a repeating lattice configuration composed of microscopic struts."

Making the samples for the experiments was challenging. “We knew that we wanted to test nano-architected carbon, which is made using a process called pyrolisis after the 3D lithography process,” she continued.

Similar Reading: Using Muscle to Spin Fiber

Pyrolisis is a process that burns without oxygen, which is what converts polymers and other organic materials into glassy carbon. This process also generates substantial linear and volumetric shrinkage, which made it difficult to work with. “For example, samples were no longer attached to the substrates and flew away in the furnace before we could take them out, or samples cracked, or often were simply too small to manipulate and test,” Greer said.

Once the samples were made, they were subjected to extreme deformation at the Massachusetts Institute of Technology using laser-induced particle impact tests. The technique aims an ultrafast laser through a glass slide coated with a thin film of gold, which itself is coated with a layer of micro silicon-oxide particles. As the laser passes through the slide, a plasma is generated that releases and propels silicon oxide particles toward the target.

To the team’s surprise, its nano-architected carbon was, in fact, highly impact resistant.

“We did not anticipate these results. That at velocities up to almost 1 km/s, the micro-projectiles [silicon beads] would either elastically recover or embed themselves into the material or damage it slightly and then rebound,” said Greer. “In no experiment did the projectile either penetrate through the material or transmit the shock wave onto the underlying matter. This was a big surprise for us, and we didn’t have the benefit of checking the literature because it was a first-of-its-kind experiment on a nano-architected material.”

https://www.asme.org/topics-resources/content/new-nanomaterial-proves-stronger-than-kevlar

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New Laser-Based Method Could Help Scientists Discover New Puncture-Resistant Materials

 

 July 3, 2023

 

Using tiny laser-launched projectiles and troves of data, scientists can more quickly bridge the gap between a material’s microscopic properties and its real-world behavior.

 

A bullet piercing the protective armor of a first responder, a jellyfish stinging a swimmer, micrometeorites striking a satellite: High-speed projectiles that puncture materials show up in many forms. Researchers constantly aim to identify new materials that can better resist these high-speed puncture events, but it has been hard to connect the microscopic details of a promising new material to its actual behavior in real-world situations. 

 

To address this issue, researchers at the National Institute of Standards and Technology (NIST) have designed a method that uses a high-intensity laser to blast microscale projectiles into a small sample at velocities that approach the speed of sound. The system analyzes the energy exchange between the particle and the sample of interest at the micro level then uses scaling methods to predict the puncture resistance of the material against larger energetic projectiles, such as bullets encountered in real-world situations. This new method, described in the journal ACS Applied Materials & Interfaces, reduces the need to perform a lengthy series of lab experiments with larger projectiles and bigger samples.

 

“When you’re investigating a new material for its protective applications, you don’t want to waste time, money and energy in scaling up your tests if the material doesn’t pan out. With our new method we can see earlier if it’s worth looking into a material for its protective properties,” said NIST chemist Katherine Evans. 

 

During lab experiments, synthesizing small amounts of a new polymer — e.g., a few milligrams from glassware the size of a coffee cup — can be fairly routine. The challenge comes with scaling up to produce kilograms of material to be able to test its puncture resistance. For materials made from new synthetic polymers, scaling up to sufficient quantities is often not possible or practical. 

 

“The problem with ballistic tests is that you must take two steps when making new materials. You need to synthesize a new polymer that you think will be better, and then scale it up to kilogram size. That is a big jump. The biggest accomplishment of this work is that we surprisingly show that the micro-ballistic tests can be scaled and linked to real-world large-scale tests,” said NIST materials research engineer Christopher Soles.

 

During the course of the study, researchers used their method to evaluate several materials, including a widely used compound for bulletproof glass, a novel nanocomposite, and the strong, all-carbon material known as graphene.

 

The test is called LIPIT, which stands for laser-induced projectile impact testing. It uses lasers to launch a microprojectile made of either silica or glass into a thin film of the material of interest. Through a process called laser ablation, the laser creates a high-pressure wave that propels the microprojectile material toward the sample. 

 

 

LIPIT, which stands for laser-induced projectile impacting testing, uses tiny laser-launched microprojectiles aimed at a thin layer of polymer film.

https://www.nist.gov/news-events/news/2023/07/new-laser-based-method-could-help-scientists-discover-new-puncture

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Wood pulp extract stronger than carbon fiber or Kevlar

 

September 3, 2012

 http://www.gizmag.com/cellulose-nanocrystals-stronger-carbon-fiber-kevlar/23959/?li_source=LI&li_medium=default-widget

The Forest Products Laboratory of the US Forest Service has opened a US$1.7 million pilot plant for the production of cellulose nanocrystals (CNC) from wood by-products materials such as wood chips and sawdust. Prepared properly, CNCs are stronger and stiffer than Kevlar or carbon fibers, so that putting CNC into composite materials results in high strength, low weight products. In addition, the cost of CNCs is less than ten percent of the cost of Kevlar fiber or carbon fiber. These qualities have attracted the interest of the military for use in lightweight armor and ballistic glass (CNCs are transparent), as well as companies in the automotive, aerospace, electronics, consumer products, and medical industries.

 

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Cellular Nanocrystals From Recycled Wood Waste Make Carbon-Fiber Composites Tougher

 

August 15, 2020

 

 

 Electron micrograph of cellular nanocrystals on the carbon fibers.

 

 Polymers reinforced with ultra-fine strands of carbon fibers epitomize composite materials that are “light as a feather and strong as steel,” earning them versatile applications across several industries. Adding materials called carbon nanotubes can further enhance the composites’ functionality. But the chemical processes used for incorporating carbon nanotube end up spreading them unevenly on the composites, limiting the strength and other useful qualities that can be ultimately achieved.

https://scitechdaily.com/cellular-nanocrystals-from-recycled-wood-waste-make-carbon-fiber-composites-tougher/

 

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Processed wood can be moulded into complex 3D structures

 

10 Nov 2021

 

 Researchers in the US have developed a new technique that allows wood to be shaped into complex 3D structures. Shaoliang Xiao, Bing Hu and colleagues at the University of Maryland, have shown how useful components can be made by breaking down the molecular structures of wood cell walls, and then moulding the material into desirable shapes. The approach could allow the manufacture of components that are normally made from plastics and metals, but with far lower environmental impacts.

 

Plastics and metals can be easily processed into lightweight structural components, with widely varying shapes and sizes. This property makes these materials particularly valuable for use in vehicles and buildings, where weight-saving measures are often vital for reducing costs and improving performance. Yet due to the environmental costs of producing metals and plastics, there is now a growing need for more sustainable alternatives.

 

As a mechanically strong, lightweight, and widely available resource, wood is now being studied as a potential replacement material. Since it is completely renewable, its production can be far more environmentally friendly than metals and plastics, provided it comes from sustainable sources.

 

https://physicsworld.com/a/processed-wood-can-be-moulded-into-complex-3d-structures/

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Citrus Derivatives Can Create 100% Renewable Transparent Wood

 

May 06 2021

Transparent wood has been developed by researchers at KTH Royal Institute of Technology as an advanced structural material for building construction after it was first launched in 2016. It allows natural light to pass through while still storing thermal energy.

 

Researchers at KTH's Wallenberg Wood Science Centre used fossil-based polymers in earlier models of the composite. The researchers have now successfully tested an environmentally safe alternative: limonene acrylate, a limonene-derived monomer. They published their findings in the journal Advanced Science.

 

"The current limonene acrylate is made from organic citruses, such as peel waste from the orange juice industry," says Céline Montanari, lead author and Ph.D. student.

 

The polymer that restores the strength of delignified wood while allowing light to pass through is made from an extract from orange juice processing.

 

According to the researchers, the modern composite has a 90 percent optical transmittance at 1.2 mm thickness and a 30 percent haze. Unlike other translucent wood composites produced in the last five years, the material manufactured at KTH is intended for structural use. With a power of 174 MPa (25.2 ksi) and an elasticity of 17 GPa, it demonstrates heavy-duty mechanical efficiency (or about 2.5 Mpsi).

 

But, according to Professor Lars Berglund, head of the KTH's Department of Fibre and Polymer Technology, "sustainability has always been a focus for the study community."

 

"One of the problems we've had in producing organic translucent wood has been replacing fossil-based polymers," Berglund says.

 

According to him, environmental concerns and so-called green chemistry pervade the whole project. No solvents are used in the production of the products, and all additives are obtained from bio-based raw materials.

 

 https://www.natureworldnews.com/articles/45941/20210506/citrus-derivatives-can-create-100-renewable-transparent-wood.htm

 

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Graphene could find use in lightweight ballistic body armor

 

December 1st, 2014

While graphene is already known for being the world's strongest material, most studies have focused on its tensile strength – that's the maximum stress that it can withstand while being pulled or stretched, before failing. According to studies conducted at Houston's Rice University, however, its ability to absorb sudden impacts hadn't previously been thoroughly explored. As it turns out, the material is 10 times better than steel at dissipating kinetic energy. That could make it an excellent choice for lightweight ballistic body armor.

http://www.gizmag.com/graphene-bulletproof-armor/35004/?li_source=LI&li_medium=default-widget

 

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Carbyne is stronger than any known material

 

August 20, 2013 

 

 

 A paper on Arxiv presents a detailed look at the properties of carbyne, stronger than graphene and diamond, a true supermaterial. The paper is titled, "Carbyne from first principles: Chain of C atoms, a nanorod or a nanorope?" Authors are Mingjie Liu, Vasilii I. Artyukhov, Hoonkyung Lee, Fangbo Xu, and Boris I. Yakobson, from Rice University, in Houston, from the departments of mechanical engineering and materials science, chemistry, and the Smalley Institute for Nanoscale Science and Technology. They have calculated the properties of carbyne. Described as a chain of carbon atoms that are linked by alternate triple and single bonds or by consecutive double bonds, carbyne is of special interest, chemists find, because it is stronger, and stiffer than anything that they have seen before. The discovery of carbyne is not entirely new. Explorations of carbyne have their own history.

 

 http://phys.org/news/2013-08-carbyne-stronger-material.html

 

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“Unprecedented Mechanical Behavior of Diamond” – Scientists Discover Diamond Can Be Bent at the Nanoscale

 

February 6, 2020

 

“Diamond is the frontrunner for emerging applications in nanophotonics, microelectrical mechanical systems, and radiation shielding. This means a diverse range of applications in medical imaging, temperature sensing, and quantum information processing and communication.

 

“It also means we need to know how these materials behave at the nanoscale — how they bend, deform, change state, and crack. And we haven’t had this information for single-crystal diamonds,” Regan said.

 

The team, which included scientists from Curtin University and Sydney University, worked with diamond nanoneedles, approximately 20nm in length, or 10,000 times smaller than a human hair. The nanoparticles were subjected to an electric field force from a scanning electron microscope. By using this unique, non-destructive and reversible technique, the researchers were able to demonstrate that the nanoneedles, also known as diamond nanopillars, could be bent in the middle to 90 degrees without fracturing.

 

As well as this elastic deformation, the researchers observed a new form of plastic deformation when the nanopillar dimensions and crystallographic orientation of the diamond occurred together in a particular way.

 
https://scitechdaily.com/unprecedented-mechanical-behavior-of-diamond-scientists-discover-diamond-can-be-bent-at-the-nanoscale/

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Programmable soft material bends, bounces and absorbs energy on demand

  

August 7, 2025 

 

Scientists at Lawrence Livermore National Laboratory (LLNL) and their collaborators have created a new class of programmable soft materials that can absorb impacts like never before, while also changing shape when heated.

 

The research—which includes collaborators from Harvard University, the California Institute of Technology (Caltech), Sandia National Laboratories and Oregon State University—opens the door to smarter, lighter and more resilient materials that respond to the world around them. The research is published in the journal Advanced Materials.

 

Built from liquid crystal elastomers (LCEs)—rubbery polymers that shift in response to heat, light or stress—the team 3D-printed the materials into carefully engineered lattice structures. These lattices can be designed to absorb energy, stiffen, soften or even change shape, depending on their architecture and environmental conditions.

 

https://phys.org/news/2025-08-programmable-soft-material-absorbs-energy.html 

 

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Tubulane Inspired Ultrahard Polymers Are Full of Holes, but Stop Bullets Better Than Solid Materials

 

November 14, 2019

 

Theoretical tubulanes inspire ultrahard polymers: Rice University-printed sample is full of holes, but stops bullets better than solid materials.

 

A lightweight material full of holes is nearly as hard as a diamond. The mere dents left by speeding bullets prove it.

 

Researchers at Rice University’s Brown School of Engineering and their colleagues are testing polymers based on tubulanes, theoretical structures of crosslinked carbon nanotubes predicted to have extraordinary strength.

 

They fired projectiles into patterned and solid cubes at 5.8 kilometers per second (~21,000 km/h or ~13,000 mph) and the results were impressive. For the patterned cube, the bullet was stuck in the second layer of the structure, while in the solid block, cracks propagated through the whole structure.

 

The Rice lab of materials scientist Pulickel Ajayan found tubulanes can be mimicked as scaled-up, 3D-printed polymer blocks that prove to be better at deflecting projectiles than the same material without holes. The blocks are also highly compressible without breaking apart.

 

https://scitechdaily.com/tubulane-inspired-ultrahard-polymers-are-full-of-holes-but-stop-bullets-better-than-solid-materials/

 

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Lightweight metal foam turns armor-piercing bullets into dust

 

April 10, 2016 

 http://newatlas.com/metal-foam-bullets/42731/

 

 
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Scientists 3D-Print Foam That Repairs Itself

 

April 5, 2025 

 

https://scitechdaily.com/scientists-3d-print-foam-that-repairs-itself/

 

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Bacterial Armor Holds Clues for Self-Assembling Nanostructures

 

 February 11, 2015

 

Imagine thousands of copies of a single protein organizing into a coat of chainmail armor that protects the wearer from harsh and ever-changing environmental conditions. That is the case for many microorganisms. In a new study, researchers with the U.S. Department of Energy (DOE)’s Lawrence Berkeley National Laboratory (Berkeley Lab) have uncovered key details in this natural process that can be used for the self-assembly of nanomaterials into complex two- and three-dimensional structures.


Caroline Ajo-Franklin, a chemist and synthetic biologist at Berkeley Lab’s Molecular Foundry, led this study in which high-throughput light scattering measurements were used to investigate the self-assembly of 2D nanosheets from a common bacterial surface layer (S-layer) protein. This protein, called “SbpA,” forms the protective armor for Lysinibacillus sphaericus, a soil bacterium used as a toxin to control mosquitoes. Their investigation revealed that calcium ions play a key role in how this armor assembles. Two key roles actually.
“Calcium ions not only trigger the folding of the protein into the correct shape for nanosheet formation, but also serve to bind the nanosheets together,” Ajo-Franklin says. “By establishing and using light scattering as a proxy for SbpA nanosheet formation, we were able to determine how varying the concentrations of calcium ions and SbpA affects the size and shape of the S-layer armor.”
 

http://newscenter.lbl.gov/2015/02/11/bacterial-armor/

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Mesospheres in nano-armor:

 

Copyright © 2009

http://www.sciencedirect.com/science/article/pii/S002197970901090X



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Sweden Invents a Revolutionary Anti Bullet Wall, Saab Barracuda Soft Armour

 Oct 23, 2014

https://www.youtube.com/watch?v=OuQOmOBayBA




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Hypersonic Vibrations of Ag@SiO₂ (Cubic Core)−Shell Nanospheres

 

Copyright © 2010

http://pubs.acs.org/doi/abs/10.1021/nn102581g

 


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DARPA seeks high-tech alternatives to armor

 

August 20, 2014

As a quick visit to any armored division will make obvious, tanks are big ... really big. A Challenger 2 main battle tank, for example, weighs 62.5 tonnes (68.9 tons) and costs about £4.2 million (US$7 million). And as anti-tank weapons get better, tanks can only get bigger. To avoid armies of tomorrow having to pay for land-going battleships, DARPA’s Ground X-Vehicle Technology (GXV-T) program aims at developing lighter, more agile successors to the tank that protect themselves with more than ever-thicker walls of steel.

http://www.gizmag.com/darpa-gxv-t-tank-armor/33404/

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Liquid metal could be used to create morphing electronics

 

 September 21, 2014 

 

 

 http://www.gizmag.com/liquid-metal-morphing-electronics/33836/

 

Who could forget the scene in Terminator 2: Judgement Day where the shape-shifting T-1000 reassembles itself from thousands of blobs of molten metal? Researchers from North Carolina State University (NCSU) have taken the first steps to such science fiction becoming reality by developing a way to control the surface tension of liquid metals with the application of very low voltages. This may offer opportunities in a new field of morphing electronic circuits, self-healing electronics, or – one day – maybe even self-assembling terminator-style robots.

The liquid metal used by the researchers was an alloy of gallium and indium. Gallium is liquid just above room temperature at about 29° C (84° F), while Indium has a much higher melting point at around 156° C (312° F), yet when mixed together, they form an alloy that is liquid at room temperature. In other words, a eutectic alloy – one that is composed of metals with disparate melting points that, when combined, melt as a whole at a specific temperature.

Another important aspect of this eutectic alloy, and one that the researchers sought to exploit in their experiments, is its exceptionally high surface tension of approximately 500 millinewtons per meter (mN/m). The consequence of this is that a blob of this alloy resting on a surface will tend to form an almost spherical ball and hold its shape if undisturbed...

 


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Squid inspires camouflaging smart materials

 

June 15, 2015

 http://phys.org/news/2015-06-squid-camouflaging-smart-materials.html

 

Three prototype artificial cephalopod chromatophores are shown in unactuated states. The chromatophores are made from dielectric elastomer using tape coated with black carbon grease electrodes.

- The researchers have shown the artificial skin, made from electroactive dielectric elastomer, a soft, compliant smart material, can effectively copy the action of biological chromatophores. Chromatophores are small pigmented cells embedded on cephalopods skin which can expand and contract and that work together to change skin colour and texture.

The system achieves the dynamic pattern generation by using simple local rules in the artificial chromatophore cells, so that they can sense their surroundings and manipulate their change. By modelling sets of artificial chromatophores in linear arrays of cells, the researchers explored whether the system was capable of producing a variety of patterns...



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Liquid Armor

 

2009

 https://www.youtube.com/watch?v=rYIWfn2Jz2g

 

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Liquid Armor

 2012

 https://www.youtube.com/watch?v=6md1wgyo3Ik


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How Liquid Body Armor Works

 

http://science.howstuffworks.com/liquid-body-armor1.htm
 

The fluid used in body armor is made of silica particles suspended in polyethylene glycol. Silica is a component of sand and quartz, and polyethylene glycol is a polymer commonly used in laxatives and lubricants. The silica particles are only a few nanometers in diameter, so many reports describe this fluid as a form of nanotechnology.

To make liquid body armor using shear-thickening fluid, researchers first dilute the fluid in ethanol. They saturate the Kevlar with the diluted fluid and place it in an oven to evaporate the ethanol. The STF then permeates the Kevlar, and the Kevlar strands hold the particle-filled fluid in place. When an object strikes or stabs the Kevlar, the fluid immediately hardens, making the Kevlar stronger.

Other Uses for MR Fluids MR fluids have numerous uses besides strengthening body armor. Their ability to change from liquids to semisolids almost instantly makes them useful for dampening impacts and vibrations in items like:

 

• Car shock absorbers
• Washing machines
• Prosthetic limbs
• Bridges

 

Since it can instantly and reversibly change shape, it could also be used to create scrolling Braille displays or reconfigurable molds.

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Engineers Create New Liquid Safety Cushioning Technology

July 17, 2023

The discovery that football players were unknowingly acquiring permanent brain damage as they racked up head hits throughout their professional careers created a rush to design better head protection. One of these inventions is nanofoam, the material on the inside of football helmets.

Thanks to mechanical and aerospace engineering associate professor Baoxing Xu at the University of Virginia and his research team, nanofoam just received a big upgrade and protective sports equipment could, too. This newly invented design integrates nanofoam with “non-wetting ionized liquid," a form of water that Xu and his research team now know blends perfectly with nanofoam to create a liquid cushion. This versatile and responsive material will give better protection to athletes and is promising for use in protecting car occupants and aiding hospital patients using wearable medical devices.

https://www.technologynetworks.com/applied-sciences/news/engineers-create-new-liquid-safety-cushioning-technology-376246

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Smart Materials (4 of 5): Magneto Rheological (MR) Fluid

 May 30, 2011

 https://www.youtube.com/watch?v=SBXQ-6uI8GY&list=PLQoTHqAEU9OSjWhEvxWS5PIka1lSQrEZ8&index=4

 


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Smart materials (2 of 5): Battle Jacket, Self-healing protective coating

 

 May 30, 2011

 

https://www.youtube.com/watch?v=R6qHY1H6piE&index=2&list=PLQoTHqAEU9OSjWhEvxWS5PIka1lSQrEZ8

 

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We can even make tanks go invisible to the eye with new technology.

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Obrum ADVANCED STEALTH Main Battle Tank Marketing video NEW challenger to abrams and merkava tank

 

https://www.youtube.com/watch?v=b-LupA0YkeU

 

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Quantum Stealth material designed to make target invisible

 

December 16, 2012 

 

 

 Scientists are exploring better methods of camouflage, a so-called scientific invisibility cloak, and news has spread fast about a Canadian company with substantial claims on how far they have come with camouflage technology. The company, HyperStealth Biotechnology, has developed Quantum Stealth camouflage material, which renders its wearers invisible by bending light waves around them. Their work has obvious implications for the defense industry. How can the enemy hit targets they cannot see or defend themselves from attackers who are invisible? Theoretically, any soldier could put on the material and get it working with no power source required.

 

http://phys.org/news/2012-12-quantum-stealth-material-invisible.html

 

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With new advances in armor technology, we are able to make tanks do many different tasks, that were not possible before. This includes advanced mine sweeping tanks, to the tanks such as the Crusher.

 

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Chobham armour

 http://en.wikipedia.org/wiki/Chobham_armour




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Many natural elements react with these synthetic compounds differently in the environment. It would take years of research to find out how many of these different natural compounds would react. This also includes other synthetic compounds, such as pesticides and genetically modified organisms. This is why I have stated that we need to take a step back for a moment on much of the genetic modification being done in food. This also includes other nano and bio-technology research in all fields of genetic modification.


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Laser technique improves ultra-high temperature ceramic manufacturing for space and defense applications

May 29, 2025

https://news.ncsu.edu/2025/05/laser-extreme-ceramics/

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Plants you can wear: Hydrogel material weaves seeds into textiles 

07/05/2025

Wearable Flora: The Future of Fashion is Growing on You

Imagine strolling through a bustling street, dressed in a garment that not only turns heads but also cultivates life. No longer the stuff of science fiction, thanks to the visionary minds at Cornell University's College of Human Ecology, this dream is blossoming into reality. Researchers have conjured up an astonishing technique that embeds seeds right into our clothes using hydrogel materials. From stylish hairbands to chic wristbands, and even trendy hats and sandals, these wearable marvels are capable of sprouting into living plants—yes, you heard that right! This groundbreaking innovation ushers in a new era of human-plant relationships, transitioning from mere utility to heartwarming symbiosis.

The project, aptly named "LivingLoom," is led by Jingwen Zhu under the astute guidance of Cindy Hsin-Liu Kao. This initiative envisions a harmonious future where humans and plants thrive together. Using a digital Jacquard loom, researchers weave hydrogel yarns—each lovingly integrated with seeds—into imaginative textile structures. Designed for growth, these creations only require a tad bit of nurturing to transform them into delightful sprouts. It’s an invitation to engage with nature in a dynamic and meaningful way.

So, how does this alchemical process work, you ask? It begins with a wet-spinning technique, where a polymer-hydrogel concoction, chock-full of chia seeds, is skillfully extruded into a coagulation bath. This bewitching process gives birth to fibers that are then woven into our beloved fabrics. The beauty of this method? It’s a well-established technique, beloved in the world of hydrogel fiber preparation, known for producing fibers ranging from a dainty few microns to several hundred. That’s some fine-quality fabric if you ask me!

The allure of these hydrogel textiles extends well beyond the realm of aesthetic appeal, beckoning insights into sustainable design and human-plant interactions. By incorporating living organisms into our fabric, we’re not just strutting around in our fashionable threads; we're championing ecological awareness. Imagine how this could revolutionize our perception of the garments we wear, making them instruments for a mutual benefit relationship with the flora that surrounds us.

But the innovation doesn’t end there. This remarkable technology holds implications that reach into the world of wearable sensing and monitoring. While this is a bit detached from the plants-in-clothes theme, it’s worth noting that hydrogel-based sensors are receiving well-deserved attention for their ability to detect environmental changes and stress in plants—real-time. Imagine a biohydrogel sensor keeping tabs on hydrogen peroxide levels in your garden plants, alerting you to any signs of stress before it’s too late—now that’s hands-on gardening at its finest!

As we leap into this brave new world of high-tech fabrics woven with natural elements, one thing is clear: we’re advancing towards a future where our everyday attire nurtures life and inspires a collective conversation about sustainability. By choosing to wear these living threads, we not only assert our unique style but also engage deeply with vital issues surrounding our environment and our connection to the natural world. It’s a win-win, making fashion an extension of our values rather than a hollow garment stripped of meaning.

The integration of seeds into textiles is merely the tip of the iceberg. It's a precursor to an exciting journey awaiting us—one filled with limitless possibilities in textile science, wearable technology, and environmental stewardship. As we forge ahead, it’s thrilling to consider how these living garments could transform not only our fashion choices but our daily lives and our attitudes toward nature.

In conclusion, this concept of plants you can wear transcends simple labels like fashion or technology; it’s about redefining our connection to the world around us. By embracing such groundbreaking innovations, we take one step closer to a future anchored in sustainability and mutualism—a future where our creativity and nature coexist beautifully. It’s about harmony, folks, and the blending of life’s richest elements. 

https://libertad.land/archives/2140

 

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Nano-Chainmail Unveiled: Revolutionary Material for Lightweight, Tough Protection

 

 January 16, 2025

 

Northwestern University researchers have achieved a groundbreaking development in materials science with the creation of a two-dimensional, mechanically interlocked polymer that mirrors the robust, flexible properties of chainmail.

 

This novel material, boasting the highest density of mechanical bonds ever recorded, promises revolutionary applications in lightweight body armor and other high-demand fields.

 

2D Interlocked Materials

 

A Northwestern University-led research team has achieved a remarkable feat of chemistry by creating the first two-dimensional (2D) mechanically interlocked material.

 

This nanoscale innovation, resembling the interlocking links of chainmail, boasts exceptional flexibility and strength. With further refinement, it shows great potential for applications in lightweight, high-performance body armor and other demanding uses that require materials to be both tough and flexible.

 

Published today (January 16) in the journal Science, the study establishes several key firsts in the field. This is not only the first-ever 2D mechanically interlocked polymer but also a material with an unprecedented density of 100 trillion mechanical bonds per square centimeter — the highest ever achieved. The research team accomplished this using a novel, efficient, and scalable polymerization process, paving the way for large-scale production...

 
https://scitechdaily.com/nano-chainmail-unveiled-revolutionary-material-for-lightweight-tough-protection/

 

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New material could better protect soldiers, athletes and motorists

 

July 20, 2021

 

 

SOLDIERS, athletes, and motorists could lead safer lives thanks to a new process that could lead to more efficient and re-useable protection from shock and impact, explosion, and vibration, according to a new study.

 

Pressurized insertion of aqueous solutions into water-repellent nanoporous materials, such as zeolites and metal-organic frameworks, could help to create high-performance energy absorbing systems.

 

An international research team experimented with hydrothermally stable zeolitic imidazolate frameworks (ZIFs) with a ‘hydrophobic’ cage-like molecular structure—finding that such systems are remarkably effective energy absorbers at realistic, high-rate loading conditions, and this phenomenon is associated with the water clustering and mobility in nanocages.

 

Researchers from the Universities of Birmingham and Oxford, together with Ghent University, Belgium, published their findings in Nature Materials.

 

https://cbn.co.za/featured/new-material-could-better-protect-soldiers-athletes-and-motorists/

 

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Multifunctional Nanofiber Protects Against Explosions – For Soldiers, Firefighters, Astronauts and More

 

June 29, 2020

 

https://scitechdaily.com/multifunctional-nanofiber-protects-against-explosions-for-soldiers-firefighters-astronauts-and-more/

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Atomic Armor for Next-Generation, Electron-Beam Accelerators

 

January 27, 2022

 

Advancement in single-atom layer graphene coatings improves accelerator electron source lifespans.

 

Protective coatings are common for many things in daily life that see a lot of use: we coat wood floors with finish; apply Teflon to the paint on cars; even use diamond coatings on medical devices. Protective coatings are also essential in many demanding research and industrial applications.

 

Now, researchers at Los Alamos National Laboratory have developed and tested an atomically thin graphene coating for next-generation, electron-beam accelerator equipment — perhaps the most challenging technical application of the technology, the success of which bears out the potential for “Atomic Armor” in a range of applications.

 

https://scitechdaily.com/atomic-armor-for-next-generation-electron-beam-accelerators/


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Chapter 3: Materials & fibers

 

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We see many toxins in everyday consumer items. Many plastics out on the market and synthetic fibers have problems coexisting and biodegrading properly.

We need sustainable materials that can be used in clothing, shoes, fibers,  plastics, including any material for consumer items. 

We can make organic linen from flax and hemp for fiber.

We can create tencel fiber from birch trees and eucalyptus trees for clothing. It is debated how tencel and plastics made from plant material could impact the environment. Many question if there is a more environmentally friendly version of tencel.
We are already putting a lot of stress on many of the forests of the world.  Whenever we harvest too many resources from forests it can cause problems. There is a sustainable way to harvest trees from forests. Currently tree harvesting around the world has been causing problems in different habitats.

We can even use banana fiber, coconut fiber and jute fiber for making clothing.

We can even use grass as a sustainable source for making baskets. An example would be alaffia for making grass baskets.

Cork leather and seaweed leather could be sustainable materials for mass-producing materials for clothing and fibers.

Many say that silk, is also a sustainable fiber. Some groups debate the ethical standards of how some ways silk is harvested.

Current artificial PVC leather on the market contains harmful chemicals. 

  

Even if we make an eco-friendly version of leather, such as seaweed leather. We must question the types of chemicals going into these materials.

 

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Dutch Students Make Leather from Fruit Waste

  

September 1, 2015

 

 http://www.greenoptimistic.com/leather-fruit-waste/#.Ve-t05e-2zk

They developed a method to produce a new material from the fruit and vegetable left-overs. As the name of the initiative suggests, the new material is called “fruit leather“, and it is created by processing spoiled biological plant waste. This new type of vegan leather can be used to make all sorts of products, from handbags to furniture, and it can potentially have the same quality as its animal ancestor after a few more improvements are made.

The young designers have not yet released their precise method, I am guessing because of a patent or a possibility for commercializing the product, but in general it involves cleaning, mashing, boiling and then drying of the waste.

 

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Many types of clothing that's labeled as organic is not fully organic or biodegradable. Many shirts labeled as organic cotton contain synthetic dyes on the organic cotton, including synthetic poly material used for stitching, labels and the printed images on the shirt. Kapok is another good natural fiber that can be used for certain applications that cotton can be used for.

This is why when searching for organic clothing we must look at the organic materials, organic dyes, stitching, labels and buttons being used.  Even the grade of metal or materials (coconut buttons, wood buttons, stones, bone, etc ), that is used for making buttons.

 We need to make all clothing non-toxic for humans, including on how this material biodegrades in the environment. No one should have the chance to harm themselves, just from putting on an article of clothing. Everyone has the right to wear non-toxic clothing.

 


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Making clothes out of gelatin could reduce agricultural waste

 

June 24, 2015

 

 From gummy bears to silky mousses, gelatin is essential for making some of our favorite sweets. Now scientists are exploring another use for the common food ingredient: spinning it into yarn so it can be made into clothing. And because gelatin comes from livestock by-products, the new technique would provide an additional use for agricultural leftovers. The report appears in the ACS journal Biomacromolecules.

More than a century ago, the textile industry started using protein fibers from animals and vegetables such as casein from milk and zein from corn to make new kinds of fabrics. But synthetic fibers derived from petroleum products boomed and quickly eclipsed those efforts. Now, as consumers search for "greener" products, scientists have revived the idea of making fabrics from animal and plant proteins. Wendelin J. Stark and colleagues decided to try spinning yarn out of gelatin, which comes from collagen, an abundant protein in livestock by-products.

The researchers spun filaments of gelatin, twisted them into a yarn and then treated it with gaseous formaldehyde and lanolin (wool grease) to make it water-resistant. The resulting yarn was about as strong as a strand of merino wool. It was also just as warm when knitted into a glove.

http://phys.org/news/2015-06-gelatin-agricultural.html#jCp

 

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A leather and plastic alternative made of seaweed

28 January 2021 


Anna Watkins, a student at the University of Huddersfield in the UK, developed a seaweed based material that aims to replace materials like leather and plastic.

The aim of the project was to create a biomaterial to replace the often unsustainable materials used in fashion.

The main ingredient is powdered seaweed, often used as a gelling agent in food production. By heating this powder, it becomes a jelly-like substance that becomes firm within two minutes. The material can be poured in moulds, allowing for the creation of various products.

https://materialdistrict.com/article/a-leather-and-plastic-alternative-made-of-seaweed/

 

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What Is Cork Fabric?: Peeling Back The Layers On Cork Leather

13 April 2024


When it comes to fabrics, our faves are those that—like the Lorax—speak for the trees. So what better choice than a fabric that actually comes from them? We’re talking cork leather fabric.

Cork fabric is a tre(e)mendously useful material used for everything from bags and purses to yoga mats... 

https://www.sustainablejungle.com/what-is-cork-fabric/

 

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Jute Fiber: Properties, Uses, Benefits & Environmental Impact Explained

April 13, 2025

Top Uses of Jute Fiber

1. Textiles & Fashion

2. Packaging Industry

3. Home Furnishings

4. Agriculture

5. Paper Industry

6. Composite Materials

https://textilelisting.com/jute-fiber-properties-uses-benefits-environmental-impact-explained/

 

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What is Jute Rope Used for: 10 Surprising Uses! 

May 15, 2024

Introduction To Jute Rope

Home Decor Inspiration

Gardening Applications

Crafting With Jute

Packaging With A Twist

Fashion Accessories

Nautical Uses

Pet And Livestock Utilities

Theatrical And Cinematic Props

Survival And Outdoor Gear

https://yifarope.com/what-is-jute-rope-used-for/ 

 

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The Difference Between Jute and Other Natural Fibers: An Eco-Friendly Comparison

April 13, 2025

https://textilelisting.com/the-difference-between-jute-and-other-natural-fibers-an-eco-friendly-comparison/ 

 

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15 Sustainable Straw Bags for Trips to the Beach and Beyond

2022

Materials mentioned: 

Jute, Hemp, Rafia, sisal, seagrass, Iraca palm fibers, cotton canvas, Piaçava straw, Elephant swamp grass, banana leaf, maize, wild vine, fique, moriche (palm fiber) natural straw, Sabaii grass, Natural palm fiber,  natural fibers

https://consciousfashion.co/guides/straw-woven-beach-bags


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Finland chooses sustainable fashion -- a gown made of birch in time for the holidays 
 
10-Dec-2018 

https://www.eurekalert.org/news-releases/786664

 

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Fashion Fabrics Made From Wood Are Set To Double In Volume: What Does This Mean For Forests And Emissions? 

May 27, 2022

In the fast-growing next-gen materials market, cellulose fibers extracted from wood, old textiles, and even bacteria are performing akin to cotton, silk, and polyester. This offers an exciting opportunity to alleviate environmental problems caused by incumbent fibers, and at the core of this movement are man-made cellulosic fibers (MMCFs).

MMCFs include viscose, lyocell, modal, and acetate. Around 98% of these fibers are made from wood (usually eucalyptus), 1% is from bamboo, and less than 1% are from cellulose-rich waste (but Evrnu, Renewcell, Infinited Fiber, and others are working hard to raise that percentage). While the innovators forge this path, the MMCF market is set to grow from 6 to 10 million tonnes within 15 years, with recycled MMCFs (rMMCFs) likely to reach only a fraction of this volume.

So what types of MMCFs will hoover up this growth opportunity? Right now 40-45% will come from “conventional/unknown sources/processes”, which is shorthand for possibly toxic production methods and using ancient/endangered forest wood. And here exists a critical paradox: while next-gen MMCFs offer huge potential to replace damaging incumbent materials, stakeholders risk emboldening a market that is not ready to deliver on its low-impact promises, and may cause more harm before it realizes its potential for good.

https://www.forbes.com/sites/brookerobertsislam/2022/05/27/fashion-fabrics-made-from-wood-are-set-to-double-in-volume-what-does-this-mean-for-forests-and-emissions/

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Edible, Biodegradable Food Packaging Made From Milk Protein

June 10, 2025

Milk protein and plant-derived cellulose can be electrospun into thin fibers for use in biodegradable (and edible) materials, a new study has shown.

https://www.technologynetworks.com/applied-sciences/news/edible-biodegradable-food-packaging-made-from-milk-protein-400830

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With genetically modified soybeans in the industry, different companies try to use this technology to create plastics, including bacteria from soy.

Some think that it is not ethical to use bacteria made from genetically modified soy to make clothing people have stated that some GMO plants and bacteria were not properly tested in the environment. 

 
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MIT group explores bacteria use for comfort wear

 

October 30, 2015

 Now they are using the bacteria in a new way—it becomes a nanoactuator that expands and shrinks based on atmospheric moisture or the sweat of the skin. As Gizmodo wrote, the team was interested in the possibilities: "if natto's expansion and contraction could be carefully calibrated, perhaps it could act more like a machine than an unpredictable organism. Perhaps it could act more like an actuator."
The team said, "We introduce a specific type of living cells as nanoactuators that react to body temperature and humidity change. The living nanoactuator can be controlled by electrical signal and communicate with the virtual world as well." A digital printing system and design simulation software were developed too.

http://techxplore.com/news/2015-10-mit-group-explores-bacteria-comfort.html

 

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We need sustainable materials to replace many toxins in plastics and fiberglass for boats, vehicles and everyday consumer items that you can think of. 


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Best and Most Sustainable Insulation: Safe, Eco-friendly, LEED Compliant, High R-Value


#1 :: ROCK WOOL Comfort Batt

KEY FEATURES

Composition: Natural rock and slag, a nontoxic and renewable resource
R-value per inch: 4

Cost per sq. ft. per R-rating: $0.06

One Community Priority ratings: 1st place in Durability, 2nd place in Health and Safety, Sustainability, and Cost

Unique Feature: Only company to place facilities strategically nearby local resources to minimize transportation energy

#2 :: Black Mountain USA Sheep Wool Insulation

KEY FEATURES

Composition: Made of 98% sheep wool, a natural and renewable resource

#3 :: Havelock Wool’s Sheep Wool

KEY FEATURES

Composition: Made of 100% sheep wool, a natural and renewable resource

#4 :: ROCKWOOL Comfort Board 80

KEY FEATURES

Composition: Made of rock wool, a sustainable and nontoxic natural resource

#5 :: DIY Aircrete (Aka AirCrete, Air Crete, Airkrete, AirKrete, Air Krete)

KEY FEATURES

Composition: cement, water, and foam

#6 :: Hempitecture HempWool Fiber Batt

KEY FEATURES

Composition: 92% hemp fibers, a renewable and sustainable process

#7 :: Owens Corning ThermaFiber Ultra Batt

KEY FEATURES

Composition: 96+% charge (primarily recycled blast furnace slag, supplemented with fieldspar and trap rock) and less than 4% binder (silane, surfactant, and other)

#8 :: ThermaCork

KEY FEATURES

Composition: Made entirely of cork and water, without any additive or adhesives

#9 :: Hempitecture HempCrete

KEY FEATURES

Composition: Made of limestone and woody core fibers of hemp stalks

#10 :: Air Krete GREENsulation

KEY FEATURES

Composition: Made of cement, water, and foam

CONS FOR THIS INSULATION

Claims to be nontoxic, though magnesium oxide is on OSHA’s regulated Hazardous Items List

#11 :: Straw Bales

KEY FEATURES

Composition: 100% straw

CONS FOR THIS INSULATION

If the straw gets wet it becomes susceptible to mold growth

#12 :: Bonded Logic UltraTouch Denim Insulation (Prefer Organic Denim)

KEY FEATURES

Composition: 80% post-consumer Recycled Fiber Products (i.e. denim, cotton), ammonium sulfate, binder fiber, and boric acid (fire retardant, antifungal, antimicrobial)

CONS FOR THIS INSULATION

Post-consumer denim could contain residues of chemically-based laundry products, which likely is not widely toxic but might be a potential problem for those who are chemically sensitive

Though cotton has a small carbon footprint, the processing of dying the denim results in significant emissions

Should be biodegradable when its time to dispose of, however, there are environmental concerns of various chemicals in the recycled materials

Very poor moisture management, since it’s cotton-based it does not dry easily once it becomes wet

    No vapor barrier, likely requiring additional installation


#13 :: Kenafcrete

KEY FEATURES

Composition: Kenaf wood core chips, Hydrated lime, and Water

#14 :: Greenfiber Blended Blow-In Insulation

KEY FEATURES

Composition: 85% recycled newsprint (cellulose fiber), <10% boric acid (for flame retardant), and <10% ammonium sulfate

CONS FOR THIS INSULATION

Toxicity issues, can cause eye and skin irritation, difficulty with breath when inhaled, diarrhea or vomiting if ingested, and contains reproductive toxins

Concerns of mold growth due to being made of cellulose

Some materials have ecotoxicity concerns, making safe disposal questionable

May need to rent a blow-in machine for installation, slightly more involved of a process than other products

Less durable than other products, typical lifespan is 20-30 years

Poor sound absorbency

#15 :: Styrofoam Board Insulation (Debated)

CONS FOR THIS INSULATION

    Contains toxic chemicals that are released when exposed to excessive heat, including 1,1,1,2-Tetrafluoroethane, which can cause dizziness or asphyxiation

    Contains teratogenic (causing harm to fetuses) and reproductive toxins

    Mediocre fire resistance (Class A or B), customer reviews cite flammability concerns

    Only made of 20% recycled material, not a renewable resource

    Manufacturing is energy-intensive

    May contain HCFCs, which deplete the ozone layer

    Non-biodegradable, so when disposed of it accumulates in the environment and leaches toxic chemicals into ecosystems

    Average price per sq. ft. per R-rating

    Poor sound absorbency


#16 :: Aspen Aerogels Spaceloft (Debated)

KEY FEATURES

    Composition: Made primarily of 40-50% Synthetic Amorphous Silica, Methylsilylated Silica, Polyethylene Terephthalate (PET or polyester), and Fibrous Glass.

CONS FOR THIS INSULATION

    Minor exposure concerns, inhalation of dust can cause irritation, eye contact can cause temporary redness

    Made of synthetic, non-renewable resources

    Production and transportation processes are energy-intensive

    Adverse atmospheric effects, Global Warming Potential of 4.3 (highest of any product)
    Poor price per sq. ft. per R-rating

    High density, making transportation and installation more challenging
    Poor sound absorbency

    No vapor barrier, likely requiring additional installation


#17 :: Fiberglass Insulation (Debated)


CONS FOR THIS INSULATION

    Short term toxicity concerns such as rashes, itches, throat irritation, and aggravation of asthma

    Though the insulation is mold resistant, many products have a paper backing, which is susceptible to mold growth

    Mostly nonrenewable/non-recycled materials, may contain 0-30% recycled materials (such as crushed recycled glass)

    Energy-intensive manufacturing process

    Non-biodegrable and may contain toxins that can leech into the soil and cause harm to animals and humans

    Though DIY installation is possible, it is more complicated and often it is recommended to hire technicians to install it

    Less durable, average lifespan of 15 years

    Poor moisture management, when it gets wet its insulative properties are impaired and it can slump or sag

    No vapor barrier, likely requiring additional installation


#18 :: Demilec HeatlokSoya 2000 (Debated)

CONS FOR THIS INSULATION

    Significant short-term toxicity concerns, including skin irritation, headaches and dizziness if inhaled, and diarrhea and vomiting if ingested

    Contains chemicals suspected to be carcinogenic and toxic to internal organs

    Only 22% of the materials are recyclable or renewable

    Uses a blowing agent that contributes to global warming

    May be harmful to the environment if disposed of in large quantities, especially hazardous to fish
    Cost not listed anywhere

    DIY installation not possible, it’s performed by technicians


#19 :: DIY Recycled Styrofoam (Debated)

CONS FOR THIS INSULATION

    Contains toxic chemicals that are released when exposed to excessive heat, including 1,1,1,2-Tetrafluoroethane, which can cause dizziness or asphyxiation

    Contains teratogenic (causing harm to fetuses) and reproductive toxins

    Extremely flammable, and releases dangerous gases when burned

    May contain HCFCs, which deplete the ozone layer

    Non biodegradable, so when disposed of it accumulates in the environment and leaches toxic chemicals into ecosystems

    Unknown price, very variable

    Unknown durability, new styrofoam insulation can last 50 years, but DIY insulation likely won’t last as long

    Unknown moisture management abilities

    Poor sound absorbency

    No vapor barrier, likely requiring additional installation


#20 :: Icynene Classic Plus (Debated)

KEY FEATURES

    Composition: -Diphenylmethane-4,4′-diisocyanate, Benzene -1-isocyanato-2-[(4-isocyanatophenyl)methyl]-.

    R-value per inch: 3.7

    Cost per sq. ft. per R-rating: Unknown

    One Community Priority ratings: Last place in DIY

    Unique feature: Claims to have the lowest Global Warming Potential (GWP of 1) value for foam insulation products


CONS FOR THIS INSULATION

    Various short-term toxicity concerns including irritation of the eyes, nose, skin, and throat

    Contains carcinogens and various hazardous decomposition products such as carbon monoxide, hydrogen cyanide, and nitrogen oxides

    No renewable or recyclable materials

    Has a Global Warming Potential of 1

    Nonbiodegrable and may meet the definition of hazardous waste in many cases
    Unknown price

    DIY installation not possible, technicians perform installation
    Poor sound absorbency

    No vapor barrier, likely requiring additional installation

 

https://onecommunityglobal.org/most-sustainable-insulation/ 

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10 Modern Mud House Design Ideas, towards Sustainable Buildings

March 3, 2024


1. Designing with Insulation Properties

2. Strawbale Technique

Straw-bale construction is a building method that uses bales of straw (commonly wheat, rice, rye, and oats) as structural elements, building insulation, or both.

It is a construction method that is commonly used in natural building or “brown” construction projects. Research has shown that straw-bale construction is a sustainable method for building, from the standpoint of both materials and energy needed for heating and cooling.

Advantages of Strawbale Technique:

    Strawbales are made from a waste product.

    Homes insulated with straw bales can have insulation values of R-30 or more. The thickness of the wall helps to reflect sunlight throughout the room.

    Strawbales have low-embodied energy.

    Strawbales are 100% biodegradable when the time comes.

3. Use of Conventional Materials

Unlike traditional mud houses, modern mud houses can incorporate conventional materials to make them fire-resistant. Builders construct a fire-resistant modern mud house with lime, cement, or sand. 

They can also be designed with features like metal roofs, fire-resistant doors, and windows made of tempered glass. This helps to increase the durability and density of the walls, making them more resistant to an inferno.

It is vital to note that while contemporary mud houses can be fire-resistant, they still require proper maintenance to ensure their safety.

4. Use of Soundproof

5. Rammed Earth Technique

Rammed earth is a method of building walls on-site by compacting a selected mixture of earth, sand, and aggregate in layers between the forms. Each layer is approximately 15cm deep. As each form is filled out, another form is placed above it, and the process begins again.

Until the desired wall height is reached this process is continued. A wider range of soils are suitable when a small amount of cement is added to the mix. The result, known as ‘stabilized rammed earth’, is an extremely durable and attractive masonry product with numerous benefits.

From an environmental standpoint, reducing or eliminating Portland cement is advantageous because it lowers the energy embodied in the final product. Using soils directly from the site represents an environmental advantage for the same reason.

Over 7% of global CO2 emissions come from the production of cement. Stabilized rammed earth creates beautiful and unique buildings while at the same time providing a swathe of benefits to meet the varied demands of homeowners, artists, industry, architects, and engineers.

Advantages of Rammed Earth Walls:

    Rammed earth walls contain excellent thermal mass.

    Buildings made from rammed earth have more durability.

    It has a high fire-resistance rating and the walls are water-repellent.

    These walls are load-bearing walls; you can make a multi-story house.

    The nature of rammed earth is that it is non-toxic.

6. Designing with Termite-Resistant Materials

7. Use of Proper Ventilation

Proper ventilation prevents moisture build-up and promotes air circulation. Use exhaust fans and open windows to ensure adequate ventilation throughout the house.

8. Cob Technique

Cob is an earth-building technique based on a mixture of clay, sand, straw, and water. The mixture is kneaded with hands, feet, or simple tools; subsequently, lumps are made that are then compressed together and shaped by hand, forming foundations and walls.

The walls of a cob house are generally about 24 inches (61 cm) thick, and the windows are correspondingly deep-set, giving the home a characteristic internal appearance.

The contents of subsoil naturally vary, and if it does not contain the right mixture, it can be modified with sand or clay. Cob is fireproof, resistant to seismic activity, and uses low-cost materials, although it is very labor intensive.

It can be used to create artistic and sculptural forms, and its use has been revived in recent years by the natural building and sustainability movements.

9. Use of Waterproof

10. Earthbag Structure

Earthbag construction is an inexpensive building method using mostly local soil to create structures that are both strong and can be quickly built.

It is a natural building technique developed from historic military bunker construction techniques and temporary flood-control dike building methods.

The technique requires very basic construction materials; such as sturdy sacks filled with organic material usually available on site.

https://environmentgo.com/modern-mud-house-design-ideas-towards-sustainable-buildings/

 

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Ex-MIT scientist reveals how safe, comfortable homes can be built from mud: 'Yes, you can have it all'

June 15, 2025

https://www.thecooldown.com/green-tech/modern-mud-homes-construction-techniques-costs/

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Building Sustainable Mud Homes: A Comprehensive Guide

September 16, 2023

https://toolack.com/mud-homes/

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From Africa Mud Huts to Modern Eco Homes: The Revival of Earthen Architecture 

April 22, 2025

https://echoesofafrika.com/africa-mud-huts-sustainable-architecture-africa/

 

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Embracing Sustainable Living with Modern Mud Houses

2024

https://www.lifestylemind.com/sustainable-lifestyle/eco-friendly-house/modern-mud-houses/

 

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Eco Friendly Mud House

October 25, 2024

https://environfriend.com/eco-friendly-mud-house/

 

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How to Build a Sustainable Home | The Magic of Mud

Mar 1, 2024

https://www.youtube.com/watch?v=ilMutLUcGH4

 

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Mud Homes: Nature’s Answer to Summer Heat

May 12, 2024

https://medium.com/@kristanvihaan11/mud-homes-natures-answer-to-summer-heat-844246913a51

 

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Novel cement lets buildings cool themselves

 

August 21, 2025 

 

https://techxplore.com/news/2025-08-cement-cool.html 

 

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Ancient Roman concrete could self-heal thanks to “hot mixing” with quicklime

 

Jan 6, 2023

 

 

 Raman microscopy on Roman concrete in Admir Masic's lab.

 

The famous Pantheon in Rome boasts the world's largest unreinforced concrete dome—an architectural marvel that has endured for millennia, thanks to the incredible durability of ancient Roman concrete. For decades, scientists have been trying to determine precisely what makes the material so durable. A new analysis of samples taken from the concrete walls of the Privernum archaeological site near Rome has yielded insights into those elusive manufacturing secrets. It seems the Romans employed "hot mixing" with quicklime, among other strategies, that gave the material self-healing functionality, according to a new paper published in the journal Science Advances.

 

As we've reported previously, like today's Portland cement (a basic ingredient of modern concrete), ancient Roman concrete was basically a mix of a semi-liquid mortar and aggregate. Portland cement is typically made by heating limestone and clay (as well as sandstone, ash, chalk, and iron) in a kiln. The resulting clinker is then ground into a fine powder, with just a touch of added gypsum—the better to achieve a smooth, flat surface. But the aggregate used to make Roman concrete was made up of fist-sized pieces of stone or bricks.

 

In his treatise De architectura (circa 30 CE), the Roman architect and engineer Vitruvius wrote about how to build concrete walls for funerary structures that could endure for a long time without falling into ruins. He recommended the walls be at least two feet thick, made of either "squared red stone or of brick or lava laid in courses." The brick or volcanic rock aggregate should be bound with mortar composed of hydrated lime and porous fragments of glass and crystals from volcanic eruptions (known as volcanic tephra).

 

Admir Masic, an environmental engineer at MIT, has studied ancient Roman concrete for several years. For instance, in 2019, Masic and two colleagues (MIT's Janille Maragh and Harvard's James Weaver) pioneered a new set of tools for analyzing Roman concrete samples from Privernum at multiple length scales—notably, Raman spectroscopy for chemical profiling and multi-detector energy dispersive spectroscopy (EDS) for phase mapping the material. 

 

Masic was also a co-author of a 2021 study analyzing samples of the ancient concrete used to build a 2,000-year-old mausoleum along the Appian Way in Rome known as the Tomb of Caecilia Metella, a noblewoman who lived in the first century CE. It's widely considered one of the best-preserved monuments on the Appian Way. They used the Advanced Light Source to identify the many different minerals contained in the samples and their orientation, as well as scanning electron microscopy.

 

They discovered that the tomb's mortar was similar to the walls of the Markets of Trajan: volcanic tephra from the Pozzolane Rosse pyroclastic flow, binding together large chunks of brick and lava aggregate. However, the tephra used in the tomb's mortar contained much more potassium-rich leucite. The potassium in the mortar dissolved in turn and effectively reconfigured the binding phase. Some parts remained intact after more than 2,000 years, while other areas looked wispier and showed some signs of splitting. In fact, the structure somewhat resembled nanocrystals. So the interfacial zones constantly evolve through long-term remodeling, reinforcing those interfacial zones.

 

https://arstechnica.com/science/2023/01/ancient-roman-concrete-could-self-heal-thanks-to-hot-mixing-with-quicklime/ 

 

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Roman concrete

 

https://en.wikipedia.org/wiki/Roman_concrete

 

Roman concrete, also called opus caementicium, was used in construction in ancient Rome. Like its modern equivalent, Roman concrete was based on a hydraulic-setting cement added to an aggregate. 

 

Many buildings and structures still standing today, such as bridges, reservoirs and aqueducts, were built with this material, which attests to both its versatility and its durability. Its strength was sometimes enhanced by the incorporation of pozzolanic ash where available (particularly in the Bay of Naples). The addition of ash prevented cracks from spreading. Recent research has shown that the incorporation of mixtures of different types of lime, forming conglomerate "clasts" allowed the concrete to self-repair cracks.^[1]

 

Roman concrete was in widespread use from about 150 BC;^[2] some scholars believe it was developed a century before that.^[3]

 

It was often used in combination with facings and other supports,^[4] and interiors were further decorated by stucco, fresco paintings, or colored marble. Further innovative developments in the material, part of the so-called concrete revolution, contributed to structurally complicated forms. The most prominent example of these is the Pantheon dome, the world's largest and oldest unreinforced concrete dome.^[5]

 

Roman concrete differs from modern concrete in that the aggregates often included larger components; hence, it was laid rather than poured.^[6] Roman concretes, like any hydraulic concrete, were usually able to set underwater, which was useful for bridges and other waterside construction.

 

Material properties

 

Roman concrete, like any concrete, consists of an aggregate and hydraulic mortar, a binder mixed with water that hardens over time. The composition of the aggregate varied, and included pieces of rock, ceramic tile, lime clasts, and brick rubble from the remains of previously demolished buildings. In Rome, readily available tuff was often used as an aggregate.^[14]

 

Gypsum and quicklime were used as binders.^[2] Volcanic dusts, called pozzolana or "pit sand", were favoured where they could be obtained. Pozzolana makes the concrete more resistant to salt water than modern-day concrete.^[15] Pozzolanic mortar had a high content of alumina and silica. 

 

Research in 2023 found that lime clasts, previously considered a sign of poor aggregation technique, react with water seeping into any cracks. This produces reactive calcium, which allows new calcium carbonate crystals to form and reseal the cracks.^[16] These lime clasts have a brittle structure that was most likely created in a "hot-mixing" technique with quicklime rather than traditional slaked lime, causing cracks to preferentially move through the lime clasts, thus potentially playing a critical role in the self-healing mechanism.^[1]

 

Concrete and, in particular, the hydraulic mortar responsible for its cohesion, was a type of structural ceramic whose utility derived largely from its rheological plasticity in the paste state. The setting and hardening of hydraulic cements derived from hydration of materials and the subsequent chemical and physical interaction of these hydration products. This differed from the setting of slaked lime mortars, the most common cements of the pre-Roman world. Once set, Roman concrete exhibited little plasticity, although it retained some resistance to tensile stresses.

 

The setting of pozzolanic cements has much in common with setting of their modern counterpart, Portland cement. The high silica composition of Roman pozzolana cements is very close to that of modern cement to which blast furnace slag, fly ash, or silica fume have been added. 

 

The strength and longevity of Roman 'marine' concrete is understood to benefit from a reaction of seawater with a mixture of volcanic ash and quicklime to create a rare crystal called tobermorite, which may resist fracturing. As seawater percolated within the tiny cracks in the Roman concrete, it reacted with phillipsite naturally found in the volcanic rock and created aluminous tobermorite crystals. The result is a candidate for "the most durable building material in human history". In contrast, modern concrete exposed to saltwater deteriorates within decades.^[17][18][19]

 

The Roman concrete at the Tomb of Caecilia Metella is another variation higher in potassium that triggered changes that "reinforce interfacial zones and potentially contribute to improved mechanical performance".

 

 

Seismic technology

 

For an environment as prone to earthquakes as the Italian peninsula, interruptions and internal constructions within walls and domes created discontinuities in the concrete mass. Portions of the building could then shift slightly when there was movement of the earth to accommodate such stresses, enhancing the overall strength of the structure. It was in this sense that bricks and concrete were flexible. It may have been precisely for this reason that, although many buildings sustained serious cracking from a variety of causes, they continue to stand to this day.^[21][10]

 

Another technology used to improve the strength and stability of concrete was its gradation in domes. One example is the Pantheon, where the aggregate of the upper dome region consists of alternating layers of light tuff and pumice, giving the concrete a density of 1,350 kilograms per cubic metre (84 lb/cu ft). The foundation of the structure used travertine as an aggregate, having a much higher density of 2,200 kilograms per cubic metre (140 lb/cu ft).

 

 

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Roman cement

 

https://en.wikipedia.org/wiki/Roman_cement

 

Roman cement is a substance developed by James Parker in the 1780s, being patented in 1796.^[1][2]

 

The name is misleading, as it is nothing like any material used by the Romans, but was a "natural cement" made by burning septaria – nodules that are found in certain clay deposits, and that contain both clay minerals and calcium carbonate. The burnt nodules were ground to a fine powder. This product, made into a mortar with sand, set in 5–15 minutes.^[1][2][3] The success of Roman cement led other manufacturers to develop rival products by burning artificial mixtures of clay and chalk.

 

History

 

There has been recent resurgence of interest in natural cements and Roman cements due mainly to the need for repair of façades done in this material in the 19th century. The major confusion involved for many people in this subject is the terminology used. Roman cement was originally the name given, by Parker, to the cement he patented which is a natural cement (i.e. it is a marl, or limestone containing integral clay, dug out of the ground, burnt and ground to a fine powder).

 

 

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Tobermorite 

 

https://en.wikipedia.org/wiki/Tobermorite

 

Tobermorite is a calcium silicate hydrate mineral with chemical formula: Ca₅Si₆O₁₆(OH)₂·4H₂O or Ca₅Si₆(O,OH)₁₈·5H₂O. 

 

Two structural varieties are distinguished: tobermorite-11 Å and tobermorite-14 Å. Tobermorite occurs in hydrated cement paste and can be found in nature as an alteration mineral in metamorphosed limestone and in skarn. It has been reported to occur in the Maqarin Area of north Jordan and in the Crestmore Quarry near Crestmore Heights, Riverside County, California. 

 

Tobermorite was first described in 1880 for an occurrence in Scotland, on the Isle of Mull, around the locality of Tobermory.

 

Use in Roman concrete

 

Aluminum-substituted tobermorite is understood to be a key ingredient responsible for the longevity of ancient undersea Roman concrete. The volcanic ash that Romans used for construction of sea walls contained phillipsite, and an interaction with sea water caused the crystalline structures in the concrete to expand and strengthen, making that material substantially more durable than modern concrete when exposed to sea water.

 

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Rice, beer, and urine mixed into ancient structures could help explain how they're still standing after millennia

Oct 3, 2023

Ancient builders across the world created structures that are still standing today, thousands of years later — from Roman engineers who poured thick concrete sea barriers, to Maya masons who crafted plaster sculptures to their gods, to Chinese builders who raised walls against invaders.

Yet scores of more recent structures are already staring down their expiration dates: The concrete that makes up much of our modern world has a lifespan of around 50 to 100 years.

A growing number of scientists have been studying materials from long-ago eras — chipping off chunks of buildings, poring over historical texts, mixing up copycat recipes — hoping to uncover how they've held up for millennia.

Tree bark, volcanic ash, rice, beer, and even urine

This reverse engineering has turned up a surprising list of ingredients that were mixed into old buildings — materials such as tree bark, volcanic ash, rice, beer, and even urine. These unexpected add-ins could be key to some pretty impressive properties, like the ability to get stronger over time and "heal" cracks when they form.

Figuring out how to copy those features could have real impacts today: While our modern concrete has the strength to hold up massive skyscrapers and heavy infrastructure, it can't compete with the endurance of these ancient materials.

And with the rising threats of climate change, there's a growing call to make construction more sustainable. A recent UN report estimates that the built environment is responsible for more than a third of global CO2 emissions — and cement production alone makes up more than 7% of those emissions.

"If you improve the properties of the material by using … traditional recipes from Maya people or the ancient Chinese, you can produce material that can be used in modern construction in a much more sustainable way," said Carlos Rodriguez-Navarro, a cultural heritage researcher at Spain's University of Granada.

Is ancient Roman concrete better than today's?

Many researchers have turned to the Romans for inspiration. Starting around 200 BCE, the architects of the Roman Empire were building impressive concrete structures that have stood the test of time — from the soaring dome of the Pantheon to the sturdy aqueducts that still carry water today.

Even in harbors, where seawater has been battering structures for ages, you'll find concrete "basically the way it was when it was poured 2,000 years ago," said John Oleson, an archaeologist at the University of Victoria in Canada.

Most modern concrete starts with Portland cement, a powder made by heating limestone and clay to super-high temperatures and grinding them up. That cement is mixed with water to create a chemically reactive paste. Then, chunks of material like rock and gravel are added, and the cement paste binds them into a concrete mass.

According to records from ancient architects like Vitruvius, the Roman process was similar. The ancient builders mixed materials like burnt limestone and volcanic sand with water and gravel, creating chemical reactions to bind everything together.

Now, scientists think they've found a key reason why some Roman concrete has held up structures for thousands of years: The ancient material has an unusual power to repair itself. Exactly how is not yet clear, but scientists are starting to find clues.

In a study published earlier this year, Admir Masic, a civil and environmental engineer at the Massachusetts Institute of Technology, proposed that this power comes from chunks of lime that are studded throughout the Roman material instead of being mixed in evenly. Researchers used to think these chunks were a sign that the Romans weren't mixing up their materials well enough.

Instead, after analyzing concrete samples from Privernum — an ancient city outside of Rome — the scientists found that the chunks could fuel the material's "self-healing" abilities. When cracks form, water is able to seep into the concrete, Masic explained. That water activates the leftover pockets of lime, sparking up new chemical reactions that can fill in the damaged sections.

Marie Jackson, a geologist at the University of Utah, has a different take. Her research has found that the key could be in the specific volcanic materials used by the Romans.

The builders would gather volcanic rocks left behind after eruptions to mix into their concrete. This naturally reactive material changes over time as it interacts with the elements, Jackson said, allowing it to seal cracks that develop.

The ability to keep adapting over time "is truly the genius of the material," Jackson said. "The concrete was so well designed that it sustains itself."

Using tree juice to make sculptures as strong as seashells

At Copan, a Maya site in Honduras, intricate lime sculptures and temples remain intact even after more than 1,000 years exposed to a hot, humid environment. And according to a study published earlier this year, the secret to these structures' longevity might lie in the trees that sprout among them.

Researchers here had a living link to the structures' creators: They met with local masons in Honduras who traced their lineage all the way back to the Maya builders, explained Rodriguez-Navarro, who worked on the study.

The masons suggested using extracts from local chukum and jiote trees in the lime mix. When researchers tested out the recipe — collecting bark, putting the chunks in water and adding the resulting tree "juice" into the material — they found the resulting plaster was especially durable against physical and chemical damage.

When scientists zoomed in, they saw that bits of organic material from the tree juice got incorporated into the plaster's molecular structure. In this way, the Maya plaster was able to mimic sturdy natural structures like seashells and sea urchin spines — and borrow some of their toughness, Rodriguez-Navarro said.

Studies have found all kinds of natural materials mixed into structures from long ago: fruit extracts, milk, cheese curd, beer, even dung and urine. The mortar that holds together some of China's most famous structures — including the Great Wall and the Forbidden City — includes traces of starch from sticky rice.

 

https://www.businessinsider.com/how-ancient-maya-roman-chinese-buildings-last-millennia-2023-10?op=1 

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Geopolymer

 

https://en.wikipedia.org/wiki/Geopolymer

 

A geopolymer is an inorganic, often ceramic-like material, that forms a stable, covalently bonded, non-crystalline to semi-crystalline network through the reaction of aluminosilicate materials with an alkaline or acidic solution. Many geopolymers may also be classified as alkali-activated cements or acid-activated binders.^[1] They are mainly produced by a chemical reaction between a chemically reactive aluminosilicate powder e.g. metakaolin or other clay-derived powders, natural pozzolan, or suitable glasses, and an aqueous solution (alkaline or acidic) that causes this powder to react and re-form into a solid monolith. The most common pathway to produce geopolymers is by the reaction of metakaolin with sodium silicate, which is an alkaline solution, but other processes are also possible.^[2]

 

The term geopolymer was coined by Joseph Davidovits in 1978 due to the rock-forming minerals of geological origin used in the synthesis process.^[3] These materials and associated terminology were popularized over the following decades via his work with the Institut Géopolymère (Geopolymer Institute).^[3]

 

Geopolymers are synthesized in one of two conditions: 

 

• in alkaline medium (Na⁺, K⁺, Li⁺, Cs⁺, Ca²⁺…)
• in acidic medium (phosphoric acid: H₃PO₄)

 

The alkaline route is the most important in terms of research and development and commercial applications. Details on the acidic route have also been published.^[4][5]

 

Commercially produced geopolymers may be used for fire- and heat-resistant coatings and adhesives, medicinal applications, high-temperature ceramics, new binders for fire-resistant fiber composites, toxic and radioactive waste encapsulation, and as cementing components in making or repairing concretes. Due to the increasing demand for low-emission building materials, geopolymer technology is being developed as a lower-CO₂ alternative to traditional Portland cement, with the potential for widespread use in concrete production.^[6] The properties and uses of geopolymers are being explored in many scientific and industrial disciplines such as modern inorganic chemistry, physical chemistry, colloid chemistry, mineralogy, geology, and in other types of engineering process technologies. In addition to their use in construction, geopolymers are utilized in resins, coatings, and adhesives for aerospace, automotive, and protective applications.

 

Composition

 

In the 1950s, Viktor Glukhovsky developed concrete materials originally known as "soil silicate concretes" and "soil cements",^[7] but since the introduction of the geopolymer concept by Joseph Davidovits, the terminology and definitions of the word geopolymer have become more diverse and often conflicting. The word geopolymer is sometimes used to refer to naturally occurring organic macromolecules;^[8] that sense of the word differs from the now-more-common use of this terminology to discuss inorganic materials which can have either cement-like or ceramic-like character. 

 

A geopolymer is essentially a mineral chemical compound or mixture of compounds consisting of repeating units, for example silico-oxide (-Si-O-Si-O-), silico-aluminate (-Si-O-Al-O-), ferro-silico-aluminate (-Fe-O-Si-O-Al-O-) or alumino-phosphate (-Al-O-P-O-), created through a process of geopolymerization.^[9] This method of describing mineral synthesis (geosynthesis) was first presented by Davidovits at an IUPAC symposium in 1976.^[10]

 

Even within the context of inorganic materials, there exist various definitions of the word geopolymer, which can include a relatively wide variety of low-temperature synthesized solid materials.^[11] The most typical geopolymer is generally described as resulting from the reaction between metakaolin (calcined kaolinitic clay) and a solution of sodium or potassium silicate (waterglass). Geopolymerization tends to result in a highly connected, disordered network of negatively charged tetrahedral oxide units balanced by the sodium or potassium ions. 

 

In the simplest form, an example chemical formula for a geopolymer can be written as Na₂O·Al₂O₃·nSiO₂·wH₂O, where n is usually between 2 and 4, and w is around 11-15. Geopolymers can be formulated with a wide variety of substituents in both the framework (silicon, aluminium) and non-framework (sodium) sites; most commonly potassium or calcium takes on the non-framework sites, but iron or phosphorus can in principle replace some of the aluminum or silicon.^{[citation needed]}

 

Geopolymerization usually occurs at ambient or slightly elevated temperature; the solid aluminosilicate raw materials (e.g. metakaolin) dissolve into the alkaline solution, then cross-link and polymerize into a growing gel phase, which then continues to set, harden, and gain strength.

 

 

Geopolymer synthesis

 

Covalent bonding

 

The fundamental unit within a geopolymer structure is a tetrahedral complex consisting of silicon or aluminum coordinated through covalent bonds to four oxygens. The geopolymer framework results from the cross-linking between these tetrahedra, which leads to a 3-dimensional aluminosilicate network, where the negative charge associated with tetrahedral aluminium is balanced by a small cationic species, most commonly an alkali metal cation (Na+, K+ etc). These alkali metal cations are often ion-exchangeable, as they are associated with, but only loosely bonded to the main covalent network, similarly to the non-framework cations present in zeolites. 

 

Oligomer formation

 

Geopolymerization is the process of combining many small molecules known as oligomers into a covalently bonded network. This reaction process takes place via formation of oligomers (dimer, trimer, tetramer, pentamer) which are believed to contribute to the formation of the actual structure of the three-dimensional macromolecular framework, either through direct incorporation or through rearrangement via monomeric species.^[12] These oligomers are named by some geopolymer chemists as sialates following the scheme developed by Davidovits,^[3] although this terminology is not universally accepted within the research community due in part to confusion with the earlier (1952) use of the same word to refer to the salts of the important biomolecule sialic acid.^[6]

 

The image shows five examples of small oligomeric potassium aluminosilicate species (labelled in the diagram according to the poly(sialate) / poly(sialate-siloxo) nomenclature), which are key intermediates in potassium-based alumino-silicate geopolymerization. The aqueous chemistry of aluminosilicate oligomers is complex,^[13] and plays an important role in the discussion of zeolite synthesis, a process which has many details in common with geopolymerization. 

 

Example of geopolymerization of a metakaolin precursor, in an alkaline medium^[14]

 

The reaction process broadly involves four main stages: 

 

• Alkaline hydrolysis of the layered structure of the calcined kaolinite
• Formation of monomeric and oligomeric species
• In the presence of waterglass (soluble potassium or sodium silicate), cyclic Al-Si structures can form (e.g. #5 in the figure), whereby the hydroxide is liberated by condensation reactions and can react again
• Geopolymerization (polycondensation) into polymeric 3D-networks. 

 

The reaction processes involving other aluminosilicate precursors (e.g. low-calcium fly ash, crushed or synthetic glasses, natural pozzolans) are broadly similar to the steps described above.

 

Geopolymer 3D-frameworks and water

 

Geopolymerization forms aluminosilicate frameworks that are similar to those of some rock-forming minerals, but lacking in long-range crystalline order, and generally containing water in both chemically bound sites (hydroxyl groups) and in molecular form as pore water. This water can be removed at temperatures above 100 – 200 °C. Cation hydration and the locations, and mobility of water molecules in pores are important for lower-temperature applications, such as in usage of geopolymers as cements.^[15][16] The figure shows a geopolymer containing both bound (Si-OH groups) and free water (left in the figure). Some water is associated with the framework similarly to zeolitic water, and some is in larger pores and can be readily released and removed. After dehydroxylation (and dehydration), generally above 250 °C, geopolymers can then crystallise above 800-1000 °C (depending on the nature of the alkali cation present).^[17]

 

Commercial applications

 

There exists a wide variety of potential and existing applications. Some of the geopolymer applications are still in development, whereas others are already industrialized and commercialized.^[18] They are listed in three major categories: 

 

Geopolymer cements and concretes

 

• Building materials (for example, clay bricks)
• Low-CO₂ cements and concretes
• Radioactive and toxic waste containment

 

Geopolymer resins and binders

 

• Fire-resistant materials, thermal insulation, foams
• Low-energy ceramic tiles, refractory items, thermal shock refractories
• High-tech resin systems, paints, binders and grouts
• Bio-technologies (materials for medicinal applications)
• Foundry industry (resins), tooling for the manufacture of organic fiber composites
• Composites for infrastructure repair and strengthening
• Fire-resistant and heat-resistant high-tech carbon-fiber composites for aircraft interiors and automobiles

 

Arts and archaeology

 

• Decorative stone artifacts, arts and decoration
• Cultural heritage, archaeology and history of sciences

 

Alkali-activated materials vs. geopolymer cements

 

There exists some confusion in the terminology applied to geopolymers, alkali-activated cements and concretes, and related materials, which have been described by a variety of names including also "soil silicate concretes" and "soil cements".^[7] Terminology related to alkali-activated materials or alkali-activated geopolymers is also in wide (but debated) use. These cements, sometimes abbreviated AAM, encompass the specific fields of alkali-activated slags, alkali-activated coal fly ashes, and various blended cementing systems. 

 

User-friendly alkaline-reagents

 

Geopolymerization uses chemical ingredients that may be dangerous and therefore requires some safety procedures. Material Safety rules classify the alkaline products in two categories: corrosive products (named here: hostile) and irritant products (named here: friendly).^[20]

 

The table lists some alkaline chemicals and their corresponding safety labels.^[22] Alkaline reagents belonging to the second (less elevated pH) class may also be termed as User-friendly, although the irritant nature of the alkaline component and the potential inhalation risk of powders still require the selection and use of appropriate personal protective equipment, as in any situation where chemicals or powders are handled. 

 

The development of some alkali-activated-cements, as shown in numerous published recipes (especially those based on fly ashes) use alkali silicates with molar ratios SiO₂:M₂O below 1.20, or are based on concentrated NaOH. These conditions are not considered so user-friendly as when more moderate pH values are used, and require careful consideration of chemical safety handling laws, regulations, and state directives. 

 

Conversely, geopolymer cement recipes employed in the field generally involve alkaline soluble silicates with starting molar ratios ranging from 1.45 to 1.95, particularly 1.60 to 1.85, i.e. user-friendly conditions. It may happen that for research, some laboratory recipes have molar ratios in the 1.20 to 1.45 range. 

 

Examples of materials that are sometimes called geopolymer cements

 

Commercial geopolymer cements were developed in the 1980s, of the type (K,Na,Ca)-aluminosilicate (or "slag-based geopolymer cement") and resulted from the research carried out by Joseph Davidovits and J.L. Sawyer at Lone Star Industries, USA, marketed as Pyrament® cement. The US patent 4,509,985 was granted on April 9, 1985 with the title 'Early high-strength mineral polymer'.^[23]

 

In the 1990s, using knowledge of the synthesis of zeolites from fly ashes, Wastiels et al.,^[24] Silverstrim et al.^[25] and van Jaarsveld and van Deventer^[26] developed geopolymeric fly ash-based cements. 

 

Materials based on siliceous (EN 197), also called class F (ASTM C618), fly ashes are known: 

 

• alkali-activated fly ash geopolymer:^[27]

In many (but not all) cases requires heat curing at 60-80°C; not manufactured separately as a cement, but rather produced directly as a fly-ash based concrete. NaOH + fly ash: partially-reacted fly ash particles embedded in an alumino-silicate gel with Si:Al= 1 to 2, zeolitic type (chabazite-Na and sodalite) structures.

 

• slag/fly ash-based geopolymer cement:^[28]

Room-temperature cement hardening. Alkali metal silicate solution + blast furnace slag + fly ash: fly ash particles embedded in a geopolymeric matrix with Si:Al ~ 2. Can be produced with "user-friendly" (not extremely high pH) activating solutions.

 

The properties of iron-containing "ferri-sialate"-based geopolymer cements are similar to those of rock-based geopolymer cements but involve geological elements, or metallurgical slags, with high iron oxide content. The hypothesised binder chemistry is (Ca,K)-(Fe-O)-(Si-O-Al-O).^[29]

 

Rock-based geopolymer cements can be formed by the reaction of natural pozzolanic materials under alkaline conditions,^[30] and geopolymers derived from calcined clays (e.g. metakaolin) can also be produced in the form of cements. 

 

CO₂ emissions during manufacturing

 

Geopolymer cements can be designed to have lower attributed CO₂ emissions compared to other widely used materials such as ordinary Portland cement.^[31] Geopolymers use industrial byproducts/waste containing aluminosilicate phases in manufacturing, which minimizes CO₂ emissions and therefore have a lower global warming potential (GWP).^[32] However, emissions still arise from various stages of production of geopolymer concretes. The extraction and processing of raw materials, such as fly ash, slag, or metakaolin, require energy and contribute to CO₂ emissions, though they are often industrial by-products with a lower environmental impact than clinker production in Portland concrete.^[33] A significant source of emissions in geopolymer concrete manufacturing is the production of alkali activators like sodium hydroxide (NaOH) and sodium silicate, which require high-temperature processing and contribute to the overall global warming potential.^[33] Additionally, energy consumption during mixing, transportation, and curing, especially when elevated temperatures are used, can further contribute to emissions. While studies suggest that geopolymer concrete can reduce global warming potential by up to 64% compared to Portland concrete through material selection and optimized activator use, the overall impact depends on the specific composition and processing methods employed.^[33]

 

While geopolymer concrete generally has a lower global warming potential (GWP) than ordinary Portland concrete, its environmental impact varies based on the choice of raw materials and activators.^[33] In particular, the production of alkali activators like sodium hydroxide plays a crucial role in determining the overall sustainability of geopolymer concrete. A life cycle assessment (LCA) study by Salas et al. (2018) shows that sodium hydroxide production is a major factor in the environmental impact of geopolymer concrete, as it is also essential for sodium silicate production.^[34] The energy mix used in its production significantly influences emissions, with a 2018 mix (85% hydroelectricity) reducing impacts by 30–70% compared to a 2012 mix (62% hydroelectricity).^[34] The source of sodium hydroxide also affects geopolymer concrete’s sustainability, with solar salt-based production and hydropower reducing its GWP by 64% compared to conventional concrete (CC).^[34] However, geopolymer concrete has higher ozone depletion potential due to CFC emissions from the chlor-alkali process, a drawback not present in CC production.^[34] Other environmental impacts vary, with geopolymer concrete slightly outperforming CC in fossil fuel depletion and eutrophication but performing slightly worse in acidification and photochemical oxidant formation.

 

Geopolymers as ceramics

 

Geopolymers can be used as a low-cost and/or chemically flexible route to ceramic production, both to produce monolithic specimens, and as the continuous (binder) phase in composites with particulate or fibrous dispersed phases.^[39]

 

Room-temperature processed materials

 

Geopolymers produced at room temperature are typically hard, brittle, castable, and mechanically strong. This combination of characteristics offers the opportunity for their usage in a variety of applications in which other ceramics (e.g. porcelain) are conventionally used. Some of the first patented applications of geopolymer-type materials - actually predating the coining of the term geopolymer by multiple decades - relate to use in automobile spark plugs.^[40]

 

Thermal processing of geopolymers to produce ceramics

 

It is also possible to use geopolymers as a versatile pathway to produce crystalline ceramics or glass-ceramics, by forming a geopolymer through room-temperature setting, and then heating (calcining) it at the necessary temperature to convert it from the crystallographically disordered geopolymer form to achieve the desired crystalline phases (e.g. leucite, pollucite and others).^[41]

 

Geopolymer applications in arts and archaeology 

 

Because geopolymer artifacts can look like natural stone, several artists started to cast in silicone rubber molds replicas of their sculptures. For example, in the 1980s, the French artist Georges Grimal worked on several geopolymer castable stone formulations.^[42]

 

Egyptian pyramid stones

 

Main article: Egyptian pyramid construction techniques

 

In the mid-1980s, Joseph Davidovits presented his first analytical results carried out on samples sourced from Egyptian pyramids. He claimed that the ancient Egyptians used a geopolymeric reaction to make re-agglomerated limestone blocks.^[43][44][45] Later on, several materials scientists and physicists took over these archaeological studies and have published results on pyramid stones, claiming synthetic origins.^{[46][47][48][49]} However, the theories of synthetic origin of pyramid stones have also been stridently disputed by other geologists, materials scientists, and archaeologists.^[50]

 

Roman cements

 

It has also been claimed that the Roman lime-pozzolan cements used in the building of some important structures, especially works related to water storage (cisterns, aqueducts), have chemical parallels to geopolymeric materials.

 

 

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Energetically modified cement

 

https://en.wikipedia.org/wiki/Energetically_modified_cement

 

Energetically modified cements (EMCs) are a class of cements made from pozzolans (e.g. fly ash, volcanic ash, pozzolana), silica sand, blast furnace slag, or Portland cement (or blends of these ingredients).^[1] The term "energetically modified" arises by virtue of the mechanochemistry process applied to the raw material, more accurately classified as "high energy ball milling" (HEBM). At its simplest this means a milling method that invokes high kinetics by subjecting "powders to the repeated action of hitting balls" as compared to (say) the low kinetics of rotating ball mills.^[2] This causes, amongst others, a thermodynamic transformation in the material to increase its chemical reactivity.^[3] For EMCs, the HEBM process used is a unique form of specialised vibratory milling discovered in Sweden and applied only to cementitious materials, here called "EMC Activation".^[4]

 

By improving the reactivity of pozzolans, their strength-development rate is increased. This allows for compliance with modern product-performance requirements ("technical standards") for concretes and mortars. In turn, this allows for the replacement of Portland cement in the concrete and mortar mixes. This has a number of benefits to their long-term qualities.^[3]

 

Energetically modified cements have a wide range of uses. For example, EMCs have been used in concretes for large infrastructure projects in the United States, meeting U.S. concrete standards.

 

Justification

 

The term "energetically modified cement" incorporates a simple thermodynamic descriptor to refer to a class of cements produced using a specialised highly intensive milling process first discovered in 1992 at Luleå University of Technology (LTU) in Sweden.^[6][7] The transformatory process is initiated entirely mechanically as opposed to heating the materials directly.^[7][8][9] The mechanisms of mechanochemical transformations are often complex and different from "traditional" thermal or photochemical mechanisms.^[10][11] HEBM can transform both the physical and thermodynamic properties that for example, "can lead to glass formation from elemental powder mixtures as well as by amorphization of intermetallic compound powders".^[12] The effects of HEBM-transformation cause a thermodynamic change that resides ultimately in a modified Gibbs Energy.^[13] The process increases the binding capacity and chemical reactivity rates of the materials transformed.^[4][14]

 

Continuing academic work and research regarding "self-healing" properties of energetically modified cements is ongoing at LTU.^[15] For example, EMCs has received awards from the Elsa ō Sven Thysells stiftelse för konstruktionsteknisk forskning (Elsa & Sven Thysell Foundation for Construction Engineering Research) of Sweden.^[16] The contribution of EMCs to the domain of mechanochemistry itself has also been recognised.

 

Overview

 

The claims made include:

• An EMC is a fine powder (typical of all cements) whose colour depends on the material processed.
• EMCs are produced using only a "fraction" of the energy used in Portland cement production (claimed ~100 KWh/tonne, <8% of Portland cement).
• No CO₂ is released by the process. It is "zero emissions".
• The purpose of an EMC is to replace the Portland cement requirement in the mortar or concrete being used. More than 70% replacement is claimed.
• EMC Activation is a dry process.
• No noxious fumes are released.
• EMC Activation is a low-temperature process, even though temperatures can be "momentarily extreme" at "sub-micron" scales.
• EMCs require no chemicals for their thermodynamic transformation.
• There are several types of EMCs, depending on the raw materials transformed.
• Depending on user-requirements, delivered dry products may comprise also a minority proportion of "high clinker" Portland cement.
• Each type of EMC has its own performance characteristics, including mechanical load and strength development. Concretes cast from EMCs may yield significant "self-healing" capabilities.
• The most frequently used EMCs are made from fly ash and natural pozzolans. These are relatively abundant materials, and the performance characteristics can exceed those of Portland cement.
• In 2009, fly ash EMCs were demonstrated to exceed the 'Grade 120 Slag' benchmark per ASTM C989 — the most reactive form of cementitious blast furnace slag.
• Silica sand and granite can also be treated by the process to replace Portland cement.
• EMC products have been extensively tested by independent labs and certified for use by several US DOTs including in Federal Highway Administration projects.
• EMCs comply with respective technical standards, such as ASTM C618-19 (U.S.); EN-197, EN-206 and EN 450-1:2012 (CEN territories, including EEA); BS 8615‑1:2019 (U.K.).
• Compared to using Portland cement, the resulting concrete-mix using EMC does not require a higher "total cementitious content" to meet strength-development requirements.
• In testing by BASF, the 28-day strength-development for 55% replacement of Portland cement by a natural pozzolanic EMC was 14,000 psi / 96.5 MPa (i.e. > C95). This comprised a "total cementitious content" of 335 kg/m^3 (564 lbs/CY) concrete mix.

 

 

Production and field-usage

 

No noxious emissions or toxic chemicals during production

 

EMC Activation is purely a mechanical process. As such, it does not involve heating or burning or indeed any chemical treatments. This means no fumes at all are produced during an EMC's manufacture.^[23]

 

History

 

EMCs have been produced for project usage since 1992 for a wide range of uses.^[5] By 2010, the volume of concrete poured containing EMCs was about 4,500,000 cu yd (3,440,496 m³), largely on US DOT projects.^[5] To place this into context, that is more than the entire construction of the Hoover Dam, its associated power plants and appurtenant works, where a total of 4,360,000 cu·yds (3,333,459 m³) of concrete was poured—equivalent to a U.S. standard highway from San Francisco to New York City.^[32]

 

Early usage in Sweden

 

An early project used a concrete comprising a 50% Portland cement substitution using a silica sand EMC. This was deployed for the construction of a road bridge in Karungi, Sweden, in 1999, with Swedish construction firm Skanska. The Karungi road bridge has withstood Karungi's harsh subarctic climate and divergent annual and diurnal temperature ranges.^[23]

 

Usage in the United States

 

In the United States, energetically modified cements have been approved for usage by a number of state transportation agencies, including PennDOT, TxDOT and CalTrans.^[25]

 

In the United States, highway bridges and hundreds of miles of highway paving have been constructed using concretes made from EMC derived from fly ash.^[5] These projects include sections of Interstate 10.^[5] In these projects, EMC replaced at least 50% of the Portland cement in the concrete poured.^[26] This is about 2.5 times more than the typical amount of fly ash in projects where energetic modification is not used.^[33] Independent test data showed 28-day strength-development requirements were exceeded in all projects. In 2009, fly ash EMCs were demonstrated to exceed the 'Grade 120 Slag' benchmark per ASTM C989.^[26]

 

Another project was the extension of the passenger terminals at the Port of Houston, Texas, where energetically modified cement's ability to yield concretes that exhibit high resistances to chloride– and sulphate–ion permeability (i.e., increased resistance to seawater) was a factor.^[5]

 

Developments in 2024

 

In February 2024 it was jointly announced that a manufacturing plant for EMCs made from volcanic materials will be jointly developed by "EMC Cement" and HES International at the Port of Amsterdam, and further, that the "all-electric zero-emissions plant, of an initial capacity of 1.2 million tonnes, will cut CO2 emissions by 1 million tonnes annually — using less than 10% of the energy of a conventional Portland cement plant".

 

EMCs using Pozzolans such as volcanic materials

 

Self-healing properties of pozzolanic EMCs

 

Natural pozzolanic reactions can cause mortars and concretes containing these materials to "self-heal".^[40][41][42] The EMC Activation process can increase the likelihood of the occurrence of these pozzolanic reactions.^[43][44] The same tendency been noted and studied in the various supporting structures of Hagia Sophia built for the Byzantine emperor Justinian (now, Istanbul, Turkey).^[45] There, in common with most Roman cements, mortars comprising high amounts of pozzolana were used — in order to give what was thought to be an increased resistance to the stress-effects caused by earthquakes.^[46]

 

EMCs made from pozzolanic materials exhibit "biomimetic" self-healing capabilities that can be photographed as they develop (see picture insert).^[39]

 

EMCs using California pozzolans

 

Concretes made by replacing at least 50% of the Portland cement with EMCs have yielded consistent field results in high-volume applications.^[26] This is also the case for EMC made from natural pozzolans (e.g., volcanic ash).^[47]

 

Volcanic ash deposits from Southern California were independently tested; at 50% Portland cement replacement, the resulting concretes exceeded the requirements of the relevant US standard.^[48] At 28 days, the compressive strength was 4,180 psi / 28.8 MPa (N/mm²). The 56-day strength exceeded the requirements for 4,500 psi (31.1 MPa) concrete, even taking into account the safety margin as recommended by the American Concrete Institute.^[49] The concrete made in this way was workable and sufficiently strong, exceeding the 75% standard of pozzolanic activity at both 7 days and 28 days.^[48] The surface smoothness of pozzolans in the concrete was also increased.

 

Effect on pozzolanic reactions

 

EMC Activation is a process that increases a pozzolan's chemical affinity for pozzolanic reactions.^[43][44] This leads to faster and greater strength development of the resulting concrete, at higher replacement ratios, than untreated pozzolans.^[26][47] These transformed (now highly reactive pozzolans) demonstrate further benefits using known pozzolanic reaction-pathways that typically see as their end-goal a range of hydrated products. An NMR study on EMCs concluded that EMC Activation caused "the formation of thin SiO₂ layers around C3S crystals", which in turn, "accelerates the pozzolanic reaction and promotes growing of more extensive nets of the hydrated products".^[50]

 

In simple terms, by using pozzolans in concrete, porous (reactive) Portlandite can be transformed into hard and impermeable (relatively non-reactive) compounds, rather than the porous and soft relatively reactive calcium carbonate produced using ordinary cement.^[51] Many of the end products of pozzolanic chemistry exhibit a hardness greater than 7.0 on the Mohs scale."Self healing" capabilities may also contribute to enhanced field-application durabilities where mechanical stresses may be present. 

 

In greater detail, the benefits of pozzolanic concrete, starts with an understanding that in concrete (including concretes with EMCs), Portland cement combines with water to produce a stone-like material through a complex series of chemical reactions, whose mechanisms are still not fully understood. That chemical process, called mineral hydration, forms two cementing compounds in the concrete: calcium silicate hydrate (C-S-H) and calcium hydroxide (Ca(OH)₂). This reaction can be noted in three ways, as follows:^[52]

 

• Standard notation:  ${\displaystyle {\text{Ca}}_3^{}{\text{SiO}}_5^{}+{\text{H}}_2^{}\text{O}⟶(\text{CaO})\cdot ({\text{SiO}}_2^{})\cdot ({\text{H}}_2^{}\text{O})+\text{Ca}{(\text{OH})}_2^{}}$

• Balanced:  ${\displaystyle 2{\text{Ca}}_3^{}{\text{SiO}}_5^{}+7{\text{H}}_2^{}\text{O}⟶3\text{CaO}\cdot 2{\text{SiO}}_2^{}\cdot 4{\text{H}}_2^{}\text{O}+3\text{Ca}{(\text{OH})}_2^{}}$

• Cement chemist notation (the hyphenation denotes the variable stoichiometry):  C₃S  +  H   →   C-S-H  +  CH

 

The underlying hydration reaction forms two products: 

 

1. Calcium silicate hydrate (C-S-H), which gives concrete its strength and dimensional stability. The crystal structure of C-S-H in cement paste has not been fully resolved yet and there is still ongoing debate over its nanostructure.^[53]
2. Calcium hydroxide (Ca(OH)₂), which in concrete chemistry is known also as Portlandite. In comparison to calcium silicate hydrate, Portlandite is relatively porous, permeable and soft (2 to 3, on Mohs scale).^[54] It is also sectile, with flexible cleavage flakes.^[55] Portlandite is soluble in water, to yield an alkaline solution which can compromise a concrete's resistance to acidic attack. 

 

Portlandite makes up about 25% of concrete made with Portland cement without pozzolanic cementitious materials.^[51] In this type of concrete, carbon dioxide is slowly absorbed to convert the Portlandite into insoluble calcium carbonate (CaCO₃), in a process called carbonatation:

 

${\displaystyle \text{Ca}{(\text{OH})}_2^{}+{\text{CO}}_2^{}⟶{\text{CaCO}}_3^{}+{\text{H}}_2^{}\text{O}}$

 

In mineral form, calcium carbonate can exhibit a wide range of hardness depending on how it is formed. At its softest, calcium carbonate can form in concrete as chalk (of hardness 1.0 on Mohs scale). Like Portlandite, calcium carbonate in mineral form can also be porous, permeable and with a poor resistance to acid attack, which causes it to release carbon dioxide. 

 

Pozzolanic concretes, including EMCs, however, continue to consume the soft and porous Portlandite as the hydration process continues, turning it into additional hardened concrete as calcium silicate hydrate (C-S-H) rather than calcium carbonate.^[51] This results in a denser, less permeable and more durable concrete.^[51] This reaction is an acid-base reaction between Portlandite and silicic acid (H₄SiO₄) that may be represented as follows:

 

${\displaystyle \text{Ca}{(\text{OH})}_2^{}+{\text{H}}_4^{}{\text{SiO}}_4^{}⟶{\text{Ca}}^{2+}+{\text{H}}_2^{}{\text{SiO}}_4^{2-}+2{\text{H}}_2^{}\text{O}⟶{\text{CaH}}_2^{}{\text{SiO}}_4^{}\cdot 2{\text{H}}_2^{}\text{O}}$ ^{[Note 4]}

 

Further, many pozzolans contain aluminate (Al(OH)₄⁻) that will react with Portlandite and water to form:

 

• calcium aluminate hydrates, such as calcium aluminium garnet (hydrogrossular: C₄AH₁₃ or C₃AH₆ in cement chemist notation, hardness 7.0 to 7.5 on Mohs scale);^[57]  or
• in combination with silica, to form strätlingite (Ca₂Al₂SiO₇·8H₂O or C₂ASH₈ in cement chemist notation), which geologically can form as xenoliths in basalt as metamorphosed limestone. 

 

Pozzolanic cement chemistry (along with high-aluminate cement chemistry) is complex and per se is not constrained by the foregoing pathways. For example, strätlingite can be formed in a number of ways, including per the following equation which can add to a concrete's strength:

 

C₂AH₈  +  2CSH  +  AH₃  +  3H    →    C₂ASH₈    (cement chemist notation) ^[61][62]

 

The role of pozzolans in a concrete's chemistry is not fully understood. For example, strätlingite is metastable, which in a high temperature and water-content environment (that can be generated during the early curing stages of concrete) may of itself yield stable calcium aluminium garnet (see first bullet point above).^[63] This can be represented per the following equation: 

 

3C₂AH₈    →    2C₃AH₆  +  AH₃  +  9H    (cement chemist notation) ^[64]

 

Per the first bullet point, although the inclusion of calcium aluminium garnet per se is not problematic, if it is instead produced by the foregoing pathway, then micro-cracking and strength-loss can occur in the concrete.^[65] However, adding high-reactivity pozzolans into the concrete mix prevents such a conversion reaction.^[66] In sum, whereas pozzolans provide a number of chemical pathways to form hardened materials, "high-reactivity" pozzolans such as blast furnace slag (GGBFS) can also stabilise certain pathways. In this context, EMCs made from fly ash have been demonstrated to produce concretes that meet the same characteristics as concretes comprising "120 Slag" (i.e., GGBFS) according to U.S. standard ASTM C989.

 

Portlandite, when exposed to low temperatures, moist conditions and condensation, can react with sulphate ions to cause efflorescence. In contrast, pozzolanic chemistry reduces the amount of Portlandite available, to reduce the proliferation of efflorescence.

 

 

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Natural nanocrystals shown to strengthen concrete

 

Mar 31, 2015 

 

 

http://phys.org/news/2015-03-natural-nanocrystals-shown-concrete.html?utm_source=menu&utm_medium=link&utm_campaign=item-menu

 

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Building green with CO2-absorbing concrete

Apr 25, 2024

A little over an hour from Tokyo, nestled in the mountains near Nagano, a house has been built in Karuizawa with the world's first carbon dioxide-removing concrete walls produced by replacing a percentage of the cement content with an industrial byproduct and adding a CO2-absorbing admixture of dicalcium silicate.

Karuizawa is one of Japan's oldest and most famous forested mountain resort towns. The house, designed by Japanese studio Nendo, has panel walls made of new eco-friendly concrete blocks called CO2-SUICOM, short for CO2-storage and utilization for infrastructure by concrete materials, jointly developed by Kajima Corp. and the Chugoku Electric Power Co., Denka, and Landes Co.

The special admixture used in CO2-SUICOM absorbs CO2 and solidifies it through a calcium carbonation process. This significantly reduces the amount of cement and accelerates the permanent absorption of CO2 inside the concrete.

Generally, concrete hardens through a chemical reaction between cement and water. During the CO2-SUICOM manufacturing process, concrete is formed with byproducts such as coal ash or blast furnace slag, then placed in a curing chamber fed with CO2 to be absorbed into the concrete, a reaction which hardens the concrete mix without needing water while retaining the same strength as traditional concrete. 

In addition, it has excellent abrasion resistance and is chemically neutral and nontoxic to plants.

CO2 from various sources, including steel, power, and cement plants, could be directly used for this, resulting in reduced emissions and even carbon-negative production, depending on the source of CO2. For example, a thermal power plant or other facility can redirect its carbon-heavy exhaust into a carbon sequestration chamber, where concrete products made with CO2-SUICOM can be placed to capture the CO2 in the gases.

https://www.metaltechnews.com/story/2024/04/17/tech-bytes/building-green-with-co2-absorbing-concrete/1720.html


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AI simulates billions of atoms to create concrete that traps carbon and lasts centuries

 

Jul 25, 2025

 

Allegro-FM simulates atoms at record scale to develop smart concrete that’s greener, stronger, and fire-resistant.

 

https://interestingengineering.com/innovation/ai-concrete-simulation-carbon-capture 

 

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Concrete that lasts centuries and captures carbon? AI just made it possible

 

July 23, 2025

 

Allegro-FM achieves breakthrough scalability for materials research, enabling simulations 1,000 times larger than previous models.

 

https://www.sciencedaily.com/releases/2025/07/250723045707.htm 

 

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New carbon-negative material could make concrete and cement more sustainable

March 19, 2025

Using seawater, electricity and carbon dioxide (CO2), Northwestern University scientists have developed a new carbon-negative building material.

As Earth’s climate continues to warm, researchers around the globe are exploring ways to capture CO2 from the air and store it deep underground. While this approach has multiple climate benefits, it does not maximize the value of the enormous amounts of atmospheric CO2.

Now, Northwestern’s new strategy addresses this challenge by locking away CO2 permanently and turning it into valuable materials, which can be used to manufacture concrete, cement, plaster and paint. The process to generate the carbon-negative materials also releases hydrogen gas — a clean fuel with various applications, including transportation.

“We have developed a new approach that allows us to use seawater to create carbon-negative construction materials,” said Northwestern’s Alessandro Rotta Loria, who led the study. “Cement, concrete, paint and plasters are customarily composed of or derived from calcium- and magnesium-based minerals, which are often sourced from aggregates — what we call sand. Currently, sand is sourced through mining from mountains, riverbeds, coasts and the ocean floor. In collaboration with Cemex, we have devised an alternative approach to source sand — not by digging into the Earth but by harnessing electricity and CO2 to grow sand-like materials in seawater.”

https://news.northwestern.edu/stories/2025/03/new-carbon-negative-material-could-make-concrete-and-cement-more-sustainable/ 

 

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Bio-Concrete Made From Urine: Researchers Create Sustainable Building Material

Jun 2, 2025

https://sigmaearth.com/bio-concrete-made-from-urine-researchers-create-sustainable-building-material/ 

 

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AI-powered self-healing asphalt: A step toward sustainable net-zero roads

Feb 2025

Self-healing asphalt roads, made from biomass waste and designed with the help of artificial intelligence (AI), could offer a promising solution to the UK's pothole problem, which is estimated to cost £143.5 million a year.

A team of scientists from Swansea University and King’s College London, in collaboration with scientists in Chile, is designing a new type of self-healing asphalt that can mend its own cracks without the need for maintenance or human intervention.

Cracks form when bitumen—the sticky black material in the asphalt mixture—hardens through oxidisation, but the exact processes behind this are not entirely known.

The team has found a way to reverse cracking and develop methods to "stitch" asphalt back together, creating more durable and sustainable roads.

During the research, a type of AI known as machine learning was used to study organic molecules in complex fluids like bitumen. The team developed a new data-driven model to accelerate atomistic simulations, advancing research into bitumen oxidation and crack formation. They are also collaborating with Google Cloud to simulate the behaviour of the bitumen on a computer.

To make the asphalt “self-healing”, the team incorporated tiny, porous materials known as spores, which are smaller than a strand of hair and produced by plants. These spores are filled with recycled oils, which are released when the asphalt begins to crack, helping to reverse the process.

In laboratory experiments, this advanced asphalt material was shown to completely heal a microcrack on its surface in less than an hour.

Dr Jose Norambuena-Contreras, a Senior Lecturer in the Department of Civil Engineering at Swansea University and an expert in self-healing asphalt, said: "As part of our interdisciplinary study, we have brought together experts in civil engineering, chemistry, and computer science, combining this knowledge with the state-of-the-art AI tools of Google Cloud.

“We are proud to be advancing the development of self-healing asphalt using biomass waste and artificial intelligence. This approach positions our research at the forefront of sustainable infrastructure innovation, contributing to the development of net-zero roads with enhanced durability."

A substantial portion of carbon emissions from roads is linked to asphalt production. As the highway sector increasingly prioritises carbon reduction to support the UK Government's goal of achieving net-zero emissions by 2050, advancing innovative bituminous materials for asphalt roads has become a key research priority.

https://www.swansea.ac.uk/press-office/news-events/news/2025/02/ai-powered-self-healing-asphalt-a-step-toward-sustainable-net-zero-roads.php

 

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Basanite basalt rebar chosen to reinforce underground concrete structures

04/22/2022

Indian Creek Village, an island municipality located in Florida, selected BasaFlex and BasaMesh fiber reinforcement products as alternatives to steel rebar.

https://www.compositesworld.com/news/basanite-basalt-rebar-chosen-to-reinforce-underground-concrete-structures

 

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The NCC, Skanska trial low-carbon, basalt fiber-reinforced concrete

02/08/2022

Study is critical to understanding the impact of low-carbon concrete and advanced composite reinforcement systems in the construction sector, and its contributions toward low-carbon emissions, structural performance and EOL recycling.

https://www.compositesworld.com/news/the-ncc-skanska-trial-low-carbon-basalt-fiber-reinforced-concrete

 

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Mortar Made From Recycled Plastic Is More Insulating and Eco-Friendly (Controversial)

February 20, 2025 

https://www.technologynetworks.com/applied-sciences/news/mortar-made-from-recycled-plastic-is-more-insulating-and-eco-friendly-396369

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Nano-engineered sealer leads to more durable concrete

 

February 17, 2022

 

A nanomaterials-engineered penetrating sealer developed by Washington State University researchers is able to better protect concrete from moisture and salt – the two most damaging factors in crumbling concrete infrastructure in northern states. 

https://www.thegraphenecouncil.org/blogpost/1501180/446597/Nano-engineered-sealer-leads-to-more-durable-concrete

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Finding a new formula for concrete

 

27-May-2016

 

 

“If we can replace cement, partially or totally, with some other materials that may be readily and amply available in nature, we can meet our objectives for sustainability,” MIT Professor Oral Buyukozturk says. 

 

Looking to bones and shells as blueprints for stronger, more durable concrete.

 

https://www.chemeurope.com/en/news/158228/finding-a-new-formula-for-concrete.html 

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Innovation Pioneers Score World First for Sustainable Construction With “Game-Changing” Graphene-Enhanced Concrete

June 5, 2021

 

What’s Concrete’s Problem?

 

Production of cement for concrete in the building industry is one of the leading causes of global carbon dioxide emissions. Remarkably, if concrete were a country, it would be the third largest emitter in the world behind only China and the US, producing around 8% of global CO₂ emissions.

 

The addition of tiny amounts of graphene — a so-called ‘2D material’ made of a single layer of carbon atoms — strengthens Concretene by around 30% compared to standard RC30 concrete, meaning significantly less is needed to achieve the equivalent structural performance.

 

“We are thrilled to have developed and constructed this game-changing, graphene-enhanced concrete on a real project,” said Alex McDermott, co-founder and managing director of Nationwide Engineering, who is also a civil engineering graduate from Manchester. “Together with our partners at The University of Manchester’s Graphene Engineering Innovation Centre and structural engineers HBPW Consulting, we are rapidly evolving our knowledge and experience and are positioned for wider industry deployment through our construction frameworks, becoming the go-to company for graphene-enhanced concrete.”

 

What Could This Mean for the Building Industry?

 

Nationwide Engineering has three existing five-year construction frameworks with Network Rail and two seven-year Government Crown commercial building frameworks. With Network Rail committing to an 11% reduction in CO₂ emissions over the next four years, graphene-enhanced concrete shows significant potential to help meet this target.

 
https://scitechdaily.com/innovation-pioneers-score-world-first-for-sustainable-construction-with-game-changing-graphene-enhanced-concrete/

 

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Electrifying cement with nanocarbon black

  

April 20, 2021

 

A collaboration between MIT and CNRS has yielded a cement that conducts electricity and generates heat.

https://news.mit.edu/2021/electrifying-cement-nanocarbon-black-0420

 

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Recycled Tire Waste Turned Into Graphene Makes Stronger Concrete (Controversial, many tires are toxic)

April 10, 2021

 

https://www.intelligentliving.co/recycled-tire-graphene-stronger-concrete/ 

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Simple changes in brick kilns cut emissions and improve air quality in Bangladesh

May 8, 2025 

https://techxplore.com/news/2025-05-simple-brick-kilns-emissions-air.html

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How to Make Orgonite

 

http://www.orgonite.info/how-to-make-orgonite.html

Basic orgonite is simply fiberglass resin, metal shavings and a quartz crystal, cured in any mold you like. There's no one "right" shape or size for orgonite, and its range of effect seems to scale linearly with volume, but there are specific, time-tested, widely-used and repeatedly-confirmed effective designs for both personal and field devices which have grown and continue to grow out of the steadfast work of talented and dedicated gifters from around the world.

____________________________________

 

A better board: Glassing with a Bio-Based Epoxy Resin

 

July 19 2012



http://www.surfrider.org/jims-blog/entry/a-better-board-non-toxic-glassing


____________________________________

 

New high-volume joining process expands use of aluminum in autos

 

May 12, 2015

 

 Researchers have demonstrated a new process for the expanded use of lightweight aluminum in cars and trucks at the speed, scale, quality and consistency required by the auto industry. The process reduces production time and costs while yielding strong and lightweight parts, for example delivering a car door that is 62 percent lighter and 25 percent cheaper than that produced with today's manufacturing methods.


 http://phys.org/news/2015-05-high-volume-aluminum-autos.html#jCp


____________________________________

 

Exceptionally strong and lightweight new metal created 

 

 December 23, 2015 

 

 

 A team led by researchers from the UCLA Henry Samueli School of Engineering and Applied Science has created a super-strong yet light structural metal with extremely high specific strength and modulus, or stiffness-to-weight ratio. The new metal is composed of magnesium infused with a dense and even dispersal of ceramic silicon carbide nanoparticles. It could be used to make lighter airplanes, spacecraft, and cars, helping to improve fuel efficiency, as well as in mobile electronics and biomedical devices.

 http://phys.org/news/2015-12-exceptionally-strong-lightweight-metal.html#jCp



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A metal composite that will (literally) float your boat

May 12, 2015 

 

Researchers have demonstrated a new metal matrix composite that is so light that it can float on water. A boat made of such lightweight composites will not sink despite damage to its structure. The new material also promises to improve automotive fuel economy because it combines light weight with heat resistance.


http://phys.org/news/2015-05-metal-composite-literally-boat.html#jCp

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Nanostructured copper alloy rivals superalloys in strength and stability

March 27, 2025

 

 

Colorized scanning transmission electron microscope (STEM) image showing a Cu₃Li precipitate in the Cu-Ta-Li alloy. The orange-colored features are primarily Cu atoms in the alloy matrix, while the blue and yellow features correspond to the Cu₃Li precipitate. The yellow represents Ta atoms in the atomic bilayer complexion, and the blue features represent Li atoms in the core of the Cu₃Li precipitate. 

Researchers from the U.S. Army Research Laboratory (ARL) and Lehigh University have developed a nanostructured copper alloy that could redefine high-temperature materials for aerospace, defense, and industrial applications.

Their findings, published in the journal Science, introduce a Cu-Ta-Li (copper-tantalum-lithium) alloy with exceptional thermal stability and mechanical strength, making it one of the most resilient copper-based materials ever created.

"This is cutting-edge science, developing a new material that uniquely combines copper's excellent conductivity with strength and durability on the scale of nickel-based superalloys," said Martin Harmer, the Alcoa Foundation Professor Emeritus of Materials Science and Engineering at Lehigh University and a co-author of the study. "It provides industry and the military with the foundation to create new materials for hypersonics and high-performance turbine engines."

The ARL and Lehigh researchers collaborated with scientists from Arizona State University and Louisiana State University to develop the alloy, which can withstand extreme heat without significant degradation.

https://phys.org/news/2025-03-nanostructured-copper-alloy-rivals-superalloys.html

 

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MIT Scientists Unveil a Secret of Stronger Metals

 

May 22, 2022

 

New research shows what happens when crystalline grains in metals reform at nanometer scales, improving metal properties.

 

Forming metal into the specific shapes needed for various purposes is done in many ways, including casting, machining, forging, and rolling. These processes affect the sizes and shapes of the tiny crystalline grains that make up the bulk metal, whether it be steel, aluminum, titanium, or other widely used metals and alloys.

 

Researchers at MIT have now been able to analyze exactly what happens as these crystal grains form during an extreme deformation process, at the tiniest scales, down to a few nanometers across. The new discoveries could lead to improved ways of processing to produce better, more consistent properties such as hardness and toughness.

https://scitechdaily.com/mit-scientists-unveil-a-secret-of-stronger-metals/

 

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Chemical oscillations in palladium nanoparticles could pave way for recycling precious metal catalysts

March 26, 2025

https://phys.org/news/2025-03-chemical-oscillations-palladium-nanoparticles-pave.html

 

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Nanocluster discovery will protect precious metals

17 August 2021

 

Scientists have created a new type of catalyst that will lead to new, sustainable ways of making and using molecules and protect the supply of precious metals.

 

A research team from the University of Nottingham have designed a new type of catalyst that combines features that are previously thought to be mutually exclusive and developed a process to fabricate nanoclusters of metals on a mass scale.

 

In their new research, published today in Nature Communications, they demonstrate that the behaviour of nanoclusters of palladium do not conform to the orthodox characteristics that define catalysts as either homogeneous or heterogenous.

 

Traditionally, catalysts are divided into homogeneous, when catalytic centres are intimately mixed with reactant molecules, and heterogenous, where reactions take place on surface of a catalyst. Usually, chemists must make compromises when choosing one type or another, as homogeneous catalysts are more selective and active, and heterogenous catalysts are more durable and reusable. However, the nanoclusters of palladium atoms appear to defy the traditional categories, as demonstrated by studying their catalytic behaviour in the reaction of cyclopropanation of styrene.

 

Catalysts enable nearly 80 % of industrial chemical processes that deliver the most vital ingredients of our economy, from materials (such as polymers) and pharmaceuticals right through to agrochemicals including fertilisers and crop protection. The high demand for catalysts means that global supplies of many useful metals, including gold, platinum and palladium, are become rapidly depleted. The challenge is to utilise each-and-every atom to its maximum potential. Exploitation of metals in the form of nanoclusters is one of the most powerful strategies for increasing the active surface area available for catalysis. Moreover, when the dimensions of nanoclusters break through the nanometre scale, the properties of the metal can change drastically, leading to new phenomena otherwise inaccessible at the macroscale.

 

The research team used analytical and imaging techniques to probe the structure, dynamics, and chemical properties of the nanoclusters, to reveal the inner workings of this unusual catalyst at the atomic level.

 

The team’s discovery holds the key to unlock full potential of catalysis in chemistry, leading to new ways of making and using molecules in the most atom-efficient and energy-resilient ways.

 

https://www.nottingham.ac.uk/news/nanocluster-discovery-will-protect-precious-metals

 

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100 uses of indium

September 10, 2023

Indium is a rare mеtal found in small amounts in the Earth’s crust. It is a soft, silvеry-whitе mеtal that has a low mеlting point. Indium has a wide variety of usеs, including in еlеctronics, optics, and thеrmoеlеctrics.

Uses of Indium

1. Semiconductor Industry:

Indium is widely used in the production of semiconductors, helping to create electronic devices such as transistors and diodes.

2. Soldering:

Indium-based alloys are used in soldering applications, providing a low melting point and excellent bonding properties.

3. Liquid Crystal Displays (LCDs):

Indium tin oxide (ITO) is a transparent conducting material used in the production of LCDs, allowing for the creation of touchscreens and high-resolution displays.

4. Solar Panels:

Indium is used in the production of photovoltaic solar panels, helping to convert sunlight into electricity.

5. Aerospace Industry:

Indium alloys are used in aerospace applications, including sealing and bonding components, as well as thermal management systems.

6. Thin Film Coatings:

Indium is utilized in thin film coatings to provide corrosion resistance, solderability, and reflectivity in various applications.

7. Transparent Electrodes:

Indium tin oxide (ITO) is used as a transparent electrode in applications such as touchscreens, solar cells, and liquid crystal displays.

8. Bearings:

Indium-based alloys are used as low-friction bearings in high-performance applications, reducing wear and improving efficiency.

9. Superconductors:

Indium compounds are used in the production of superconducting materials, which have zero electrical resistance at low temperatures.

10. Electrical Connectors:

Indium is used in electrical connectors due to its low melting point and ability to provide reliable electrical conductivity.

11. Thermal Interface Materials:

Indium-based thermal interface materials are used to improve heat transfer between electronic components, reducing the risk of overheating.

12. Radiation Shielding:

Indium alloys are used in radiation shielding applications, protecting against harmful radiation in various industries, including healthcare and nuclear power.

13. Automotive Electronics:

Indium is used in automotive electronics, contributing to the functionality of systems such as airbags, anti-lock brakes, and engine control units.

14. Electrical Fuses:

Indium-based alloys are utilized in electrical fuses, providing reliable and precise current interruption capabilities.

15. High-Performance Solders:

Indium-based solders are used in high-performance applications, such as aerospace and defense, where strong and durable bonding is required.

16. X-ray and Gamma-ray Detectors:

Indium compounds are employed in the production of detectors for X-rays and gamma rays, enabling accurate imaging and detection of radiation.

17. Electrical Contacts:

Indium is used in electrical contacts, ensuring reliable electrical connections in various devices and equipment.

18. Alloying Agent:

Indium is added to various alloys to enhance their properties, such as corrosion resistance, strength, and low-temperature performance.

19. Ceramics:

Indium oxide is utilized in ceramic applications, providing thermal stability, electrical conductivity, and color pigmentation.

20. Catalysts:

Indium compounds are used as catalysts in chemical reactions, facilitating the conversion of reactants into desired products.

21. Medical Imaging:

Indium-111, a radioactive isotope of indium, is used in medical imaging techniques, such as SPECT scans, for diagnostic purposes.

22. Anti-reflective Coatings:

Indium tin oxide (ITO) is employed in anti-reflective coatings, reducing glare and improving optical clarity in lenses and displays.

23. Metal Plating:

Indium is used in metal plating processes to enhance the appearance, corrosion resistance, and durability of various objects.

24. Electrical Heaters:

Indium alloys with low melting points are used in electrical heaters, providing efficient and precise heat generation.

25. Indium Seals:

Indium is used to create hermetic seals in vacuum systems and electronic devices, preventing leakage and contamination.

26. Reflective Coatings:

Indium-based coatings are applied to mirrors and reflective surfaces, improving reflectivity and durability.

27. Fiber Optics:

Indium-based materials are used in fiber optics, enabling the transmission of light signals over long distances with minimal loss.

28. Electroplating:

Indium is used in electroplating processes to deposit a thin layer of indium onto various substrates, providing desired properties and aesthetics.

29. Gas Sensors:

Indium oxide-based sensors are used to detect and measure the presence of gases, enabling gas leak detection and environmental monitoring.

30. Lubricants:

Indium-based lubricants are utilized in high-temperature applications, reducing friction and wear between moving parts.

31. Ceramic Capacitors:

Indium-based materials are used in ceramic capacitors, contributing to their electrical properties and reliability.

32. Anti-static Coatings:

Indium-based coatings are applied to surfaces to prevent the buildup of static electricity, reducing the risk of damage to electronic components.

33. Nuclear Reactors:

Indium is used in nuclear reactors as a neutron absorber, helping control the rate of nuclear fission reactions.

34. Gasoline Additives:

Indium compounds are utilized as gasoline additives, improving fuel efficiency and reducing engine emissions.

35. Alloy Plating:

Indium alloys are used in plating processes to provide desired properties, such as corrosion resistance and electrical conductivity.

36. Anti-tarnish Coatings:

Indium-based coatings are applied to prevent tarnishing and oxidation of metals, preserving their appearance and durability.

37. Optical Filters:

Indium compounds are used in the production of optical filters, allowing specific wavelengths of light to pass through while blocking others.

38. Electrical Insulation:

Indium-based materials are employed as electrical insulation coatings, protecting against electrical leakage and improving safety.

39. Solid Oxide Fuel Cells:

Indium oxide is used as a component in solid oxide fuel cells, facilitating the conversion of fuel into electrical energy.

40. Anti-friction Coatings:

Indium-based coatings are applied to reduce friction and wear between surfaces, improving the efficiency and lifespan of machinery.

41. Corrosion Protection:

Indium coatings and alloys are used to provide corrosion resistance to various materials, extending their lifespan and durability.

42. Dental Materials:

Indium-based materials are used in dentistry for applications such as dental fillings and orthodontic appliances.

43. Electrodes for Batteries:

Indium is utilized in the production of electrodes for batteries, contributing to their electrical performance and efficiency.

44. Magnetic Materials:

Indium compounds are used in the production of magnetic materials, including magnetic tapes, hard disks, and magnetic resonance imaging (MRI) contrast agents.

45. Water Purification:

Indium compounds are employed in water purification processes to remove impurities and contaminants, ensuring clean and safe drinking water.

46. Pharmaceuticals:

Indium compounds are used in the development of pharmaceuticals, particularly in radiopharmaceuticals for diagnostic imaging and targeted therapies.

47. Antifouling Coatings:

Indium-based coatings are applied to surfaces in marine environments to prevent the attachment of marine organisms, reducing fouling and improving efficiency.

48. Flame Retardants:

Indium compounds are used as flame retardants in various applications, helping to reduce the spread of fire and improve safety.

49. Cryogenics:

Indium is used in cryogenic applications, such as superconducting magnets and cooling systems, due to its low-temperature properties.

50. Nuclear Medicine:

Indium-111 is used in nuclear medicine for diagnostic imaging and targeted therapies, particularly in the detection and treatment of certain cancers.

51. Oxygen Sensors:

Indium-based materials are utilized in oxygen sensors, measuring the oxygen concentration in gases and liquids for various industrial and medical applications.

52. High-Performance Bearings:

Indium alloys are used in high-performance bearings, providing low friction, high load-carrying capacity, and durability.

53. Gas Permeation Barriers:

Indium-based coatings and films are employed as gas permeation barriers, preventing the passage of gases through materials.

54. Oxygen-Deficient Atmosphere Detection:

Indium oxide-based sensors are used to detect oxygen-deficient atmospheres, ensuring safety in confined spaces and industrial settings.

55. Microwave Applications:

Indium compounds are used in microwave applications, such as waveguides and microwave filters, due to their electrical properties.

56. Catalyst Support:

Indium is used as a catalyst support, providing a stable surface for catalytic reactions in various chemical processes.

57. Electromagnetic Shielding:

Indium-based materials are employed for electromagnetic shielding, protecting electronic devices from electromagnetic interference (EMI).

58. Wear-Resistant Coatings:

Indium-based coatings are applied to surfaces to provide wear resistance, particularly in high-friction and abrasive environments.

59. Gas Chromatography:

Indium compounds are used in gas chromatography as stationary phases, separating and analyzing gas mixtures in various industries.

60. Metal Alloys:

Indium is alloyed with various metals to create alloys with specific properties, such as low melting points and improved mechanical strength.

61. Environmental Monitoring:

Indium-based sensors are used in environmental monitoring systems to detect and measure pollutants and hazardous substances.

62. Anti-wear Additives:

Indium-based additives are used in lubricants and oils to provide anti-wear properties, reducing friction and extending equipment lifespan.

63. X-ray Shielding:

Indium compounds are employed in X-ray shielding applications, protecting against harmful radiation in medical and industrial settings.

64. Catalysts for Organic Reactions:

Indium compounds are used as catalysts in various organic reactions, facilitating chemical transformations in synthesis and manufacturing processes.

65. Semiconductor Targets:

Indium targets are used in the production of semiconductors, allowing for the deposition of indium-based films and layers.

66. Cryogenic Sealing:

Indium is used in cryogenic applications for sealing purposes, maintaining airtightness at extremely low temperatures.

67. Metal Matrix Composites:

Indium is incorporated into metal matrix composites to improve their mechanical properties, such as strength, stiffness, and thermal conductivity.

68. Oxygen Storage:

Indium-based materials are used for oxygen storage in oxygen generators and respiratory equipment, ensuring a constant oxygen supply.

69. Protective Coatings for Mirrors:

Indium-based coatings are applied to mirrors to protect against corrosion, scratching, and degradation, maintaining optical performance.

70. Indium Targets for Sputtering:

Indium targets are used in sputtering processes to deposit indium-based thin films onto various substrates for electronic and optical applications.

71. Catalysts for Hydrogenation Reactions:

Indium compounds are employed as catalysts for hydrogenation reactions, converting unsaturated compounds into saturated ones.

72. Energy Storage:

Indium-based materials are investigated for energy storage applications, such as batteries and supercapacitors, due to their unique properties.

73. Glass Coatings:

Indium-based coatings are used on glass surfaces to improve their scratch resistance, durability, and optical properties.

74. Electrodes for Solar Cells:

Indium is utilized in the production of electrodes for solar cells, facilitating the conversion of sunlight into electrical energy.

75. Soil Stabilization:

Indium compounds are used in soil stabilization applications, enhancing soil properties and preventing erosion.

76. Gas Lasers:

Indium compounds are employed in gas lasers, producing coherent light for various applications, including cutting, welding, and scientific research.

77. Adhesives and Sealants:

Indium-based materials are used in the formulation of adhesives and sealants, providing strong bonds and reliable sealing properties.

78. Metallization:

Indium is used for metallization purposes, creating conductive layers on non-conductive surfaces in electronic and semiconductor manufacturing.

79. Photovoltaic Materials:

Indium compounds are investigated for photovoltaic materials, aiming to improve the efficiency and performance of solar cells.

80. Cryogenic Cooling:

Indium alloys are used as cryogenic cooling agents, maintaining low temperatures in cryogenic systems and equipment.

81. Electrical Connectors:

Indium-based materials are employed in electrical connectors, ensuring reliable electrical connections and conductivity.

82. Coating Thickness Standards:

Indium foils and standards are used for calibrating coating thickness measurement devices in industrial applications.

83. Insulating Windows:

Indium-based coatings are applied to insulating windows to improve thermal insulation, reducing heat loss and energy consumption.

84. Aerospace Applications:

Indium-based materials are used in various aerospace applications, including electrical connectors, thermal management, and coatings.

85. Wave Soldering:

Indium-based solders are used in wave soldering processes, creating reliable connections between electronic components and circuit boards.

86. Die Attach:

Indium-based materials are employed for die attachment in electronic packaging, ensuring secure and efficient bonding between semiconductor devices and substrates.

87. Heat Transfer Fluids:

Indium-based fluids are used as heat transfer fluids in various applications, providing efficient thermal management and temperature control.

88. Pneumatic Systems:

Indium-based materials are utilized in pneumatic systems, including pneumatic seals and valves, ensuring reliable and efficient operation.

89. Flame Photometry:

Indium compounds are used in flame photometry, a technique for detecting and analyzing elements in samples based on their emission spectra.

90. Catalysts for Dehydrogenation Reactions:

Indium compounds are employed as catalysts for dehydrogenation reactions, removing hydrogen atoms from compounds.

91. Metal Etching:

Indium-based etchants are used for metal etching processes, selectively removing metal layers and creating precise patterns in semiconductor manufacturing.

92. Optical Fibers:

Indium compounds are used in the production of optical fibers, transmitting and guiding light signals in telecommunications and data transmission.

93. Aircraft Sealants:

Indium-based sealants are used in aircraft applications, providing reliable sealing and protection against moisture and corrosion.

94. Neutron Absorbers:

Indium compounds are employed as neutron absorbers in nuclear reactors, controlling neutron flux and preventing nuclear chain reactions.

95. Electronics Cooling:

Indium-based materials are used in electronic cooling systems, dissipating heat generated by electronic components and improving performance.

96. Gas Sensors:

Indium-based sensors are used for gas sensing applications, detecting and measuring specific gases in various industrial and environmental settings.

97. Alloys for Low Melting Point:

Indium is alloyed with other metals to create alloys with low melting points, used in soldering and other low-temperature applications.

98. Ion Implantation:

Indium ions are used in ion implantation processes, modifying the properties of materials for semiconductor and surface engineering applications.

99. Radiographic Contrast Agents:

Indium compounds are utilized as radiographic contrast agents in medical imaging, enhancing the visibility of specific organs and tissues.

100. DIY Makeup Remover:

Using indium compounds as a natural makeup remover helps dissolve makeup and cleanse the skin without harsh chemicals.

https://allusesof.com/elements/uses-of-indium/

 


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Indium – The Essential Yet Overlooked Metal Powering Modern Technology

April 21, 2025

https://ptoe.com/indium-the-essential-yet-overlooked-metal-powering-modern-technology/

 

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New Application of Indium in Batteries Could Increase Electric Vehicle Accessibility

Feb 7, 2024

https://www.cornellsun.com/article/2024/02/new-application-of-indium-in-batteries-could-increase-electric-vehicle-accessibility

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Touchscreen tech swaps rare metal for graphene, with no performance drop

January 09, 2022 

https://newatlas.com/electronics/indium-graphene-oled-touchscreen/

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Securing Indium Utilization for High-Tech and Renewable Energy Industries

February 3, 2023

https://pubs.acs.org/doi/10.1021/acs.est.2c07169

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Plasma tech could replace one of world's rarest materials

20 July 2021

Technology is low-cost, sustainable, readily available

New plasma coating technology could see the phase-out of rare earth metal indium that is used in smartphone glass and dimmable windows, which is predicted to run out in 10 years. 

A team led by a researcher from the University of Sydney has developed a low-cost, sustainable, and readily available technology that can dim the screens of electronic devices, anti-reflection automobile mirrors, and smart architectural windows at a fraction of the cost of current technology. 

It would replace one of the world’s scarcest – yet highly ubiquitous in use – modern materials: indium. A rare chemical element, that it is widely used in devices such as smartphones and computers, windscreen glass and self-dimming windows.

Although small amounts are used to manufacture smart device screens, indium is expensive as it is hard to source; it naturally occurs only in small deposits. Industrial indium is often made as a byproduct of zinc mining, which means a shortage could occur if demand for optoelectronic devices – such as LCDs and touch panels – ramps up.

https://www.sydney.edu.au/news-opinion/news/2021/07/20/plasma-tech-could-replace-one-of-world-s-rarest-materials.html

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MP35N Alloy: The High-Performance Material Powering the Next Generation of Tech Startups

18 June, 2025

https://theprint.in/ani-press-releases/mp35n-alloy-the-high-performance-material-powering-the-next-generation-of-tech-startups/2662093/

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Molybdenum: The New Frontier in Semiconductor Metallization according to Lam Research 

November 7, 2023

The semiconductor industry is facing a significant shift as Molybdenum (Mo or Moly as the Americans say) is tipped to replace tungsten in chip manufacturing due to its superior atomic-scale properties. Kaihan Ashtiani, Corporate Vice President and General Manager at Lam Research, highlights the critical attributes of moly that make it the ideal choice for advanced devices. The company is at the forefront, aiding chipmakers in the transition with its ALTUS® product family, drawing from its pioneering work in Tungsten ALD and expertise in 3D NAND technology.

https://www.blog.baldengineering.com/2023/11/molybdenum-new-frontier-in.html

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The Latest Industry News on Molybdenum Metal: Trends, Innovations, and Market Developments

August 7, 2024

https://www.peakrisemetal.com/knowledge/the-latest-industry-news-on-molybdenum-metal-trends-innovations-and-market-developments

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Molybdenum: Transforming Semiconductor Manufacturing For Next-Generation Technologies

May 22nd, 2025

https://semiengineering.com/scaling-3d-chips-with-molybdenum-based-metallization/

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One Material, Four Behaviors: Superconductor, Metal, Semiconductor, and Insulator

April 24, 2025

RIKEN scientists have discovered how to manipulate molybdenum disulfide into acting as a superconductor, metal, semiconductor, or insulator using a specialized transistor technique.

https://scitechdaily.com/one-material-four-behaviors-superconductor-metal-semiconductor-and-insulator/

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Scientists find new quantum behavior in unusual superconducting material

August 16, 2025

Researchers at Rice University and collaborating institutions have discovered direct evidence of active flat electronic bands in a kagome superconductor. This breakthrough could pave the way for new methods to design quantum materials—including superconductors, topological insulators and spin-based electronics—that could power future electronics and computing technologies.

https://phys.org/news/2025-08-scientists-quantum-behavior-unusual-superconducting.html

 

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Moscovium

Moscovium is a synthetic chemical element; it has symbol Mc and atomic number 115. It was first synthesized in 2003 by a joint team of Russian and American scientists at the Joint Institute for Nuclear Research (JINR) in Dubna, Russia. In December 2015, it was recognized as one of four new elements by the Joint Working Party of international scientific bodies IUPAC and IUPAP. On 28 November 2016, it was officially named after the Moscow Oblast, in which the JINR is situated.

Moscovium is an extremely radioactive element: its most stable known isotope, moscovium-290, has a half-life of only 0.65 seconds.[9] In the periodic table, it is a p-block transactinide element. It is a member of the 7th period and is placed in group 15 as the heaviest pnictogen. Moscovium is calculated to have some properties similar to its lighter homologues, nitrogen, phosphorus, arsenic, antimony, and bismuth, and to be a post-transition metal, although it should also show several major differences from them. In particular, moscovium should also have significant similarities to thallium, as both have one rather loosely bound electron outside a quasi-closed shell. Chemical experimentation on single atoms has confirmed theoretical expectations that moscovium is less reactive than its lighter homologue bismuth. Over a hundred atoms of moscovium have been observed to date, all of which have been shown to have mass numbers from 286 to 290. 

https://en.wikipedia.org/wiki/Moscovium

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Facts About Moscovium (Element 115)

December 1, 2016

Moscovium is a radioactive, synthetic element about which little is known. It is classified as a metal and is expected to be solid at room temperature. It decays quickly into other elements, including nihonium.

The element had previously been designated ununpentium, a placeholder name that means one-one-five in Latin. In November 2016, the International Union of Pure and Applied Chemistry (IUPAC) approved the name moscovium for element 115.

The IUPAC also approved names for elements 113 (nihonium, with atomic symbol Nh), 117 (tennessine, Ts) and 118 (oganesson, Og).

Names for elements 115 and 117 were proposed by their discoverers at the Joint Institute for Nuclear Research in Dubna, Russia; the Oak Ridge National Laboratory in Tennessee; Vanderbilt University in Tennessee; and Lawrence Livermore National Laboratory in California. Both element names, moscovium and tennessine, honor regions where experiments linked to creating the elements took place.

https://www.livescience.com/41424-facts-about-ununpentium.html

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Does the Real Element 115 Have a Connection With UFOs?

Oct 11, 2023

Element 115 is an enigma of sorts. It was only added to the periodic table in 2016, yet for decades it has attracted extra attention because of a supposed connection to extraterrestrial technology and alien lifeforms.

Intrigued? Before we answer whether there is a connection, let's find out what element 115 really is.

What Is Element 115?

"Element 115, or moscovium, is a man-made, superheavy element that has 115 protons in its nucleus," emailed Jacklyn Gates, a scientist with the Heavy Elements Group in the Nuclear Science Division for Berkeley Lab in California, whom we spoke with in 2020.

As with all elements on the periodic table, the element's number corresponds to the number of protons in the nucleus of the element's atom. "That is 23 more protons than the heaviest element that you can find in large quantities on Earth, uranium."

Gates said that element 115 is an extremely rare element that's made one atom at a time in particle accelerators. It exists for just a fraction of a second before it decays into another element.

"It is special because it is near a predicted 'island of stability' where some superheavy nuclei might have much longer lifetimes. Instead of living for less than a second, they could exist for minutes, days or even years! That is long enough that we might be able to use them for practical applications," she said.
How Moscovium Was Created

Element 115 was discovered in 2003 in Dubna, Russia, at the Flerov Laboratory for Nuclear Reactions by a group of Russian scientists led by nuclear physicist Yuri Oganessian. The element was eventually named moscovium because Dubna is a city in the Moscow region.

To make this element, the scientists accelerated ions of calcium-48 (48Ca) to around 10 percent of the speed of light and then bombarded americium-243 (243Am) with them.

Through this bombardment, they were able to successfully fuse the nuclei of 243Am and 48Ca atoms, said Gates. "To create a superheavy element, you need the complete fusion of two lighter elements," she noted.

This process produced four atoms of moscovium.

"The new element that they made had 115 protons (20 from the 48Ca and 95 from the 243Am)," she said. "This new element was then separated from all the other reaction products using the Dubna gas-filled recoil separator and then implanted into a detector where scientists were able to watch element 115 decay into element 113."

"The internal structure of the 115 nucleus — with odd numbers of protons and neutrons (Z = 115, N = 173) — largely prevents spontaneous fission, so it is likely that the nucleus will undergo alpha decay," Oganessian wrote in Nature Chemistry in 2019.

Alpha decay is a type of radioactive decay where an unstable nucleus changes to another element by emitting a particle composed of two protons and two neutrons.

"Emission of an alpha particle forms an odd–odd nucleus of the element 113 that, for the same reasons, will also undergo alpha decay. This decay pattern is reproduced with the element 111, then 109, and so on," he added. "At each step of this odd–odd stairway we decrease the atomic number of the nucleus by two, and we move away by two neutrons from the magic number N = 184.

"As a result, the nucleus becomes more stable to alpha decay, but more prone to spontaneous fission and eventually the chain will be terminated by spontaneous fission."

https://science.howstuffworks.com/space/aliens-ufos/element-115.htm

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Moscovium

https://en.wikipedia.org/wiki/Moscovium

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Germanium: the OG Digital Age metalloid

September 16, 2024

Original computer semiconductor now energizes space ambitions.

Germanium is a versatile and powerful semiconductor that traces its technology roots back to the dawn of the Digital Age and continues to lend its superlative semiconducting and optical properties to enhancing computers, smartphones, solar panels, fiber optics, and other devices 80 years later. 

In 1945, Sylvania introduced the first germanium diode to enhance the vacuum tube computers that launched the Digital Age, and by the 1950s, both Sylvania and General Electric had developed germanium transistors to replace the vacuum tubes in the enormous mainframes of the day.

These first steps into packing more computing power into a smaller space have evolved into the smartphones we now carry in our pockets that are hundreds of thousands of times more powerful than the Apollo-era computers that guided Man's first flight to the Moon.

Despite being the original and more powerful semiconductor for the transistors that kickstarted the age of modern computing, germanium was supplanted by silicon, a more abundant and less expensive material that is now the namesake for the global capital of computer technology and the Digital Age.

While today's global headquarters for technology and innovation may not be known as Germanium Valley, the Digital Age's original semiconductor still boasts superior semiconductive and optical qualities that make it a critical ingredient in some of the most advanced technologies of the 21st century – from quantum computers here on Earth to solar panels powering space exploration.

"The extensive use of germanium for military and commercial applications has made it a critical material in the United States and the rest of the world," the U.S. Geological Survey penned in a 2018 report on critical minerals.

This criticality rose sharply upon China's 2023 emplacement of state-controlled restrictions on the exports of this historic and future-leaning element of innovation. 

https://www.metaltechnews.com/story/2024/09/16/critical-minerals-alliances-2024/germanium-the-og-digital-age-metalloid/1918.html

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Teck Resources eyes output boost for chipmaking-metal germanium

June 20, 2025

LONDON, June 20 (Reuters) - Canada's Teck Resources (TECKb.TO)
, opens new tab is weighing options to expand production of germanium, a strategic metal key to chipmaking, and is currently talking with governments, including Canada and the United States, on available funding, said Doug Brown, VP communications & government affairs.
Teck's plan comes amid growing efforts to diversify supplies of critical minerals needed for the tech and defence sectors, as geopolitical tensions and trade barriers complicate access to materials mainly produced or refined in China.

https://www.reuters.com/world/china/teck-resources-eyes-output-boost-chipmaking-metal-germanium-2025-06-20/

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Germanium: the OG Digital Age metalloid

Sep 18, 2024

https://www.metaltechnews.com/story/2024/09/16/critical-minerals-alliances-2024/germanium-the-og-digital-age-metalloid/1918.html

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China bans exports to US of gallium, germanium, antimony in response to chip sanctions 

Dec 3, 2024

https://www.kxan.com/technology/ap-technology/ap-china-bans-exports-of-gallium-and-other-key-high-tech-materials-hitting-back-at-us-chip-sanctions/

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Gallium: A catalyst for the green future

November 13, 2023

Liquid metal again displays an almost magical ability to become a catalyst for lowering CO2 in the atmosphere

A liquid metal with semiconductor properties that make it an essential ingredient in next-generation smartphones, telecommunication networks, and solar technologies, gallium already lives at the edge of science fiction and science reality. Working at this threshold, Australian scientists are demonstrating that gallium may also be a major catalyst for the green energy future.

Working behind the scenes to create rubbers, plastics, paper, and other products that we use every day, catalysts are metals or metal compounds that facilitate and accelerate chemical reactions without participating in the reaction.

Using gallium as a medium, a research team from the University of Sydney and University of New South Wales has created a liquid metal catalyst that could greatly reduce the carbon dioxide footprint of chemical manufacturing.

"Our method offers an unparalleled possibility to the chemical industry for reducing energy consumption and greening chemical reactions," said Professor Kourosh Kalantar-Zadeh, head of the University of Sydney's School of Chemical and Biomolecular Engineering.

While much of the global focus on reducing CO2 going into the atmosphere has been on obvious emitters such as vehicles and the generation of electricity, several industrial sectors of the global economy are also major contributors. This includes the production of chemical products such as plastics, fertilizers, and fuels, which account for nearly 15% of global CO2 emissions and climbing.

"It's expected that the chemical sector will account for more than 20% of emissions by 2050," said Kalantar-Zadeh. "But chemical manufacturing is much less visible than other sectors – a paradigm shift is vital."

A liquid gallium-nickel catalyst developed by an Australian team of scientists led by Kalantar-Zadeh could substantially lower the energy required for these chemical processes, and thus the CO2 emitted by them.

Gallium super catalyst

While the chemical sector and the catalysts that enable it are largely unseen, they are an essential part of modern life. From beer and cheddar cheese to laundry detergent and plastic jugs, catalysts are an essential part of modern life.

Traditionally, these chemical processes use platinum, palladium, aluminum, nickel, and other metals or metal compounds as catalysts. The reason why these chemical processes tend to emit so much CO2 is because they require temperatures sometimes exceeding 1,000 degrees centigrade (1,800 degrees Fahrenheit), which translates to a lot of energy.

If these catalysts were liquid at near room temperature, however, they could do their work without so much energy input and CO2 output.

"Theoretically, they can catalyze chemicals at much lower temperatures – meaning they require far less energy," Kalantar-Zadeh said.

Gallium's melting point happens to be 86.5 degrees Fahrenheit, which means the heat from your hand is enough liquify it. While this liquid metal is not inherently a catalyst, it has the uncanny ability to take on catalytic properties of metals that are.

The primary reason for this is that the catalytic atoms floating around in liquid gallium are more randomly arranged and have greater freedom of movement than they do when they are solid. This allows them to easily come into contact with, and participate in, chemical reactions.

To create a near-room-temperature catalytic fluid capable of turning cooking oil into useful chemicals, the Australian research team dissolved high-melting-point nickel and tin in a gallium-based liquid metal.

"By dissolving nickel in liquid gallium, we gained access to liquid nickel at very low temperatures – acting as a 'super' catalyst. In comparison solid nickel's melting point is 1,455 degrees centigrade (2,650 degrees Fahrenheit)," said Junma Tang, who works jointly at the University of Sydney and University of New South Wales. "The same effect, to a lesser degree, is also experienced for tin metal in liquid gallium."

The metallic catalysts were dispersed in the gallium-based liquid metal at the atomic level.

"So, we have access to single atom catalysts," said Arifur Rahim, senior author of a scientific paper on the findings published in Nature Nanotechnology and DECRA Fellow at the University of Sydney's School of Chemical and Biomolecular Engineering. "Single atom is the highest surface area accessibility for catalysis which offer a remarkable advantage to the chemical industry."

With this liquid metal super catalyst, the scientists were able to break down canola oil molecules into smaller organic chains, including propylene, a high-energy fuel that is often used in clothes, outdoor furniture, automotive parts, boats, and a wide range of other products.

The researchers said their formula could also be used for other chemical reactions by mixing metals using low-temperature processes.

"It requires such low temperature to catalyze that we could even theoretically do it in the kitchen with the gas cooktop – but don't try that at home," Tang said.

https://www.metaltechnews.com/story/2023/11/15/tech-metals/gallium-a-catalyst-for-the-green-future/1528.html

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New Findings Challenge 150-Year-Old Assumptions: Scientists Discover New Properties of Unusual Metal

August 29, 2024

 

New research reveals aspects of structure and behavior at the atomic level.

 

Nearly 150 years after its discovery and subsequent addition to the periodic table, gallium continues to reveal its secrets. Scientists from the University of Auckland have recently uncovered new aspects of the metal’s structure and behavior.

 

First identified in 1875 by French chemist Paul-Émile Lecoq de Boisbaudran, gallium is notable for its low melting point, which is so low that a spoon made from gallium can melt in a cup of tea. This unusual metal is also a crucial component in the manufacturing of semiconductors.

 

The surprising discovery relates to gallium’s behavior at the atomic level.

 

Unlike most metals, gallium exists in the form of `dimers’ – pairs of atoms – and is less dense as a solid than as a liquid, akin to how ice floats on water. Gallium features `covalent bonds’ where atoms share electrons, also unusual for a metal.

 

The new study shows that while those bonds disappear at melting point, they reappear at higher temperatures.

 

That contradicts long-standing assumptions and necessitates a new explanation for gallium’s low melting point. The researchers propose that the key may be a large increase in entropy – a measure of disorder – when the bonds disappear, freeing up the atoms.

 
https://scitechdaily.com/new-findings-challenge-150-year-old-assumptions-scientists-discover-new-properties-of-unusual-metal/

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This Metal Turns Heat Into Electricity Using a Secret Hidden in Its Atomic Pattern

June 19, 2025

 

More than 200 years ago, the German physicist Thomas Seebeck discovered something seemingly magical: if you heat one side of certain materials while cooling the other, a small but steady stream of electricity appears. No moving parts. No spinning generators. Just heat transformed directly into electrical power. This phenomenon, known as the Seebeck effect, still powers deep-space probes like Voyager today.

 

But despite its promise, thermoelectric technology has remained stuck in the shadows—too inefficient, too costly, and too niche to compete with the roaring steam turbines that dominate modern power plants.

 

Now, that may be about to change.

 

In a new study published in Physical Review X, a team led by Professor Andrej Pustogow at the Institute of Solid State Physics at TU Wien has reported a major breakthrough: a novel class of thermoelectric materials, shaped by atomic patterns known as “Kagome geometry,” can outperform traditional compounds—and do so using metals far cheaper than the rare elements typically required.

 

It’s a discovery with the potential to transform waste heat—from industrial machinery, car engines, and even human bodies—into clean, usable electricity.

 

https://www.sciencenewstoday.org/this-metal-turns-heat-into-electricity-using-a-secret-hidden-in-its-atomic-pattern

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A step toward cleaner iron extraction using electricity

 

April 9, 2025

 

Iron and its alloys, such as steel and cast iron, dominate the modern world, and there's growing demand for iron-derived products. Traditionally, blast furnaces transform iron ore into purified elemental metal, but the process requires a lot of energy and emits air pollution. Now, researchers report that they've developed a cleaner method to extract iron from a synthetic iron ore using electrochemistry, which they say could become cost-competitive with blast furnaces.

https://www.sciencedaily.com/releases/2025/04/250409114953.htm

 

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The chemical industry is presented with an “unparalleled possibility” to alter the future of chemical processes.

 

January 17, 2024

Liquid metals could be the long-awaited solution to “greening” the chemical industry, according to researchers who tested a new technique they hope can replace energy-intensive chemical engineering processes harking back to the early 20^th century.

Around 10-15% of global greenhouse gas emissions stem from chemical manufacturing. Additionally, chemical plants consume over 10% of the world’s energy.

 

Findings recently published in Nature Nanotechnology offer a much-needed innovation that moves away from old, energy-intensive catalysts made from solid materials. The research is led by Professor Kourosh Kalantar-Zadeh, Head of the University of Sydney’s School of Chemical and Biomolecular Engineering, and Dr Junma Tang, who works jointly at the University of Sydney and UNSW.

 

A catalyst is a substance that makes chemical reactions occur faster and more easily without participating in the reaction. Solid catalysts, typically solid metals or solid compounds of metals, are commonly used in the chemical industry to make plastics, fertilizers, fuels, and feedstock.

 

However, chemical production using solid processes is energy-intensive, requiring temperatures of up to a thousand degrees centigrade.

 

The new process instead uses liquid metals, in this case dissolving tin and nickel which gives them unique mobility, enabling them to migrate to the surface of liquid metals and react with input molecules such as canola oil. This results in the rotation, fragmentation, and reassembly of canola oil molecules into smaller organic chains, including propylene, a high-energy fuel crucial for many industries.

https://scitechdaily.com/an-unparalleled-possibility-liquid-metals-shake-up-century-old-chemical-engineering-processes/

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Direct evidence revealed for rare pulsing pear-shapes in Gadolinium nuclei

March 18, 2025

Scientists have acquired direct evidence of rare, pulsing pear-shaped structures within atomic nuclei of the rare-earth element Gadolinium, thanks to new research. 

https://www.sciencedaily.com/releases/2025/03/250317164103.htm

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Gadolinium – The Magnetic Marvel Powering Modern Technology

April 17, 2025

In this fifteenth installment of our critical minerals series, we turn our focus to gadolinium—a rare earth element with extraordinary magnetic and neutron absorption properties. Named after the Finnish chemist Johan Gadolin, gadolinium is indispensable in medical imaging, nuclear reactors, and advanced electronics. Its unique characteristics allow it to enhance MRI scans, improve nuclear reactor efficiency, and even enable data storage innovations. As technology advances, so too does the demand for this critical mineral.

Why the U.S. Needs It

Gadolinium is crucial in several high-tech applications, particularly in healthcare. Its exceptional ability to enhance contrast in magnetic resonance imaging (MRI) makes it a cornerstone of modern diagnostics. In the energy sector, gadolinium’s neutron absorption capabilities make it essential for controlling nuclear fission reactions. Additionally, its magnetic properties are leveraged in high-performance computing, telecommunications, and even the development of next-generation refrigeration technologies. Without gadolinium, progress in these fields would be severely hindered.

https://ptoe.com/gadolinium-the-magnetic-marvel-powering-modern-technology/

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The Fascinating Uses of Gadolinium: Transforming Technology and Industry

03 Jan 2025

Gadolinium is a rare earth metal with the symbol Gd and atomic number 64. It's established as an indispensable element in numerous modern technologies and industrial applications. It has unique magnetic properties, ability to absorb neutrons, and high thermal stability. These properties make it an essential material for diverse sectors. For example, in healthcare, energy, electronics, and nuclear technology. As we look to the future, the importance of gadolinium is only expected to grow.

This article delves into the multiple uses of gadolinium. It showcases how this versatile element is transforming existing technologies. And it's also paving the way for new advancements in industries that shape our world.

https://www.aemree.com/news/uses-of-gadolinium.html

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Zirconium – The Unsung Hero of Nuclear Energy

May 7, 2025

Zirconium may not be a household name, but it plays a critical role in some of the most advanced technologies on the planet. Best known for its exceptional resistance to corrosion and high temperatures, zirconium is indispensable in nuclear reactors, aerospace applications, and cutting-edge electronics. As the fifty-fourth entry in our Critical Minerals Series, we delve into why zirconium is essential to America’s technological and energy future and why securing its domestic supply is a strategic necessity.
Why the U.S. Needs It

Zirconium’s primary use is in nuclear power plants, where it is a key component of fuel rod cladding. Its low neutron absorption properties make it ideal for safely containing nuclear fuel while allowing efficient reactor operation. Additionally, zirconium alloys are vital in aerospace engineering, advanced ceramics, and even medical implants due to their biocompatibility and durability. The demand for zirconium is only expected to rise as the U.S. expands its clean energy infrastructure and high-tech manufacturing.

https://ptoe.com/zirconium-the-unsung-hero-of-nuclear-energy/

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Yttrium – The Unsung Hero of Advanced Materials

May 6, 2025

Yttrium may not be a household name, but this rare earth element plays a vital role in some of the most cutting-edge technologies. From strengthening high-performance alloys to enabling powerful laser systems, yttrium’s unique properties make it indispensable. In this 53rd installment of the Critical Minerals Series, we dive into why yttrium is crucial to America’s technological future and the steps needed to secure its domestic supply.

Why the U.S. Needs Yttrium

Yttrium is essential for numerous advanced applications:

    Aerospace and Defense: Yttrium is a key component in thermal barrier coatings used in jet engines and missile systems, helping materials withstand extreme temperatures.
    Medical Innovations: Yttrium-90 is a radioactive isotope used in cancer treatment, particularly in targeted radiation therapies.
    Electronics and Optics: Yttrium-stabilized zirconia is critical for solid oxide fuel cells and high-performance optical materials, including camera lenses and night-vision devices.
    High-Strength Alloys: Adding yttrium to magnesium and aluminum alloys improves strength, corrosion resistance, and thermal stability, making it vital for structural components in automotive and aerospace industries.

https://ptoe.com/yttrium-the-unsung-hero-of-advanced-materials/


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Ytterbium – The Silent Power Behind Precision Technology

May 6, 2025

https://ptoe.com/ytterbium-the-silent-power-behind-precision-technology/

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Vanadium – Strengthening the Future of Energy and Industry

May 5, 2025

Vanadium: The Metal That Reinvents Steel and Batteries

In the realm of critical minerals, vanadium is an unsung hero. Used primarily as an alloying agent to strengthen steel, vanadium also plays a key role in emerging energy storage technologies. With the launch of this fifty-first article in our Critical Minerals Series, we shine a spotlight on this versatile metal and its significance in national security, infrastructure, and the clean energy revolution.

Why the U.S. Needs Vanadium

Vanadium is indispensable to multiple industries, particularly in high-strength steel production, aerospace applications, and advanced energy storage. When added to steel, vanadium increases its tensile strength, making it a crucial component in military vehicles, pipelines, and high-rise buildings. However, its future importance may lie in vanadium redox flow batteries (VRFBs), a promising technology for large-scale renewable energy storage. Unlike lithium-ion batteries, VRFBs have a much longer lifespan and are highly scalable, making them an attractive solution for grid-level energy storage.

https://ptoe.com/vanadium-strengthening-the-future-of-energy-and-industry/

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Tungsten – The Metal of Unrivaled Strength

May 5, 2025

Tungsten holds the highest melting point of any metal, a staggering 3,422°C (6,192°F), making it indispensable for high-temperature applications in aerospace, defense, and industrial manufacturing. As we conclude our Critical Minerals Series with this fiftieth installment, we highlight Tungsten’s vital role in securing America’s technological and military advantage while addressing the vulnerabilities in its supply chain.

Why the U.S. Needs It

Tungsten’s extreme hardness and heat resistance make it essential in high-stress environments such as jet engines, armor-piercing ammunition, and electrical applications. It is also used in radiation shielding, cutting tools, and wear-resistant coatings. The U.S. Department of Defense classifies Tungsten as a critical material due to its necessity in national security and energy sectors.

https://ptoe.com/tungsten-the-metal-of-unrivaled-strength/

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Titanium – The Metal of Strength and Innovation

May 5, 2025

https://ptoe.com/titanium-the-metal-of-strength-and-innovation/

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Research team develops new thin film deposition process for tin selenide-based materials

May 18, 2024

https://elnano.com/research-team-develops-new-thin-film-deposition-process-for-tin-selenide-based-materials/

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Innovative process opens up new perspectives for thin-film technology applications

 

23/06/2025

 

For the past five years, researchers at Leipzig University have been working on fundamentally new methods for selectively assembling gaseous, charged molecular fragments into new, complex molecules. The synthesised substances are deposited onto surfaces. This innovative process opens up new perspectives for applications in modern nanoelectronics and sensor technology. It also offers new avenues of research across various scientific disciplines – from catalyst research to medical applications. The scientists at Leipzig University, together with their collaborators at Purdue University (US), have published a summary of their findings from this period in the renowned journal Nature Reviews Chemistry. 

https://www.uni-leipzig.de/en/newsdetail/artikel/innovative-process-opens-up-new-perspectives-for-thin-film-technology-applications-2025-06-23

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Mushrooms' microscopic filaments provide a blueprint for better materials

June 10, 2025

Fungi have been around for many millions of years, with the incremental process of evolution honing and improving their survival skills through the millennia.

Now, Binghamton University researchers are studying the cell structure of fungi to learn how it determines their mechanical properties and what science can learn from that to create better materials.

In a paper recently published in Advanced Engineering Materials, a team from Binghamton and the University of California–Merced has looked at the microscopic filaments known as hypha that form a network-like structure in mushrooms and other fungi. By twisting around each other and branching within the larger structure, the hyphal filaments control how the fungi react to various mechanical stresses.

The two species they studied offered a contrast: The common white button mushroom (Agaricus bisporus) has only one type of hyphal filaments and typically grows with no definitive orientation, while the maitake mushroom (Grifola frondosa) has two types of filaments and grows in a preferential direction toward sunlight and moisture.

The researchers analyzed the mushrooms' cell structures by imaging with scanning electron microscopy and tested them to calculate the stress loads they could handle.

"Moving forward, the first step involves developing a finite element model—a computational framework that enables mechanical property testing and analysis in the second phase," said Mohamed Khalil Elhachimi, a Ph.D. student at the Thomas J. Watson College of Engineering and Applied Science's Department of Mechanical Engineering who served as first author on the research.

https://techxplore.com/news/2025-06-mushrooms-microscopic-filaments-blueprint-materials.html

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Porsche, Bcomp collaborate on racing car with all-natural fiber composite bodywork

10/01/2020

The Cayman 718 GT4 CS delivers a full natural fiber composite bodywork kit for the Four Motors racing team at the 24 Hours Nürburgring race.

https://www.compositesworld.com/news/porsche-bcomp-collaborate-on-racing-car-with-all-natural-fiber-composite-bodywork-

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ACMA to host new spring event focused on composites, sustainable solutions with Volkswagen Group

01/18/2022

https://www.compositesworld.com/news/acma-to-host-new-spring-event-focused-on-composites-sustainable-solutions-with-volkswagen-group

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BMW unveils new M4 GT4 race car, features most natural fiber parts for GT series to date

06/21/2022

Bcomp ampliTex and powerRibs technologies make up bodywork components such as the hood, front splitter, doors, trunk and rear wing and several interior components, taking next steps for future production models.

https://www.compositesworld.com/news/bmw-unveils-new-m4-gt4-race-car-features-most-natural-fiber-parts-for-gt-series-to-date

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Mechanical testing of ceramic matrix composites

07/23/2025

Today’s CMC materials, robust and resistant to high temperatures, provide their own set of challenges when determining their performance through mechanical testing.

https://www.compositesworld.com/articles/mechanical-testing-of-ceramic-matrix-composites


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Automating oxide CMC for higher part volumes

07/22/2025

FOX Composites has adapted infusion and RTM for slurry-based matrices, commercializing its VASI and IFOX technologies for automatable, scalable, serial production of high-quality oxide ceramic matrix composite parts, already proven in flight missions and a pilot-scale line.

https://www.compositesworld.com/articles/automating-oxide-cmc-for-higher-part-volumes


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Bio-inspired EV underbody panel developed by TPI Composites, Helicoid Industries

05/01/2023 

Composite underbody panel for battery pack protection, made of stacked multiaxial noncrimp fabric, will serve high-volume commercial and automotive markets.

https://www.compositesworld.com/news/bio-inspired-ev-underbody-panel-developed-by-tpi-composites-helicoid-industries


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All-recycled, needle-punched nonwoven CFRP slashes carbon footprint of Formula 2 seat

11/27/2024

Dallara and Tenowo collaborate to produce a race-ready Formula 2 seat using recycled carbon fiber, reducing CO2 emissions by 97.5% compared to virgin materials.

https://www.compositesworld.com/articles/all-recycled-needle-punched-nonwoven-cfrp-slashes-carbon-footprint-of-formula-2-seat


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Bcomp natural fiber composites to be used in future BMW Group production cars

06/18/2025

Bcomp partners with BMW Group to integrate high-performance natural fiber materials into series production models, reducing CO2 emissions for exterior and interior car parts.

https://www.compositesworld.com/news/bcomp-natural-fiber-composites-to-be-used-in-future-bmw-group-production-cars

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All-electric SUV motorsport vehicle incorporates Bcomp natural fiber bodywork 

04/07/2021

In preparation for the Extreme E racing series, Spark vehicles use ampliTex and powerRibs technologies for more sustainable, efficient and safe off-roading.

https://www.compositesworld.com/news/all-electric-suv-motorsport-vehicle-incorporates-bcomp-natural-fiber-bodywork-

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Automating oxide CMC for higher part volumes

 07/22/2025

FOX Composites has adapted infusion and RTM for slurry-based matrices, commercializing its VASI and IFOX technologies for automatable, scalable, serial production of high-quality oxide ceramic matrix composite parts, already proven in flight missions and a pilot-scale line.

https://www.compositesworld.com/articles/automating-oxide-cmc-for-higher-part-volumes

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Bcomp developments continue to drive natural fiber toward scalability in motorsports

11/17/2021

The Swiss sustainable lightweight manufacturer announces new developments for vehicle interiors, sustainability analyses results for ampliTEX and powerRibs reinforcements and recent technology recognition.

Bcomp (Fribourg, Switzerland), a natural fiber reinforcements manufacturer for high-performance applications ranging from race to space, has announced several new developments, from the addition of natural fiber interiors to racecars, next steps for McLaren’s Formula 1 (F1) racing seats and recent recognition for the company’s innovations.

Following the successful delivery of a full natural fiber composite bodywork kit for the doors and rear wing of Porsche Motorsport’s Cayman 718 GT4 CS back in October 2020, Bcomp has now outfitted the vehicle with a more sustainable interior to match. Nine interior carbon fiber parts — including the air channels, consoles, instrument cluster, glovebox and roof panel — were reverse engineered by Bcomp and replaced with natural fiber options using ampliTEX and powerRibs reinforcements, which are able to minimize vibrations as much as 250%. Visual components were also painted with a matt lacquer to match the finish of the GT4 CS series rear wing.

https://www.compositesworld.com/news/bcomp-developments-continue-to-drive-natural-fiber-toward-scalability-in-motorsports

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Bcomp ampliTex fabric is incorporated into bus A/C panels

10/23/2023

Proof of concept project leads to the manufacture of more environmentally responsible natural fiber-based bus panels by automotive supplier Eberspächer.

https://www.compositesworld.com/news/bcomp-amplitex-fabric-is-incorporated-into-bus-ac-panels

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Faurecia advances biocomposites, recyclability, reduced CO2 and sustainability in automotive

10/21/2022

Efforts include advancing NAFILean materials family in weight reduction and sustainability, as well as new Sustainable Materials division and R&D Center.

https://www.compositesworld.com/news/faurecia-advances-biocomposites-recyclability-reduced-co2-and-sustainability-in-automotive

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INCA secures $40 million funding commitment for biocomposites development

04/30/2023

INCA Renewable Technologies targets commercialization of hemp-based biocomposites line for automotive, wind, marine industries, moves forward with processing facility construction

https://www.compositesworld.com/news/inca-secures-40-million-funding-commitment-for-biocomposites-development

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Lingrove plant-based ekoa composite featured in Hyundai Palisade concept vehicle

01/10/2023

Carbon-neutral biocomposite enables interactive doorspear with look and feel of wood while protecting trees, enabling transparency and capacitive touch for futuretech.

https://www.compositesworld.com/news/lingrove-plant-based-ekoa-composite-featured-in-hyundai-palisade-concept-vehicle

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iPul pultrusion system enhances Carbon TT’s CFRP profile production for vehicle chassis

10/25/2021

Krauss Maffei’s subsidiary, Pultrex, delivers a customized iPul pultrusion system for the production of large profile parts for around 70,000 vehicle chassis annually.

https://www.compositesworld.com/news/ipul-pultrusion-system-enhances-carbon-tts-cfrp-profile-production-for-vehicle-chassis

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Ford Mustang Dark Horse features Carbon Revolution carbon fiber wheels

02/16/2023

The 19-inch, five-spoke Dark Horse wheels feature signature blue carbon fiber detailing, keeping with the blue accents throughout the vehicle’s interior and exterior.

https://www.compositesworld.com/news/ford-mustang-dark-horse-features-carbon-revolution-carbon-fiber-wheels

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Volkswagen unveils hemp fiber-based leather alternative with Revoltech

09/05/2024

Bio-based surface material made from industrial hemp is being developed and tested for possible use in Volkswagen vehicles from 2028 onward.

Volkswagen (Wolfsburg, Germany) has entered into a cooperation with the textiles manufacturer startup Revoltech GmbH (Darmstadt, Germany) to research and develop sustainable materials based on industrial hemp — specifically, a substitute for imitation leather. These could be used as surface materials in Volkswagen models starting in 2028.

The leather alternative is made from 100% bio-based hemp cultivated for the food industry. It is an all-natural, single-layer surface material called LOVR (“leather-free, oil-free, vegan and residue-based”) that is being developed specifically with the automotive industry in mind. It can reportedly be produced in existing industrial plants and recycled or composted at the end of its service life. The hemp fibers and a fully bio-based adhesive are combined using a distinctive technology and processed to become a surface material.

https://www.compositesworld.com/news/volkswagen-unveil-hemp-fiber-based-leather-alternative-with-revoltech

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Ohoskin, ReCarbon collaborate for aesthetic, bio-based composite

01/22/2024

Novel material to combine Ohoskin’s leather alternative made from orange and cactus byproducts with ReCarbon’s recycled carbon fiber.

Ohoskin (Sicilia), an Italian manufacturer developing a bio-based alternative material to animal leather, and ReCarbon (Busto Arsizio, Italy) a company that has developed a one-stop solution for the circularity of carbon fiber, have announced a collaboration to create a new material for the automotive, marine and furniture industries.

The material, which will be produced by combining Ohoskin’s leather alternative made from orange and cactus byproducts with ReCarbon’s recycled carbon fiber, will feature high strength, light weight and sustainability.

“ReCarbon’s recycled carbon fiber is an innovative and sustainable material that fits perfectly with the sustainability values behind our innovative material,” Ohoskin COO Stefano Mazzetti says. “Together, we believe we can offer the market a unique and cutting-edge product.”

“The collaboration with Ohoskin is an important step for ReCarbon,” Luca Grati, ReCarbon CEO, emphasizes. “We are convinced that the combination of Ohoskin’s sustainable material and recycled carbon fiber can create an elegant, lightweight and sustainable product in line with the needs of modern consumers.”

https://www.compositesworld.com/news/ohoskin-recarbon-collaborate-for-aesthetic-bio-based-composite

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RCCF of TU Dresden develops next-gen, 3D-printed structural supercapacitors

03/08/2023

Thales Research and Technology leads PRINTCAP project for more sustainable fast-charging, structural energy storage for automotive and aerospace industries using multifunctional composite materials

https://www.compositesworld.com/news/rccf-of-tu-dresden-develops-next-gen-3d-printed-structural-supercapacitors

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Scott Bader joins CHAMPION project to research novel bio-based polymers

08/11/2020

The bio-based polymers aim to replace conventional polymers in a variety of applications and promote alternative to end-of-life waste.

https://www.compositesworld.com/news/scott-bader-joins-champion-project-to-research-novel-bio-based-polymers

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Italian research agency fights COVID-19 with smart shelters using biocomposites

04/14/2020

SOS Smart Operating Shelter project offers fast-build mobile healthcare structures using natural fiber/biopolymer sandwich panels.

https://www.compositesworld.com/news/italian-research-agency-fights-covid-19-with-smart-shelters-using-biocomposites

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4M reveals progress with plasma oxidation for carbon fiber production

03/05/2020

Promising results following application of 4M Carbon Fiber’s plasma oxidation technology to make carbon fiber using polyacrylonitrile (PAN) precursor supplied by Formosa Plastics Corp.

https://www.compositesworld.com/news/4m-reveals-progress-with-plasma-oxidation-for-carbon-fiber-production

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Hexcel, NaCa Systems develop hybrid carbon/wood fiber composite car seat back

02/07/2020

Benefits are said to include a 40% weight savings and improved carbon footprint.

https://www.compositesworld.com/news/hexcel-naca-systems-develop-hybrid-carbonwood-fiber-composite-car-seat-back

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Revolutionizing space composites: A new era of satellite materials

07/28/2025

A new approach for high volumes of small satellite structures uses low-CTE, low-cost CFRP cellular core, robust single-ply skins and modular panel systems to cut lead time, labor and cost for reflectors, solar arrays and more.

https://www.compositesworld.com/articles/revolutionizing-space-composites-a-new-era-of-satellite-materials


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Bcomp natural fiber materials featured in Foiling SuMoth Challenge

08/21/2024

Hands-on application and imparted wisdom about biocomposites guided 11 participating student teams in their sustainable foiling moth designs for the three-stage content in July.

https://www.compositesworld.com/news/bcomp-natural-fiber-materials-featured-in-foiling-sumoth-challenge

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Biomaterials make strides toward composites sustainability

11/25/2024

A compilation of trends in development or application of natural fibers, bio-based resins and more showcases industry players, educational institutes and global projects.

https://www.compositesworld.com/articles/biomaterials-make-strides-toward-composites-sustainability

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Decathlon selects GreenPoxy bio-resin for latest sustainable wakeboards

03/14/2022

The sports equipment giant combines GreenPoxy 33 with FSC-accredited wood cores and monitors all ecological impacts of the manufacturing process, keeping the environment at the heart of its newest designs.

https://www.compositesworld.com/news/decathlon-selects-greenpoxy-bio-resin-for-latest-sustainable-wakeboards

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Sicomin GreenPoxy 33 chosen for Spleene kiteboard range

01/10/2024

Flax fiber multiaxial reinforcement plies, a CNC milled wood core and bamboo rail sections are press molded together using Sicomin’s bio-epoxy resin system for an eco-friendly twintip kiteboard production

Sicomin (Châteauneuf les Martigues, France), a formulator of high-performance epoxy resin systems, has confirmed its GreenPoxy 33 bio-resin range will be used by Spleene Kiteboarding (Baden-Württemberg, Germany) in its new Eco Line RIP 39 boards.  

Designed and developed with a commitment to genuine sustainability during a 2-year collaboration with the Technical University of Applied Sciences Augsburg (Germany) and the German Federal Ministry for Economic Affairs and Climate Action, all aspects of the Eco Line RIP 39 twintip kiteboard’s construction were reviewed. Flax fiber multiaxial reinforcement plies, a CNC milled wood core and bamboo rail sections are press molded together using Sicomin’s bio-epoxy resin system.

https://www.compositesworld.com/news/sicomin-greenpoxy-33-chosen-for-spleene-kiteboard-range

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MIT team engineers plant-derived composite with potential for stronger, tougher applications

03/04/2022

Tough as bone, hard as aluminum and resembling a nacre microstructure, the cellulose nanocrystal may pave the way for naturally derived composites.

https://www.compositesworld.com/news/mit-team-engineers-plant-derived-composite-with-potential-for-stronger-tougher-applications

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We see too many Boats, Jet Skis and WaveRunners made out of fiberglass. Many people even do fiberglass repairs on their boats in the water. Many of these Fiberglass pieces end up in our Oceans and lakes. We need an alternative material to build watercraft, cars and other vehicles. People have been using wood and metals for hundreds of years. We should phase out many fiberglass materials in boats and cars, we need to have better environmentally friendly materials. 

 

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Fassmer, Greenboats partner to enhance natural fiber development

11/22/2023

An established Germany-based manufacturing site to produce natural fiber laminates, as well as production of Greenboats fibers at a Fassmer facility.

Fiber composite technology company Fassmer (Berne, Germany) and Greenboats (Bremen, Germany) announce a formal partnership to enhance sustainable manufacturing technologies in Germany. Greenboats will establish the production of its ecological composite materials at Fassmer’s facility, thus creating a globally distinctive manufacturing site, distinguished by its production scope and sustainability.

This cooperation merges Fassmer’s decades of experience in composite technologies with Greenboats’ expertise in developing natural fiber composites. As part of the agreement, a production facility, designed to manufacture natural fiber-reinforced composite laminates up to 6 × 2.5 meters, and characterized by the use of eco-friendly flax fibers and bio-based resins, will be constructed. It will ultimately produce products with significantly reduced CO2 footprints and set recycling benchmarks...

https://www.compositesworld.com/news/fassmer-greenboats-partner-to-enhance-natural-fiber-development

 

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Greenboats announces sailing boat with biocomposite construction

11/15/2023

The MB9, representing a combination of high performance and eco-conscious materials use, will be commercially available in time for the 2024 sailing season.

In a stride toward eco-friendly maritime innovation, Greenboats (Bremen, Germany) announces the launch of the MB9 sailing boat. Designed by the veteran naval architect Matthias Bröker of design engineering company Judel/Vrolijk (Bremerhaven, Germany), the MB9 represents a fusion of top-tier performance and sustainability, highlighting Greenboat’s expertise in natural fiber reinforcements and natural fiber-reinforced composite semi-finished products. Having just "hit the water," the vessel is poised for final outfitting before its official debut in the 2024 sailing season.

At the heart of the MB9’s design is its eco-conscious construction, offering the potential of bio-based materials in marine construction. The sailing boat is almost entirely from natural materials like flax, balsa wood and bio-epoxy; flax fiber in particular is known for its durability, noise reduction and eco-friendly properties. Notably, only the rudder shaft and keel fin are crafted from carbon fiber, ensuring robustness where it is most needed. The construction results in a vessel weighing just over three tons.

Tailored for regatta racing, the MB9 is the epitome of ergonomic design and efficiency, Greenboat says. Its cockpit is meticulously laid out for single-handed and double-handed racing, reflecting Bröker's aspirations for participating in prominent races in Germany and Denmark. The attention to detail extends to customizing dimensions for the owner’s comfort, enhancing the boat's competitive edge.

https://www.compositesworld.com/news/greenboats-announces-sailing-boat-with-biocomposite-construction

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Nlcomp launches recyclable composite sailing boat Ecoracer30

07/07/2023

Italian startup featured its 30-foot sustainable production boat at the Ocean Race Grand Finale in Genoa, Italy, citing the challenges, highlights and future related to its development.

https://www.compositesworld.com/news/nlcomp-launches-recyclable-composite-sailing-boat-ecoracer30

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Refurbished Einstein yacht demonstrates innovative composites repair and redesign

02/15/2023

Years of creative engineering work went into resurrecting the composites-intensive IMOCA 60 racing yacht — with award-winning results.

https://www.compositesworld.com/articles/refurbished-einstein-yacht-demonstrates-innovative-composites-repair-and-redesign

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French sailmaker incorporates Aluula composites aboard Biotherm race boat

05/22/2023

Incidence Sails has successfully integrated Aluula Durlyte into its long-distance ocean race sails after withstanding two years of rigorous testing in numerous open ocean races.

Aluula Composites (Victoria, BC, Canada), an advanced materials technology firm, reports the addition of a new brand partner, Incidence Sails (La Rochelle), a French sailmaker, to introduce a new generation of ultralight, strong and recycle-ready composite material for use in sustainable sailmaking.

After two years of thorough testing on and off the water, Incidence Sails is commercializing Aluula Durlyte, primarily for critical sail reinforcements such as batten pockets, bolt ropes and high wear points such as stanchions and spreaders — additional applications include decksweepers and sail bags. Durlyte consists of a tough, technical film fusion bonded to Aluula’s ultrahigh molecular weight polyethylene (UHMWPE) core via the company’s patented fusion technology, resulting in a lamination that is said to produce a “family of high-performance composite fabrics with a low friction surface and high strength-to-weight ratio.” In addition, the material offers 10 times the abrasion resistance of competing materials; it’s bacteria- and water-resistant; recyclable; accepts heat welding, can be seam taped and is thermoformable; and is proven by Incidence Sails in Transat Jacques Vabre, Route du Rhum and The Ocean Race...

https://www.compositesworld.com/news/french-sailmaker-incorporates-aluula-composites-aboard-biotherm-race-boat

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How seawater and limestone could be used to reduce maritime emissions

Jul. 6, 2025

 

Maritime CO2 emissions could be reduced by as much as 50 per cent with the use of a new shipboard system being developed by American universities and a startup firm, according to a recently published study.

https://www.theweathernetwork.com/en/news/climate/solutions/how-seawater-and-limestone-could-be-used-to-reduce-maritime-emissions-carbon-dioxide-greenhouse-gases

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New method stores high-density methane in graphene-coated nanoporous carbon

June 27, 2025

Methane (CH4), one of the most abundant natural gases on Earth, is still widely used to power several buildings and to fuel some types of vehicles. Despite its widespread use, storing and transporting this gas safely remains challenging, as it is highly flammable and requires compression at high pressures of around 25 megapascals (MPa)...

https://techxplore.com/news/2025-06-method-high-density-methane-graphene.html

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Melker of Sweden accomplishes sea kayak with 100% sustainable composite construction

11/01/2024

Built with ampliTex flax fabrics, a solid cork core and Sicomin plant-based resins, the company’s Värmdö kayak model highlights an environmentally conscious design for paddlers of all levels.

Melker of Sweden’s (Solna) approach to innovation and sustainability has been realized through the Värmdö sea kayak. Its shift toward lightweight, high-performance and plant-based construction has been achieved through the use of Bcomp Ltd. (Fribourg, Switzerland) ampliTex flax fibers, Sicomin (Chateuneuf les Martigues, France) GreenPoxy resins and GreenCoat gelcoats and a cork core. The kayak recently won Product of the Year 2025 in the Sea Kayaking category at the Paddle Sports Show in Strasbourg, France.

Melker kayaks are designed and developed in Sweden. Värmdö highlights a sandwich layup with a solid cork core (harvested from the bark of cork oak trees) and flax fiber reinforcement. More specifically, these materials include:


    Sicomin InfuGreen 810 resin, DNV GL-certified with 38% bio-carbon content, offering ultra-low viscosity for efficient room-temperature infusion.
    Sicomin Green Coat transparent gelcoat, a robust, UV-resistant coating with 50% plant-based content that protects and enhances the natural look of the kayak’s flax and cork laminates.

    Amorim NL20 cork core providing lightweight strength and impact resistance.

The structure is vacuum infused with GreenPoxy resins, heat cured and finalized with the Green Coat gelcoat. Melker says this approach provides a combination of high mechanical properties with a design that is environmentally respectful.

The Värmdö is aimed at a broad range of paddlers — from beginners to experienced paddlers looking for a versatile kayak that can handle everything from relaxed paddling to more adventurous activities like surfing and exploring rocky areas.

For 2025, all Melker models will feature this same construction approach, incorporating Bcomp flax reinforcement fabrics, Amorim cork and plant-based resins and gelcoats from Sicomin. 

In addition to these innovations, Melker is involved in in-house R&D and rapid prototyping using large-scale additive manufacturing (LSAM) for a more efficient product development, and a new plant-based material. “This is significant for us,” the company says. “We can listen to the market's needs and quickly 3D print a full-sized prototype in one piece, which we can then intense field test in natural conditions and under different circumstances. We repeat the process until we are completely satisfied. In the final step, we manufacture molds for efficient and sustainable serial production.”

The material used for 3D printing Melker’s prototypes is recycled kayaks — shredded and re-compounded with upcycled fishing nets collected on Sweden’s west coast, along with wood fibers from Finnish pine forests. This means that not only the finished product is plant-based, but the prototypes are also created from recycled, upcycled and plant-based materials.

https://www.compositesworld.com/news/melker-of-sweden-accomplishes-sea-kayak-with-100-sustainable-composite-construction

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Sicomin bio-based resins used in flax fiber-reinforced boat

02/05/2020

The hull, deck and internal structure the FLAX 27 sailing boat were infused with Sicomin’s GreenPoxy InfuGreen 810 resin and flax fiber reinforcement fabrics.

https://www.compositesworld.com/news/sicomin-bio-based-resins-used-in-flax-fiber-reinforced-boat-

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Haydale graphene contributes to stronger, lighter sea kayaks

02/20/2023

Bespoke mechanical graphene masterbatch was effectively used in a resin infusion process to increase the strength, stiffness and breakage resistance of Norse Kayaks’ products.

https://www.compositesworld.com/news/haydale-graphene-contributes-to-stronger-lighter-sea-kayaks

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Sicomin epoxy resins power Candela composite boat construction

10/16/2023

Candela’s zero-emission P-12 foiling passenger shuttle offers low vessel weight, higher journey frequency with its carbon fiber-reinforced epoxy fabrication.

https://www.compositesworld.com/news/sicomin-epoxy-resins-power-candela-composite-boat-construction

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AmpliTex-constructed solar-powered ferry hits the Adriatic Sea

09/20/2024

The Marservis PROeco is a mass transportation marine vessel using Bcomp natural fiber for interior parts in place of standard materials.

https://www.compositesworld.com/news/amplitex-constructed-solar-powered-ferry-hits-the-adriatic-sea

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Toyoda Gosei develops seawater-derived fiber-reinforced material

05/14/2024

Fiber reinforcement is formed from magnesium hydroxide derived from seawater, achieving plastic parts that contributed to improved environmental performance.

https://www.compositesworld.com/news/toyoda-gosei-develops-seawater-derived-fiber-reinforced-material

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DITF, RBX Créations develops hemp-based pulp for filament-spun cellulose fibers

09/18/2024

Partners present a complete process chain for the development of hemp-based fibers, yarns and fabrics using energy- and resource-saving processes.

A partnership between the German Institutes of Textile and Fiber Research Denkendorf (DITF) and RBX Créations (Jonzac, France), an SME developing sustainable materials with hemp and flax cellulose, has resulted in a hemp-based pulp and its further processing into filament-spun cellulose fibers.

Together, the companies present a complete textile production chain — from raw materials to processing, spinning technology and the realization of textile products. The raw hemp is grown and obtained locally (offering a low carbon footprint), which is then processed into a fine-fibered pulp in a process patented by RBX Créations, and dissolved in an ionic liquid. This then serves as the raw material for a wet spinning process developed at the DITF and patented under the name HighPerCell. The solution is spun into cellulose fibers in a precipitation bath — using a solvent that can be completely recovered and reused — for development of textile fibers, yarns and fabrics.

https://www.compositesworld.com/news/ditf-rbx-creations-develops-hemp-based-pulp-for-filament-spun-cellulose-fibers

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Alliance of European Flax-Linen & Hemp announces positive outlook for 2024 flax fiber harvest

07/10/2024

https://www.compositesworld.com/news/alliance-of-european-flax-linen-hemp-announces-positive-outlook-for-2024-flax-fiber-harvest

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Project Greenlift to develop ground-effect Cicada222x prototype

11/19/2024

Bio-inspired Australian-made craft featuring hemp-reinforced fuselage panels and sustainable fuel capabilities is positioned to meet disaster relief, e-commerce and military needs.

https://www.compositesworld.com/news/project-greenlift-to-develop-ground-effect-cicada222x-prototype-

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CELC changes name to Alliance for European Flax-Linen & Hemp

12/14/2022

The Alliance for European Flax-Linen & Hemp is launching its new identity in early 2023 for all target groups, including natural fiber composite applications.

https://www.compositesworld.com/news/celc-changes-name-to-alliance-for-european-flax-linen-hemp

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Grand Largue Composites, Sicomin enable flax fiber-built Class40 racing yacht

11/09/2022

Fibers, fabrics, epoxy resins and adhesives from Sicomin helped realize the lightweight, strong and stiff Crosscall yacht, capable of tackling extreme ocean racing conditions.

https://www.compositesworld.com/news/grand-largue-composites-sicomin-enable-flax-fiber-built-class40-racing-yacht

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Flax fiber producer Group Depestele invests in Greenboats GmbH

09/15/2023

Group Depestele acquires a minority share of Greenboats in an effort to redefine the applications of natural fiber-reinforced composites on a global scale.

https://www.compositesworld.com/news/flax-fiber-producer-group-depestele-invests-in-greenboats-gmbh

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Notox surfboards harness flax fiber for wave surfing competition

12/16/2024

Libeco flax, Airbus rCF fabrics, Sicomin GreenPoxy bioresins and an agave core form a heavy, robust surfboard custom-designed for Clément Roseyro in this year’s Nazaré Big Waves Surf event.

https://www.compositesworld.com/news/notox-surfboards-harness-flax-fiber-for-wave-surfing-competition

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Cobra Advanced Composites launches flax fiber-based visual finish components

10/12/2022

New range of sustainable, low-density, production-ready composite components meet challenging automotive OEM standards for exterior and interior applications.

https://www.compositesworld.com/news/cobra-advanced-composites-launches-flax-fiber-based-visual-finish-components

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OceanWings demonstrate wind-assisted propulsion potential via Canopée

06/27/2025

For the last two years, the vessel that transports components of the Ariane 6 rocket has proven the success and viability of its installed OceanWings, including fuel savings, aerodynamic performance and versatility.

https://www.compositesworld.com/news/oceanwings-demonstrate-wind-assisted-propulsion-potential-via-canopee

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EconCore, Flaxco reveal flax fiber-reinforced thermoplastic honeycomb panels

04/04/2022

Natural fiber sandwich panels are expected to replace those made from glass and carbon fiber, offering enhanced rigidity and sustainability for applications in automotive and sporting good markets.

https://www.compositesworld.com/news/econcore-flaxco-reveal-flax-fiber-reinforced-thermoplastic-honeycomb-panels

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Nordic Bioproducts successfully spins novel plant-based textile fiber

01/27/2022

The Finnish startup begins an intensive product development period to scale up its Norratex fiber, which is manufactured without toxic chemicals or expensive solvents.

https://www.compositesworld.com/news/nordic-bioproducts-successfully-spins-novel-plant-based-textile-fiber

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Sigmatex launches recycled carbon fiber non-woven fabric

01/24/2020

https://www.compositesworld.com/news/sigmatex-launches-recycled-carbon-fiber-non-woven-fabric

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HyPoint partners with GTL to extend zero-emission flight with ultralight liquid hydrogen tanks

03/30/2022

NASA award-winning fuel cell pioneer works with carbon fiber tank maker GTL to offer up to 10 times more capacity versus existing hydrogen storage tanks.

https://www.compositesworld.com/news/hypoint-partners-with-gtl-to-extend-zero-emission-flight-with-ultralight-liquid-hydrogen-tanks

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Bcomp, KTM Technologies brake cover listed as finalist for JEC Innovation Awards 2022

03/25/2022

Flax fibers were used to reduce the CO2 emission of the motocross brake cover by 82%, with KTM’s Conexus for effective bonding between thermoset and thermoplastic parts.

https://www.compositesworld.com/news/bcomp-ktm-technologies-brake-cover-listed-as-finalist-for-jec-innovation-awards-2022

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Hypetex creates colored carbon fiber covers for IQOS tobacco heating devices

03/23/2022

The U.K. manufacturer and supplier of advanced materials coordinated all aspects, from initial concept to final solution, including a fully optimized production process.

Hypetex (London, U.K.) and Philip Morris International (PMI, Stamford, Conn., U.S.), owners of the heated tobacco devices brand IQOS, have recently collaborated on a development program to create colored carbon fiber composite covers for IQOS tobacco heating devices.

PMI claims that tobacco heating devices offer a smoke-free alternative that provide a better choice for those that would otherwise continue to smoke. PMI approached Hypetex with the objective to identify a viable composite material solution to create the IQOS accessories in a visual, colored carbon fiber material, as well as defining an easily scalable production process and manufacturing supply chain using Hypetex’s in-mold, colored composite technology.

https://www.compositesworld.com/news/hypetex-creates-colored-carbon-fiber-covers-for-iqos-tobacco-heating-devices

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AZL Aachen conducts study to evaluate the biocomposites market

03/03/2022

Comprehensive Joint Market and Technology report identifies CAGR for natural fibers, biopolymers and bio-based composites market will reach 22.7% between 2021 and 2026.

https://www.compositesworld.com/news/azl-aachen-conducts-study-to-evaluate-the-bio-based-composites-market

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Series A funding expands production for Lingrove’s Ekoa natural fiber materials

02/25/2022

Carbon-negative Ekoa composite, a substitution for wood and plastics in furniture, interiors and automotive applications, will be scaled up to deliver to far-reaching global customers.

https://www.compositesworld.com/news/series-a-funding-expands-production-for-lingroves-ekoa-natural-fiber-materials

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Diab reduces carbon footprint by 46%

02/23/2022

Between 2016 and 2021, the sandwich composite solutions company made alterations in material, reduced waste and efficient use of waste, production and energy sources to drive its reduction efforts.

https://www.compositesworld.com/news/diab-reduces-carbon-footprint-by-46

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3A Composites Core Materials passes annual FSC review 

12/17/2021

Audit identifies effort in maintaining sustainability mindset, efficient waste management, responsible forestry in the production of core materials.

https://www.compositesworld.com/news/3a-composites-core-materials-passes-annual-fsc-review-

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Six nominees chosen for Cellulose Fibre Innovation of the Year 2022 award

12/08/2021

Cellulose fiber solutions, chosen by International Conference on Cellulose Fibres conference advisory members, range from cellulose made of orange and wood pulp, to a novel technology for cellulose fiber production.

https://www.compositesworld.com/news/six-nominees-chosen-for-cellulose-fibre-innovation-of-the-year-2022-award

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University of Bristol studies mycelium composites as alternative building materials

02/09/2024

Affordable, lightweight and sustainable composite materials made from mycelium — mushroom roots — may have potential for packaging materials, insulation panels, floor tiles and furniture. 

https://www.compositesworld.com/news/university-of-bristol-studies-mycelium-composites-as-alternative-building-materials

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3A Composites Core Materials commits to sustainable growth, harvesting and processing of balsa wood

12/06/2021

https://www.compositesworld.com/news/3a-composites-core-materials-commits-to-sustainable-growth-harvesting-and-processing-of-balsa-wood

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DITF researches lignin-based protective coating for natural fiber geotextiles

10/27/2023

The bio-based coating was applied to yarns and textile surfaces to extend service life with positive results, suggesting its future application in civil engineering

The German Institutes of Textile and Fiber Research Denkendorf (DITF) are developing a bio-based protective coating, based on lignin, that extends the service life of natural fiber textiles, particularly those used in civil engineering applications. 

Depending on humidity and temperature, natural fiber materials can degrade in soil in a matter of months or even a few days. To extend the degradation time and make them suitable for geotextiles, the DITF team is studying the use of its lignin-based coating, which in itself is biodegradable and does not generate microplastics in the soil. Nevertheless, this degradation takes a very long time in nature.

Together with cellulose, lignin forms the building materials for wood — it is the “glue,” holding this composite material together. In paper production, usually only the cellulose is used, so lignin is produced in large quantities as a waste material. So-called kraft lignin remains as a fusible material. In addition, textile production can deal well with thermoplastic materials. Ultimately, these facts are why DITF believes lignin would be suitable for geotextiles. 

Lignin is brittle by nature. Therefore, it is necessary to blend the kraft lignin with softer biomaterials. For this project, these novel biopolymer compounds of brittle kraft lignin and softer biopolymers were applied to yarns and textile surfaces via adapted coating systems. For this purpose, for example, cotton yarns were coated with lignin at different application rates and evaluated. Biodegradation testing was carried out using soil burial tests in a climatic chamber with temperature and humidity defined precisely according to the standard, and outdoors under real environmental conditions.

According to DITF, the results were positive: The service life of textiles made of natural fibers can be extended by many factors with a lignin coating. The thicker the protective coating, the longer the protection lasts. In the outdoor tests, the lignin coating was still completely intact even after about 160 days of burial.

According to the team, textile materials coated with lignin enable sustainable applications. Providing an adjustable and sufficiently long service life for certain geotextile applications, in addition to still remaining biodegradable, the textiles have the potential to significantly reduce the carbon footprint. 

Nevertheless, further research is still needed to establish lignin, which was previously a waste material, as a new valuable material in industrial manufacturing processes in the textile industry.

https://www.compositesworld.com/news/ditf-researches-lignin-based-protective-coating-for-natural-fiber-geotextiles

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Metsä Group’s Kuura textile shows competitive GHG levels to existing commercial fibers

02/12/2025

A recent LCA shows that compared to viscose, lyocell and cotton fibers, large-scale production of Kuura would result in less environmental impact.

Metsä Spring (Espoo, Finland), the innovation company of Metsä Group, has completed a new life cycle assessment (LCA) of its Kuura textile fiber produced from softwood pulp, with results indicating that the large-scale production of the material would result in reduced greenhouse gas (GHG) emission levels.

To assess the environmental impact of a possible first commercial-scale mill producing Kuura, Metsä Spring asked technology service company Etteplan (Espoo) to conduct a study using standard LCA methodology. The study results were reviewed by RISE Research Institutes of Sweden. Kuura’s production process is also currently being tested and developed at a greenfield demo plant in Äänekoski, Finland, which features a nominal capacity of approximately 1 tonne/day.

The assessment shows that Kuura’s global warming potential (GWP100, fossil) score is less than one-third of the next best option, viscose. GWP is a term used to describe the relative potency, molecule for molecule, of a greenhouse gas, considering how long it remains active in the atmosphere. Kuura's GWP is only one-quarter of cotton fiber and more than 80% lower than the impact of lyocell fiber.

“Metsä Group aims to introduce a new textile fiber product to the market that would be competitive on many different metrics,” says Niklas von Weymarn, CEO of Metsä Spring. “Environmental impacts, and in particular the potential to mitigate climate change, is one key metric. Our assessment with external experts shows that our chosen concept has great potential. This will give impetus to further development.”

Contributing to Kuura’s success is the fact that it would, on an industrial scale, be produced and integrated into Metsä Group’s existing pulp-processing mill, which the company says does not use any fossil energy. In practice, the bioproduct mill generates significant amounts of excess renewable energy (steam, electricity and so on), which would be used to meet the energy demand of producing Kuura.

Kuura is produced from softwood Kraft pulp, not from dissolving pulp, which is commonly used as raw material in the production of man-made cellulosic fibers such as lyocell and viscose fibers. The wood for pulp production would be procured from forests located close to the pulp and textile fiber mills.

Von Weymarn says the main use pathways for Kuura (based on market volume) include the following: Spinning the fiber into a yarn and processing the yarn into knitted of woven fabrics, and manufacturing nonwoven fabrics. “A third, although smaller potential application area is various composite structures,” von Weymarn tells CW. “Other man-made cellulosic fibers (like viscose) are already used in such structures today and so might also be an opportunity for the Kuura fiber. On a lab scale, we have tested the use of our fiber as a reinforcing component.”..

https://www.compositesworld.com/news/metsa-groups-kuura-textile-shows-competitive-ghg-levels-to-existing-commercial-fibers

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Lingrove secures $10 million in financing to ramp up plant-based ekoa production

12/18/2023

New support will enable climate-friendly, high-performance and aesthetically pleasing interiors made from ekoa natural fiber composite surfaces and panels.

https://www.compositesworld.com/news/lingrove-secures-10-in-financing-to-ramp-up-plant-based-ekoa-production

____________________________________

 

Natural Fibers for Composites

https://www.compositesworld.com/topics/natural-fibers

____________________________________

 

Grafen AB introduces graphene-coated textiles

11/12/2021

https://www.compositesworld.com/news/grafen-ab-introduces-graphene-coated-textiles

____________________________________

 

Green Alternative to Graphite Mining Unveiled for Graphene Oxide Production

March 3, 2025

https://miningtechnologyinsights.com/2025/03/03/green-alternative-to-graphite-mining-unveiled-for-graphene-oxide-production/

____________________________________

 

Easy Composites partners with Eco-Technilin to deliver sustainable, natural fiber composites products

10/26/2021

Product range includes Eco-Technilin Fibrimat nonwoven, FlaxDry woven, FlaxTape UD and FlaxPreg prepreg reinforcements and feature excellent vibration damping properties.

https://www.compositesworld.com/news/easy-composites-partners-with-eco-technilin-to-deliver-sustainable-natural-fiber-composites-products

 

____________________________________

Porcher Industries strengthens partnership with Terre de Lin

05/01/2023

Technical and commercial cooperation enables Terre de Lin to deliver flax rovings to Porcher for the production of woven Polypreg Flax/TP composite reinforcements.

https://www.compositesworld.com/news/porcher-industries-strengthens-partnership-with-terre-de-lin

____________________________________

 

Hypetex wins Innovate UK Smart grant for FlaxTex composite

05/22/2024

In addition to its aesthetic qualities, the novel colored natural fiber is waterproof, 100% biodegradable and features enhanced manufacturing attributes thanks to Hypetex’s coloring process

https://www.compositesworld.com/news/hypetex-wins-innovate-uk-smart-grant-for-flaxtex-composite

____________________________________


Lanxess reveals highly sustainable Scopeblue composite material series

10/19/2021

PA6 glass fiber-reinforced compound under Lanxess’ new Scopeblue series is made from 92% sustainable raw materials, with content goals headed toward 100%.

https://www.compositesworld.com/news/lanxess-reveals-highly-sustainable-scopeblue-composite-material-series

____________________________________

 

BioStruct project to validate biocomposite-focused manufacturing processes

05/14/2024

For the next 3 years, Ideko and European partners are working to develop and validate to TLR 7 novel processes to boost the use of natural fibers and biological resins.

https://www.compositesworld.com/news/biostruct-project-to-validate-biocomposite-focused-manufacturing-processes

____________________________________

 

New research developments identify new methods for bio-derived carbon filler reinforcement for biocomposites

01/16/2023

Sustainable methodologies employed by researchers from Tuskegee University enable the synthesis of carbon from biomass-based precursor materials, and its effective reinforcement in composites.

https://www.compositesworld.com/news/new-research-developments-identify-new-methods-for-bio-derived-carbon-filler-reinforcement-for-biocomposites

____________________________________

 

Carbon fiber, additive manufacturing enhance Pleko spike shoe performance

10/11/2021

Developed with 3D scanning support from Diadora and CRP Technology’s Windform SP carbon fiber-filled composite material and 3D printing process for a track shoe that meets individuals’ needs in terms of foot structure and athletic performance.

https://www.compositesworld.com/news/carbon-fiber-additive-manufacturing-enhance-pleko-spike-shoe-performance

____________________________________

 

Nanofibers yield stronger, tougher carbon fiber composites

June 17, 2025

 

 

A carbon fiber is prepared for mounting in a device to test its adhesion to a polymer matrix. ORNL researchers are using polymer nanofibers to increase the adhesion, and thus the performance, of carbon fiber composites. 

https://www.ornl.gov/news/nanofibers-yield-stronger-tougher-carbon-fiber-composites

____________________________________

 

Georgia Tech leads effort to tackle the composite and hybrid materials challenge

08/24/2021

New National Science Foundation (NSF) center combines industry and academia, uses analytics, AI to modernize how manufacturers repair composites.

https://www.compositesworld.com/news/georgia-tech-leads-effort-to-tackle-the-composite-and-hybrid-materials-challenge

____________________________________

 

GreenLight project explores fire-resistant and bio-based FRPs for structural lightweight design in ships

08/11/2021

Project leader Fraunhofer IFAM and six associated partners to study FRPs such as polybenzoxazine- and benzoxazine-based composite materials to meet strict safety regulations, requirements on passenger ships.

https://www.compositesworld.com/news/greenlight-project-explores-fire-resistant-and-bio-based-frps-for-structural-lightweight-design-in-ships

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NTU Singapore, Arkema manufacture carbon fiber helmets using Elium resin

07/30/2021

Carbon fiber reinforcement increases stiffness, toughness of the helmet’s outer shell and allows it to absorb more impact energy over a longer period.

https://www.compositesworld.com/news/ntu-singapore-arkema-manufacture-carbon-fiber-helmets-using-elium-resin

____________________________________

 

Deutsche Aircraft and H2FLY join forces to explore hydrogen powered flight

07/09/2021

First flight of Dornier 328 demonstrator with fuel cell planned for 2025 to display potential for climate-neutral regional flights.

https://www.compositesworld.com/news/deutsche-aircraft-and-h2fly-join-forces-to-explore-hydrogen-powered-flight

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Testing validates, prepares Verne CcH2 truck for commercialization

01/22/2025

Verne has demonstrated the density and dormancy benefits of its cryo-compressed hydrogen Class 8 truck and refueling system, moving the technology forward for trucking and hydrogen distribution.

https://www.compositesworld.com/news/testing-validates-verne-cch2-truck-prepares-for-commercialization

____________________________________

 

Basaltex reveals basalt fiber milestone for use in rail carriage interiors

06/17/2021

Testing and development of basalt fiber, bioresin and rPET combo achieves rigidity, fire resistance and lightweight properties that meet railway application standards.

https://www.compositesworld.com/news/basaltex-reveals-basalt-fiber-milestone-for-use-in-rail-carriage-interiors

____________________________________

 

Michelman provides fiber sizing support for FibreCoat aluminum-coated basalt fibers

02/07/2025

AluCoat, addressing applications requiring conductive and lightweight materials, integrates Hydrosize which provides the right balance of sizing for optimal processing, unlocking key fiber attributes.

https://www.compositesworld.com/news/michelman-provides-fiber-sizing-support-for-fibrecoat-aluminum-coated-basalt-fibers

____________________________________

 

Use of basalt fibers for concrete structures

 

2015

 

Abstract

 

This study investigated the use of basalt fiber bars as flexural reinforcement for concrete members and the use of chopped basalt fibers as an additive to enhance the mechanical properties of concrete. The material characteristics and development length of two commercially-available basalt fiber bars were evaluated. Test results indicate that flexural design of concrete members reinforced with basalt fiber bars should ensure compression failure and satisfying the serviceability requirements. ACI 440.1R-06 accurately predicts the flexural capacity of members reinforced with basalt bars, but it significantly underestimates the deflection at service load level. Use of chopped basalt fibers had little effect on the concrete compressive strength; however, significantly enhanced its flexural modulus.

 

 https://www.sciencedirect.com/science/article/abs/pii/S0950061815301653

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Basalt fibers: the green material of the XXI-century, for a sustainable restoration of historical buildings

2021

https://www.academia.edu/47001045/Basalt_fibers_the_green_material_of_the_XXI_century_for_a_sustainable_restoration_of_historical_buildings

____________________________________

 

A Sustainable fiber

 

Basalt fibers are made purely from the single raw material of basalt volcanic rock. It is effectively a thread of stone.

 

Made without the addition of chemicals like boric acid (glass fibers) or any other minerals, these fibers are sustainable, recyclable, circular and environmentally-neutral.

 

They are considered circular as they contain no additives and basalt fibers can be recycled by simply melting them down to create new fibers of exactly the same quality.

 

Basalt fibers are environmentally-neutral as they are made from 100% natural rock and any basalt residue in the environment will not disturb any eco system. They are an effective alternative to plastics, preventing the release of damaging micro plastics into our oceans.

 

Basalt fibers are produced directly from basalt rock, of which there is a sustainable and plentiful global supply.

https://www.basaltex.com/sustainable-fiber

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Eco-Marine textiles

 

Basalt fibers are environmentally-neutral and equal to natural stone. Any environmental residues will not disturb any eco system. This makes them a valid alternative to plastics, preventing the release of micro plastics into our oceans.

Rope, twine and net for aquaculture and sea farming (e.g. mussels, seaweed and fish).
Natural fabrics for soil stabilization for marine and fluvial constructions.

https://www.basaltex.com/applications/technical-textiles/eco-marine-textiles
 

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BASALT REBAR – THE ULTIMATE STRUCTURAL COMPONENT

 

THE STRUCTURAL COMPONENT OF THE FUTURE

 

Basalt is the future, it is ready now and proven. Basalt rebars, basalt mesh, basalt chopped fibers and basalt rope twine are stronger than steel and will never rust or corrode. 

 

Basalt is much stronger and yet lighter and lasting many dozens of years longer than the structures of today that are considered by DOTs to be the “standard”.

 

The future is here, it is ready and proven and we can make sea walls and buildings safe and strong and long lasting.

 

Protects structures from the elements with advanced concretes such as geo-polymers which are 2-3 times stronger than CO2 producing Portland cement, while also being a greener and waterproof solution to many problems.

 

Basalt in geo-polymers is the strongest thing for construction. The use of traditional steel rebar has demonstrated that this “preferred” steel reinforcement can cause expensive maintenance, repair and replacement problems.

 

Reinforced concrete structures are facing serious degradation problems due to the corrosion of the steel rebar inside of the concrete structures. Reinforced concrete structures have to be able to support the load and its own weight. As such, the greater the total weight to be supported, the more rebar and concrete required.

 

The problems associated with steel rebar (corrosion, weight, etc.) are avoided with the use of basalt. This new alternative to steel rebar also wants to return to a straight state. Steel when bent, stays bent, and does not want to return to being straight like basalt. Build safe, build green, and build smarter because it makes monetary sense and keeps us alive and healthy.

https://diamondbasalt.com/

____________________________________

 

Magnetic Properties and Ferromagnetic Mineralogy of Oceanic Basalts

 

01 April 1993

https://academic.oup.com/gji/article/113/1/95/732980?login=false

____________________________________

 

Preliminary Characterization of Submarine Basalt Magnetic Mineralogy Using Amplitude-Dependence of Magnetic Susceptibility

 

30 January 2024

 
https://agupubs.onlinelibrary.wiley.com/doi/full/10.1029/2023GC011222
 

____________________________________

 

Electromagnetic properties of dry and water saturated basalt rock, 1-110 GHz

 

31 May 1998

https://ieeexplore.ieee.org/document/673669

____________________________________

 

Chapter 2. Magnetic Properties of Oceanic Basalts

 

1972

https://www.sciencedirect.com/science/article/abs/pii/S0422989408710857

____________________________________

 

On the magnetic and mineralogical properties of basalts

 

December 1967

https://link.springer.com/article/10.1007/BF00875312

____________________________________

 

Magnetic Recording Fidelity of Basalts Through 3D Nanotomography

 

07 March 2025

 
https://agupubs.onlinelibrary.wiley.com/doi/full/10.1029/2024GC011776

____________________________________

 

Some magnetic and electrical properties of basalt rocks

 

1990

https://www.sciencedirect.com/science/article/abs/pii/0167577X90900909

____________________________________

 

Effects of microwave radiation on dynamic compressive properties of basalt

 

2022 

https://www.sciencedirect.com/science/article/pii/S1003632622660278

____________________________________

 

Research on the mechanical properties and pore structure deterioration of Basalt-polyvinyl alcohol hybrid fiber concrete under the coupling effects of sulfate attack and freeze-thaw cycles

 

2025

https://www.sciencedirect.com/science/article/abs/pii/S0950061825010979

____________________________________

 

Magnetic anomalies and rock magnetism of basalts from Reykjanes (SW-Iceland)

 

12 February 2011

https://link.springer.com/article/10.1007/s11200-011-0007-4

____________________________________

 

Physicists May Have Discovered a New State of Matter – By Accident

 

February 28, 2020

 

The phenomenon appeared while the researchers were running experiments with crystalline materials that are only a few atoms thick, known as 2D materials. These materials are made up of a repeating pattern of atoms, like an endless checkerboard, and are so thin that the electrons in them can only move in two dimensions.  

 

Stacking these ultra-thin materials can create unusual effects as the layers interact at a quantum level. 

 

Kar and his colleagues were examining two such 2D materials, bismuth selenide and a transition metal dichalcogenide, layered on top of each other like sheets of paper. That’s when things started to get weird.

 

Electrons should repel one another—they’re negatively charged, and move away from other negatively charged things. But that’s not what the electrons in these layers were doing. They were forming a stationary pattern.

 

“At certain angles, these materials seem to form a way to share their electrons that ends up forming this geometrically periodic third lattice,” Kar says. “A perfectly repeatable array of pure electronic puddles that resides between the two layers.”

 

At first, Kar assumed the result was a mistake. The crystalline structures of 2D materials are too small to observe directly, so physicists use special microscopes that fire beams of electrons instead of light. As the electrons pass through the material, they interfere with each other and create a pattern. The specific pattern (and a bunch of math) can be used to recreate the shape of the 2D material.

https://scitechdaily.com/physicists-may-have-discovered-a-new-state-of-matter-by-accident/

____________________________________ 

 

 

Material of Interest: Magnesium-Zinc-Bismuth

 

https://tothestars.media/blogs/press-and-news/material-of-interest-magnesium-zinc-bismuth

____________________________________

 

The Bi-Mg (Bismuth-Magnesium) system

 

December 1985

https://link.springer.com/article/10.1007/BF02887150

____________________________________

 

Previous Analysis of TTSA Magnesium-Bismuth Material by Dr. William Mallow by Whitley Strieber

 

October 11, 2019

https://unknowncountry.com/insight/previous-analysis-of-ttsa-magnesium-bismuth-material-by-dr-william-mallow-by-whitley-strieber/

 

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Excellent room temperature deformability in high strain rate regimes of magnesium alloy

 

12 January 2018

 

Abstract

 

Magnesium and its alloys have the lowest density among structural metallic materials; thus, this light-weight metal has great potential for reducing the weight, for example, of vehicles and trains. However, due to its crystal structure, deformability is poor; in particular, under compressive stress. In this study, we modified magnesium with bismuth as an alloying element, which has the characteristics of being likely to form precipitates instead of grain boundary segregation. The Mg-Bi binary alloy showed excellent deformability and high absorption of energy in high-strain rate regimes at room temperature via contribution of grain boundary sliding. These properties, which are closely comparable to those of conventional middle-strength aluminum alloys (Al-Mg and Al-Mg-Si series alloys), have never been observed before in magnesium alloys. The development of such properties opens the door for not only academic but also industrial research in magnesium.

 
https://www.nature.com/articles/s41598-017-19124-w

 

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Puzzling Material Reveals Quantum Twist: Scientists Have Uncovered the True Nature of Bismuth

 

 June 1, 2025

 

https://scitechdaily.com/puzzling-material-reveals-quantum-twist-scientists-have-uncovered-the-true-nature-of-bismuth/ 

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Protein and metal give mussels their muscle

 

March 4, 2010

 

The tough, stretchy threads that fix mussels to seashore rocks are made up of a combination of sticky proteins and tough metal ions, researchers have found. 

 

Engineers in Germany and the U.S. are investigating the remarkable properties of the mussel threads, called the byssus or beard, in the hopes of recreating them in a lab.

 

The threads can stretch to twice their normal length, and also resist the constant scraping and tearing from sand particles suspended in crashing ocean waves.

 

"Nature has evolved an elegant solution to a problem that engineers are still struggling with; namely, how to combine the properties of abrasion resistance and high extensibility in the same material," said Peter Fratzl, of the Max Planck Institute for Colloids and Interfaces, in a statement.

 

The researchers used a process called Raman microscopy to probe the chemical makeup of the threads, which the mussels squeeze out like spaghetti through a pasta maker.

 

They found that the outer layers of the byssal threads were made of an amino acid called dopa, a strong adhesive that gives the threads their stickiness and stretchiness.

 

There's also a high concentration of iron ions in the threads, giving them their toughness. The proteins and metal ions form a chemical complex, and their connections vary at different points on the thread.

 

At some points, the metals and proteins are strongly cross-linked, making the thread resistant to ocean waves and sand. At other points there are fewer cross-links, allowing the threads to stretch.

 

As well, when the thread stretches, tiny tears form in the protein-metal chemical complex, which prevents larger tears from forming and breaking the thread. The small tears can repair themselves when the chemical bonds reform.

 

The researchers said figuring out the chemical properties of mussel beard threads could allow engineers to replicate those properties in synthetic materials.

 

"Protective coatings are important for prolonging the lifetime of materials and devices. However, considering that hardness and extensibility are seldom coupled in engineered polymers or composites, understanding how one protects a flexible substrate becomes quite important," said Matthew Harrington of the Max Planck Institute.

 

Researchers from the University of California, Santa Barbara and the University of Chicago also took part in the research, published this week in Science.

 

https://physicsworld.com/a/mussels-mix-proteins-and-metals-to-create-sticky-threads/

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Defying 60 Years of Physics – “Strange Metals” Break the Rules of Electricity

 

April 26, 2025

 

https://scitechdaily.com/defying-60-years-of-physics-strange-metals-break-the-rules-of-electricity/ 

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AARO Releases Lab Report on Alleged Alien Metamaterial

 

Jul 11, 2024 

https://www.metabunk.org/threads/aaro-releases-lab-report-on-alleged-alien-metamaterial.13548/

 

____________________________________

 

Non-Equilibrium Crystallization of Monotectic Zn-25%Bi Alloy under 600 g

 

2021

https://pmc.ncbi.nlm.nih.gov/articles/PMC8347316/

____________________________________

 

Effect of bismuth on microstructure, mechanical properties and fracture behavior of AZ magnesium alloys

 

2022

https://www.sciencedirect.com/science/article/abs/pii/S0921509322010607

____________________________________

 

Outstanding Strength: Next-Gen Copper Alloy Pushes Past Limits of Traditional Materials

 

April 12, 2025

 

The strongest Cu-Ta-Li alloy developed to date exhibits outstanding strength and stability, making it ideal for advanced engineering applications.

 

A team of researchers from Arizona State University, the U.S. Army Research Laboratory (ARL), Lehigh University, and Louisiana State University has developed a groundbreaking high-temperature copper alloy with outstanding thermal stability and mechanical strength.

 

Their study, published in the journal Science, presents a novel bulk nanocrystalline alloy, Cu-3Ta-0.5Li, that demonstrates exceptional resistance to grain coarsening and creep deformation, even at temperatures approaching its melting point.

 

“Our alloy design approach mimics the strengthening mechanisms found in Ni-based superalloys,” said Kiran Solanki, a professor at the Ira A. Fulton Schools of Engineering in the School for Engineering of Matter, Transport and Energy, and a co-author of the study.

 

Nickel-based superalloys are currently the primary materials used in applications that demand exceptional strength, corrosion resistance, and stability at high temperatures. These alloys are essential in critical industries such as aerospace, gas turbine engines, and chemical processing.

https://scitechdaily.com/outstanding-strength-next-gen-copper-alloy-pushes-past-limits-of-traditional-materials/

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Ground-Breaking Discovery Could Create Superior Alloys

 

June 19, 2018

 

Developing alloys that can withstand high temperatures without corroding is a key challenge for many fields, such as renewable and sustainable energy technologies like concentrated solar power and solid oxide fuel cells, as well as aviation, materials processing and petrochemistry.

 

At high temperatures, alloys can react violently with their environment, quickly causing the materials to fail by corrosion. To protect against this, all high-temperature alloys are designed to form a protective oxide scale, usually consisting of aluminum oxide or chromium oxide. This oxide scale plays a decisive role in preventing the metals from corroding. Therefore, research on high-temperature corrosion is very focused on these oxide scales – how they are formed, how they perform at high heat, and how they sometimes fail.

 

The article in Nature Materials answers two classical issues in the area. One applies to the very small additives of so-called ‘reactive elements’ – often yttrium and zirconium – found in all high-temperature alloys. The second issue is about the role of water vapor.

 

“Adding reactive elements to alloys results in a huge improvement in performance – but no one has been able to provide robust experimental proof why,” says Nooshin Mortazavi, materials researcher at Chalmers’ Department of Physics, and first author of the study. “Likewise, the role of water, which is always present in high-temperature environments, in the form of steam, has been little understood. Our paper will help solve these enigmas.”

 

In this paper, the Chalmers researchers show how these two elements are linked. They demonstrate how the reactive elements in the alloy promote the growth of an aluminum oxide scale. The presence of these reactive element particles causes the oxide scale to grow inward, rather than outward, thereby facilitating the transport of water from the environment, toward the alloy substrate. Reactive elements and water combine to create a fast-growing, nanocrystalline, oxide scale.

 

“This paper challenges several accepted ‘truths’ in the science of high-temperature corrosion and opens up exciting new avenues of research and alloy development,” says Lars Gunnar Johansson, Professor of Inorganic Chemistry at Chalmers, Director of the Competence Centre for High Temperature Corrosion (HTC) and co-author of the paper.

 

https://scitechdaily.com/ground-breaking-discovery-could-create-superior-alloys/

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Recovery of ancient Greek shipwreck in Sicily reveals rare orichalcum, the fabled ‘Atlantis metal’

 

October 7, 2024

 

Off the coast of Sicily, near the ancient city of Gela, recovery operations are underway for the 5th-century BCE Greek shipwreck, “Gela II.” The wreck, discovered in 1980 by divers near Bulala, is a vital historical find that has yielded numerous treasures, most notably orichalcum, a metal alloy with connections to the legendary city of Atlantis. 

 

The Gela II wreck, which lies about 1,000 feet underwater, is remarkably well-preserved. Underwater archaeologists first investigated the site in the 1990s, but it was in 2015 and 2017 that significant discoveries were made. Over these two expeditions, 86 ingots of orichalcum were recovered from the seabed.

 

Orichalcum, derived from the Greek word “oreikhalkos” meaning “mountain copper,” has long been a subject of fascination. Classical sources like Plato’s Critias describe orichalcum as a highly valuable metal, second only to gold. In the mythical city of Atlantis, orichalcum was said to cover the walls of the Temple of Poseidon and Cleito, giving them a red gleam. While there has been much debate over the metal’s composition, modern analysis of the ingots from Gela II reveals that they are an alloy composed of 75-80% copper and 14-20% zinc, with traces of nickel, lead, and iron.

 

According to Sebastiano Tusa, former superintendent of Sicily’s Sea Office, the ingots recovered from the shipwreck likely originated from Greece or Asia Minor. “The discovery of orichalcum ingots is significant because nothing similar has ever been found,” Tusa noted. “We knew of orichalcum from ancient texts and a few ornamental objects, but these ingots are unprecedented.”

 

Gela II, measuring approximately 50 feet long and 16 feet wide, was a merchant vessel that would have transported goods across the Mediterranean. In addition to the orichalcum ingots, archaeologists have uncovered Corinthian helmets, amphorae, pottery, and personal belongings of the crew.

 

 https://archaeologymag.com/2024/10/recovery-of-greek-shipwreck-in-sicily-reveals-orichalcum/

 

____________________________________

 

Orichalcum

https://en.wikipedia.org/wiki/Orichalcum

 

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Natural fiber composite wheelchair seat design aims for sustainable mobility

06/11/2021

https://www.compositesworld.com/news/natural-fiber-composite-wheelchair-seat-design-aims-for-sustainable-mobility

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Greenboats, Sicomin and Bcomp selected as JEC Innovation Awards 2021 finalists

05/19/2021

Project partners nominated for an offshore nacelle manufactured with natural fiber composites, with a construction that saves approximately 60% CO2 equivalent and introduced viable options for the end of the nacelles’ life.

https://www.compositesworld.com/news/greenboats-sicomin-and-bcomp-selected-as-jec-innovation-awards-2021-finalists

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Bcomp, Siux bring natural fiber composites to padel tennis

04/30/2025

Flax fibers enter the court through Siux’s GEA padel racquets, delivering high-performance, well-balance sports equipment to a rapidly growing sports market.

https://www.compositesworld.com/news/bcomp-siux-bring-natural-fiber-composites-to-padel-tennis

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Easy Composites appointed as exclusive U.K. distributor of Eco-Technilin natural fiber reinforcements

05/04/2021

Eco-Technilin natural fiber product range offers woven, nonwoven, UD and prepreg reinforcement options that are more sustainable, affordable alternatives to traditional reinforcements like glass fiber.

https://www.compositesworld.com/news/easy-composites-appointed-as-exclusive-uk-distributor-of-eco-technilin-natural-fiber-reinforcements

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Study demonstrates improved abrasion resistance using TFP aramid nonwovens

04/14/2021

Study shows aramid veil acts as a sacrificial layer to protect the underlying reinforcement, improves durability and extends composite structure lifespan.

https://www.compositesworld.com/news/study-demonstrates-improved-abrasion-resistance-using-tfp-aramid-nonwovens

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RAMPF offers lightweight construction with high-performance epoxy board and liquid materials

04/09/2021

Raku Tool epoxy boards, gelcoats, laminating resins and infusion and RTM systems offered, with encompassing technical support.

https://www.compositesworld.com/news/rampf-offers-lightweight-construction-with-high-performance-epoxy-board-and-liquid-materials

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AIMPLAS develops pultruded bio-based profiles for rural and urban development

03/29/2021

European BASAJAUN project to optimize sustainable urban development and improve the rural economy via novel bio-based materials, products and building systems.

https://www.compositesworld.com/news/aimplas-develops-pultruded-bio-based-profiles-for-rural-and-urban-development

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Composites for structural batteries

03/26/2021

Researchers in Sweden find carbon fiber composites can be used for creating structural batteries that could help minimize mass in EVs and consumer electronics.

https://www.compositesworld.com/news/composites-for-structural-batteries

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Covestro Desmocomp resin offers facade elements efficient thermal insulation

02/17/2021

Construction equipment suppliers opt for composites to develop a facade fastening system that is more UV-resistant, sustainable and lightweight than aluminum elements.

https://www.compositesworld.com/news/covestro-desmocomp-resin-offers-facade-elements-efficient-thermal-insulation

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Sicomin-sponsored solo kayak crossing takes advantage of composites

01/27/2021

Incorporation of Sicomin carbon fiber and PVC foam sandwich construction ensures an efficient kayak for extreme paddler Richard Kohler’s 6,700-kilometer journey across the South Atlantic.

https://www.compositesworld.com/news/sicomin-sponsored-solo-kayak-crossing-takes-advantage-of-composites

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Additional funding launches UMaine Forest Bioproducts Technology Maturation Program

01/24/2025

Twenty-two million in funding by the NDAA accelerates Maine’s R&D support of natural polymers and other wood fiber bio-products for startups and established companies.

https://www.compositesworld.com/news/additional-funding-launches-umaine-forest-bioproducts-technology-maturation-program

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University of Maine unveils 100% bio-based 3D-printed home

11/23/2022

BioHome3D, made of wood fibers and bioresins and entirely 3D printed, highlights Maine’s effort to address the need for more affordable housing.

https://www.compositesworld.com/news/university-of-maine-unveils-100-bio-based-3d-printed-home

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He 3D Printed a Whole House

May 14, 2025

https://www.youtube.com/shorts/S6ci52yKAxA


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Novel 3D Printing Method a ‘Game Changer’ for Discovery, Manufacturing of New Materials

July 6, 2023


https://www.aau.edu/research-scholarship/featured-research-topics/novel-3d-printing-method-game-changer-discovery

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Bcomp, Temca achieve intricate composite cladding for French school façade

12/05/2024

A combination of flax and glass fibers went into the development of 880 openwork, shade-providing panels for an international school in France.

https://www.compositesworld.com/news/bcomp-tema-achieve-intricate-composite-cladding-for-french-school-facade

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DITF, Fiber Engineering highlight biodegradable natural fiber plant pot project

10/28/2024

Materials and fabrication process R&D achieves low-cost, compostable plant pots made from invasive hyacinth fibers and a thermoplastic matrix processed via hot press.

Together with Fiber Engineering GmbH (Karlsruhe, Germany), the German Institutes of Textile and Fiber Research Denkendorf (DITF) presents a process for the production of plant pots that are fabricated from a natural fiber-reinforced thermoplastic that has proven to be fully biodegradable. 

Controlling the spread of water hyacinth, an invasive species that now exists in water ecosystems across many countries, was the starting points for this research co-led by the DITF, which aims to produce a cost-effective composite material from the fibrous plant material’s biomass. The result is a prototype plant pot that is competitive and meets all the technical requirements of the project objectives.

https://www.compositesworld.com/news/ditf-fiber-engineering-highlight-biodegradable-natural-fiber-plant-pot-project

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Henry Royce Institute uses FET system for trials on more sustainable fibers from wood pulp

11/23/2022

Fibre Extrusion Technology wet spinning system selected for sustainable, advanced materials research in the U.K.

https://www.compositesworld.com/news/henry-royce-institute-uses-fet-system-for-trials-on-more-sustainable-fibers-from-wood-pulp

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Bio-Sep propels sustainable composites development via forestry-produced biochemicals

11/14/2022

Joint industry project with iCAST, NCC and University of Bath to produce and test bio-based composites from cellulose and lignin sawdust, replace fossil-derived ingredients.

https://www.compositesworld.com/news/bio-sep-propels-sustainable-composites-development-via-forestry-produced-biochemicals

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Helicoid Industries releases three use cases of Helicoid technology

11/11/2022

Use case applications with Helicoid technology implementation demonstrated mechanical performance improvements, such as impact resistance and strength.

https://www.compositesworld.com/news/helicoid-industries-releases-three-use-cases-of-helicoid-technology

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Heartland completes first industrial hemp fiber life cycle assessment

11/11/2022

Life cycle assessment (LCA) studies Heartland’s Imperium Filler natural fiber additive as a carbon-negative replacement for mineral fillers commonly used in plastics.  

https://www.compositesworld.com/news/heartland-completes-first-industrial-hemp-fiber-life-cycle-assessment

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Business incubator Chemovator invests in Heartland’s natural fiber additives

05/03/2024

The Michigan company, producing hemp-based natural fiber materials, is the latest addition to Chemovator’s program supporting early stage startups in the chemical industry.

https://www.compositesworld.com/news/business-incubator-chemovator-invests-in-heartlands-natural-fiber-additives

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Kordsa to work with Bpreg to expand biocomposite capabilities

01/22/2024

Kordsa concludes significant investment aimed at further enhancing its expertise in composites technologies, including development and distribution of more sustainable fiber options to customers.

Kordsa (Izmut, Turkey), a subsidiary of Sabancı Holding, announces its investment in Bpreg Composites (Nilüfer/Bursa, Turkey), a company that has specialized in industrial biocomposites using organic fibers since 2017. Kordsa aims to extend its expertise in composites technologies, particularly regarding sustainability, by offering environmentally friendly alternatives to its customers.

Kordsa told CW that it is currently focused on the use of flax and hemp fibers. “Bpreg was approved for use of hemp seeds and studies are ongoing,” Kordsa says. “Flax fiber reinforcements are also promising.”

Kordsa anticipates that its contribution will grow the company while opening up opportunities for knowledge and technology sharing domestically and internationally — Kordsa production facilities, capable of hosting Bpreg’s mass production processes, will enable the global offering of Bpreg’s product portfolio to Kordsa customers in various parts of the world.

Bpreg biocomposite solutions span different sectors such as automotive, mobility, marine vehicles, aviation, sports equipment and consumer products. The company combines products obtained from organic fibers with different polymers through a patented production technique, resulting in high-performance, sustainable and industrially user-friendly composite materials. The biocomposite materials to be produced through the Bpreg and Kordsa collaboration will also promise a natural appearance, making them suitable for aesthetic applications on external surfaces.

https://www.compositesworld.com/news/kordsa-to-work-with-bpreg-to-expand-biocomposite-capabilities

 

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Scientists achieve universal technique—called van der Waals squeezing—for atomic manufacturing of 2D metals

March 12, 2025

https://phys.org/news/2025-03-scientists-universal-technique-van-der.html

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TNO research offers circularity solution for discarded wind turbine blades

10/21/2022

Thermochemical method involving pyrolysis extracts fibers, which can then be reprocessed as thermoplastic composites for various recyclable products.

https://www.compositesworld.com/news/tno-research-offers-circularity-solution-for-discarded-wind-turbine-blades

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Delta, Joby Aviation partner to deliver sustainable home-to-airport transportation

10/14/2022

Sixty-million upfront equity investment will integrate Joby-operated eVTOL services into Delta customer-facing channels, beginning in New York and Los Angeles. 

https://www.compositesworld.com/news/delta-joby-aviation-partner-to-deliver-sustainable-home-to-airport-transportation

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Forvia brand Faurecia exhibits XL CGH2 tank, cryogenic LH2 storage solution for heavy-duty trucks

10/14/2022

Part of its full hydrogen solutions portfolio at IAA Transportation 2022, Faurecia also highlighted sustainable thermoplastic tanks and smart tanks for better safety via structural integrity monitoring.

https://www.compositesworld.com/news/forvia-brand-faurecia-exhibits-xl-cgh2-tank-cryogenic-lh2-storage-solution-for-heavy-duty-trucks

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Meringue-like material could make aircraft as quiet as a hairdryer

 

18 June 2021

 

Extremely low-density graphene-based aerogel ‘meringue’ can improve passenger comfort and reduce noise up to 80%

 

https://www.bath.ac.uk/announcements/meringue-like-material-could-make-aircraft-as-quiet-as-a-hairdryer/

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BlueWind partners with Greener to strengthen sustainability profile

09/06/2023

Greener, a Brazilian company that promotes the trade of carbon credits, will consult and coordinate BlueWind’s inventory assessment and analyze how to further offset the composites manufacturer’s carbon footprint.

https://www.compositesworld.com/news/bluewind-partners-with-greener-to-strengthen-sustainability-profile

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Toray boosts stake in Thai subsidiary to upgrade cellulosic sugar production

09/05/2023

Its work to produce bio-based fibers, resins and films will be augmented through a 84.4% stake and a larger facility to enable commercial production of 100,000 metric tons of cellulosic sugar annually by 2030.

https://www.compositesworld.com/news/toray-boosts-stake-in-thai-subsidiary-to-upgrade-cellulosic-sugar-production

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BioPowder expands capabilities with Gebrüder Dorfner partnership

06/30/2023

Paints, coatings and composites markets will gain access to high-performance renewable additives.

BioPowder (Birkikara, Malta), a responsible producer and supplier of high-grade fruit stone powders and bio-based abrasives, has formed a strategic alliance with Gebrüder Dorfner GmbH & Co. Kaolin- und Kristallquarzsand-Werke KG (Dorfner, Hirschau, Germany), an expert in the refinement and application of minerals and filler systems. The partnership combines BioPowder’s core competency in sustainable plant-based additives — which can be used in composites, coatings and more — with Dorfner’s expertise in application engineering, creating product development opportunities and unlocking new areas of research.

https://www.compositesworld.com/news/biopowder-expands-capabilities-with-gebruder-dorfner-partnership

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AMRC fiber handling expertise aids CMC coating technology

05/15/2023

The CICSiC project successfully developed equipment and processing know-how associated with the uniform, continuous coating of SiC-based CMC, to bring down cost, and improve performance and reliability for new designs, applications.

https://www.compositesworld.com/news/amrc-fiber-handling-expertise-aids-cmc-coating-technology

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Aerospace project secures funds for developing lightweighting technology

05/08/2023

A joint project between ÉireComposites, Plasma Bound and TU Dublin will be supported by the DTIF.

ÉireComposites (Galway, Ireland), Plasma Bound (Dublin, Ireland) and Technological University Dublin (TU Dublin, Dublin, Ireland) have obtained funding for the Ad Astra project. The work will be supported under the Disruptive Technologies Innovation Fund (DTIF) Call 5, which is led by the government of Ireland and Enterprise Ireland.

Lightweight composite materials’ strength-to-weight ratio versus metal alloys provides reduced weight and increased fuel efficiency, but rapid, cost-effective bonding of these materials can be challenging. Effective surface preparation is a prerequisite for achieving a strong, durable bond, but current surface preparation techniques can be highly labor intensive, increasing process costs...

https://www.compositesworld.com/news/aerospace-project-secures-funds-for-developing-light-weighting-technology

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SHD, Lineat signs terms for sustainable carbon fiber composites

05/01/2023

Alignment of “recycled” and waste carbon fiber material via a patented manufacturing technology process will encourage more sustainable, circular composite materials development.

https://www.compositesworld.com/news/shd-lineat-signs-terms-for-sustainable-carbon-fiber-composites

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'In-insect synthesis': Caterpillar factories produce fluorescent nanocarbons

 

June 5, 2025

 

 

Tobacco cutworm caterpillars can convert [6]MCPP to [6]MCPP-oxylene far more effectively than laboratory settings. 

 

Researchers led by Kenichiro Itami at the RIKEN Pioneering Research Institute (PRI) / RIKEN Center for Sustainable Resource Science (CSRS) have successfully used insects as mini molecule-making factories, marking a breakthrough in chemical engineering. 

https://phys.org/news/2025-06-insect-synthesis-caterpillar-factories-fluorescent.html

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Collaboration between NCC, UKAEA to develop fusion-grade SiC/SiC composites

04/30/2023

High-volume composites development for future fusion power reactors under HASTE-F program accelerates U.K.’s net-zero energy generation, drives transformation in industries that use high-temperature CMCs.

https://www.compositesworld.com/news/collaboration-between-ncc-ukaea-to-develop-fusion-grade-sicsic-composites

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Quantum composites research opens new avenues in energy storage, electronic applications

03/29/2023

A new type of composite material studied by the University of California, Riverside features unique properties defined by quantum condensate effects, presenting new approaches to materials engineering and utilization.

https://www.compositesworld.com/news/quantum-composites-research-opens-new-avenues-in-energy-storage-electronic-applications

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Anmet launches chipboard panels made from recycled composites

03/14/2023

Starting from university R&D collaborations, the Polish recycling company has patented a shredding and manufacturing process for wood-replacement chipboards for use by the construction industry.

https://www.compositesworld.com/news/anmet-launches-chipboard-panels-made-from-recycled-composites

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Post Cure: Natural mineral fiber biocomposite via AFP enhances implant integration

10/04/2024

Arctic Biomaterials produces high-quality composite biomaterials incorporating a natural mineral fiber that is useful in medical and healthcare-related fields.

https://www.compositesworld.com/articles/post-cure-natural-mineral-fiber-biocomposite-via-afp-enhances-implant-integration

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Belzona composite wrap restores corroded carbon steel pipeline

08/08/2024

Two-part epoxy paste, epoxy structural adhesive, composite wrap and anti-corrosion coating prevent environmental and economic loss for customer.

https://www.compositesworld.com/news/belzona-composite-wrap-restores-corroded-carbon-steel-pipeline

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Fraunhofer EMI develops local pyrolysis method to reclaim continuous carbon fiber

04/18/2025

High-power laser is used for controlled “unwinding” of thermoset composites without damaging the fibers or adversely affecting their mechanical properties, making it highly useful for recycling wound structures.

https://www.compositesworld.com/news/fraunhofer-emi-develops-local-pyrolysis-method-to-reclaim-continuous-carbon-fiber

 

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Apply Carbon announces investments, milestones for carbon fiber and aramid recyclability

02/12/2025

Financial investments, R&D facility inauguration and an operational solar power plant expands the French company’s product developments, operational recycling capacity and reduce its CO2 footprint.

https://www.compositesworld.com/news/apply-carbon-announces-investments-milestones-for-carbon-fiber-aramid-recyclability-

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Fujitsu, Teijin start joint trials to promote value of recycled carbon fiber

01/20/2023

Three-month trials with German bicycle manufacturers will lead to new platform implementation to promote use of recycled materials, enable emissions tracing/management.  

https://www.compositesworld.com/news/fujitsu-teijin-start-joint-trials-to-promote-value-of-recycled-carbon-fiber

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Hot acetic acid enables full recycling of carbon fiber composite materials

June 26, 2025

 

https://advancedcarbonscouncil.org/blogpost/2151389/511931/Hot-acetic-acid-enables-full-recycling-of-carbon-fiber-composite-materials 

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Teijin carbon fiber-reinforced thermoplastics qualified for aerospace applications

10/13/2020

Collins Aerospace deemed Teijin Ltd.’s Tenax thermoplastic woven fabric and consolidated laminate materials suitable for large-scale production of structural components

https://www.compositesworld.com/news/teijin-carbon-fiber-reinforced-thermoplastics-qualified-for-aerospace-applications

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Research shows feasting fungi could shake up carbon fiber recycling

12/20/2024

Recovered benzoic acid from CFRP matrix breakdown can be “consumed” by genetically modified fungi, enabling high-value reclamation of both the fiber and the matrix.

https://www.compositesworld.com/news/research-shows-feasting-fungi-could-shake-up-carbon-fiber-recycling

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EuReComp announces 3rd Workshop on sustainable composites recycling

02/12/2025

Keynotes, hands-on demonstrations and engaging discussions into composites circularity will take place on March 19, 2025 in Athens, Greece.

https://www.compositesworld.com/news/eurecomp-announces-3rd-workshop-on-sustainable-composites-recycling

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Magnetic nanoparticles show promise for thermosets recycling

05/22/2024

Aitiip and the University of Slovenia have collaborated to develop, test and prove how smart magnetic nanoparticles can produce a controlled decomposition of the resin for recycling.

https://www.compositesworld.com/news/magnetic-nanoparticles-show-promise-for-thermosets-recycling

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ORNL, Sierra Space create novel C/SiC TPS for reusable space vehicles

11/18/2024

CMC tiles will be used on the Sierra Space DC100 Dream Chaser spaceplane carrying critical supplies and science experiments to and from NASA’s ISS.

https://www.compositesworld.com/news/ornl-sierra-space-create-novel-csic-tps-for-reusable-space-vehicles

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ESA Project SHIELD advances reusable spacecraft

06/26/2025

Four category focuses were announced, including one focused on durable, modular and cost‑efficient TPS to be contributed to by Arceon composites.

https://www.compositesworld.com/news/esa-project-shield-advances-reusable-spacecraft

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SUSPENS project shares one-year progress, next steps

02/23/2024

European project dedicated its first year to sustainable materials development and prototype manufacture, looks to validating performance.

https://www.compositesworld.com/news/suspens-project-shares-one-year-progress-next-steps

 

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Rice paper

 

Rice paper is a product constructed of paper-like materials made from different plants. These include: 

 

• Thin peeled dried pith of Tetrapanax papyrifer: A sheet-like "paper" material was used extensively in late 19th century Guangdong, China as a common support medium for gouache paintings sold to Western clients of the era. The term was first defined in the Chinese–English Dictionary of Robert Morrison who referred to the use of the Chinese medicinal plant as material for painting, as well as for making artificial flowers and shoe soles.^[1] 
• Xuan paper made from paper mulberry: The traditional paper which originated in ancient China and it has been used for centuries in China, Japan, Korea, and Vietnam for writing, artwork, and architecture.

Dried starch sheets of various thickness or texture: These edible paper sheets have some properties of pulp paper and can be made from rice starch. They are known as bánh tráng, used in Vietnamese cuisine.

 

Mulberry paper

 

This "rice paper", smooth, thin, crackly, and strong, is named as a wrapper for rice, and is made from bark fibres of the paper mulberry tree. It is used for origami, calligraphy, paper screens and clothing. It is stronger than commercially made wood-pulp paper. Less commonly, the paper is made from rice straw. 

 

Depending on the type of mulberry used, it is named kozo (Broussonetia papyrifera, the paper mulberry), gampi (Wikstroemia diplomorpha), or mitsumata (Edgeworthia chrysantha). The fiber comes from the bark of the paper mulberry, not the inner wood or pith, and traditionally the paper is made by hand. 

 

The branches of the paper mulberry shrubs are harvested in the autumn, so the fibre can be processed and the paper formed during the cold winter months, because the fibre spoils easily in the heat. The branches are cut into sections two to three feet long and steamed in a large kettle, which makes the bark shrink back from the inner wood, allowing it to be pulled off like a banana peel. The bark can then be dried and stored, or used immediately. There are three layers to the bark at this stage: black bark, the outermost layer; green bark, the middle layer; and white bark, the innermost layer. All three can be made into paper, but the finest paper is made of white bark only. 

 

If the bark strips have been dried, they are soaked in water overnight before being processed further. To clean the black and green bark from the white bark, the bark strip is spread on a board and scraped with a flat knife. Any knots or tough spots in the fibre are cut out and discarded at this stage. 

 

The scraped bark strips are then cooked for two or three hours in a mixture of water and soda ash. The fibre is cooked enough when it can easily be pulled apart lengthwise. The strips are then rinsed several times in clean water to rinse off the soda ash. Rinsing also makes the fibre brighter and whiter—fine kozo paper is not bleached, but is naturally pure white. 

 

Each bark strip is then inspected by hand, against a white background or lit from behind by a light box. Any tiny pieces of black bark and other debris are removed with tweezers, and any knots or tough patches of fibre missed during scraping are cut out of the strips. The ultimate goal is to have completely pure white bark. 

 

The scraped, cooked, and cleaned strips are then laid out on a table and beaten by hand. The beating tool is a wooden bat that looks like a thicker version of a cricket bat. The fibres are beaten for about half an hour, or until all the fibres have been separated and no longer resemble strips of bark. 

 

The prepared fibre can now be made into sheets of paper. A viscous substance called formation aid is added to the vat with the fibre and water. Formation aid is polyethylene oxide, and it helps slow the flow of water, which gives the paper-maker more time to form sheets. Sheets are formed with multiple thin layers of fibre, one on top of another.

https://en.wikipedia.org/wiki/Rice_paper

 

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All About Mulberry Paper and How to Use It

11/13/19

 

Mulberry paper is a form of handmade paper. It is made from the mulberry tree and it has long fibers which help to give the paper its distinctive finish. These fibers also give mulberry paper a fine wispy edge when it is torn and this makes a very attractive finish. Mulberry paper is typically textured and is available in a variety of weights. Because mulberry paper is handmade, no two pieces are ever quite the same. 

 

Uses

 

Mulberry paper is ideal for rubber stamping projects. While the surface of the paper is textured and therefore makes it difficult to stamp directly onto, the mulberry paper makes a wonderful background for layered projects. It is great for handmade cards and also makes an interesting addition to a scrapbook project. Not all mulberry paper is acid-free, therefore if you require the paper for a special or archival project, it is best to check with the supplier before purchasing paper.

 
https://www.thesprucecrafts.com/mulberry-paper-2905868

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Discovering the Magic of Mulberry Paper: Origins, Production, and Creative Uses

 

Sep 02, 2023

https://kozo.studio/blogs/journal/discovering-the-magic-of-mulberry-paper-origins-production-and-creative-uses

 

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Know Your Treeless Paper Alternatives In 2023

 

March 2023

 

Is it even the same as normal paper?

 

One of the most important reasons to find tree less pieces of paper is that it takes a lot of time to grow, and we cannot simply go on cutting down trees because of our paper needs.

 

 So by exploring tree-less eco-friendly paper made from a variety of sources such as hemp, mulberry, bamboo or even stone you can find out for yourself if they are any different from regular paper. These papers may or may not look too far from the regular paper, but can also have a unique appearance, bringing a certain character like that of mulberry paper or linen paper to your stationery and craft projects.

 

For that matter, a lot of tree-less paper is manufactured as high quality paper products that are suitable to be used for all your craft projects and personalized  stationery for printing.

 

You may know that there are many kinds of tree-less alternatives to try from, such as hemp, mulberry, elephant feces or paper made from plant eating animals. Your cotton  fabrics, agricultural by-products and your consumer paper waste can all contribute to making tree less paper. We would love to hear about your experience with paper that is made from anything other than trees. Tell us in the comments below, have you tried any eco-friendly tree-less paper?

 

https://thunderboltpaper.com/blogs/news/know-your-treeless-paper-alternatives-in-2022

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It’s paper, but not as we know it!

 

03/10/2018

 

Post-Consumer Waste
This is perhaps the most common alternative to virgin paper.  This type of paper is made from a high percentage of post-consumer waste – those paper items that we have thrown into the recycling bin.  Buying stationery made from post-consumer waste ticks a number of environmental boxes by reducing the number of trees used, it keeps paper out of landfills and it also saves energy too!

 

Kenaf
This is similar to the cotton plant and uses 15-25% less energy than pine to make pulp.

 

Bamboo
This fast-growing grass produces 4 to 5 times the fibre of the fastest-growing commercial tree species and is becoming increasingly popular for paper, and clothing products too.

 

Agri-Pulp
This alternative source uses agricultural waste, along with post-consumer waste to make paper.

 

Cotton
Organically grown cotton, grown in several colors, including green, brown, and white is another popular alternative.

 

Eco-Friendly Paper Products – Paper, without trees, really?

 

There is a wide variety of alternative ‘fibres’ that can work as an alternative to wood-pulp paper. Sources for tree-free paper include:^[1]

 

• agricultural residues – for example, sugar cane bagasse, husks and straw.
• fibre crops and wild plants – such as bamboo, kenaf, hemp, jute, and flax.
• textiles and cordage wastes.

 

There are also non-fibre sources, such as:

 

• calcium carbonate bound by a high-density, non-toxic polyethylene resin.

 

A closer look

 

Cotton Paper
Made using cotton liners or cotton from used cloth as the primary material, cotton paper is used as an alternative to wood paper for printing documents. Cotton paper is superior in both strength and durability, compared to wood pulp-based.

 

Given its durability, and known to last hundreds of years without appreciable fading, discoloration, or deterioration, it is often used for archival copies of dissertations or theses, legal documents, etc.

 

Interestingly, it is used for banknotes in a number of countries.

 

Paper from Sugarcane
Bagasse is the residue left after the sugar cane is crushed in the sugar factories for juice extraction. It contains about 45% cellulose, 28% pentosans, 20% lignin, 5% sugar, and 2% minerals and its high- cellulose content makes it viable as a fibrous raw material in the paper industry.

 

Recently, paper experts have agreed that bagasse, after proper depithing process, is an ideal raw material for manufacturing different kinds of paper, newsprint etc.

 

The uses of bagasse in paper-making are extensive. The physical properties of the pulp mean that it is suited for generic printing papers, as well as tissue products. It is widely used for boxes and newspaper production and is also used for making boards like particle boards.  It is often considered as a good substitute for plywood.

 

Turning wheat into paper
Most of the mills that produce paper from wheat and other agricultural waste products are located in India, China, and other eastern hemisphere countries.

 

Kenaf is also grown in the southeastern United States, solely for its pulp, and it is promoted by many paper suppliers in the USA.

 

Rock – Paper – Scissors!

 

Stone paper is manufactured using calcium carbonate, bonded with high-density polyethylene (HDPE).  It’s used for stationery, leaflets, posters, books, magazines, bags, packaging, alongside many other uses.

 

Whilst it is not biodegradable, stone is photo-degradable and compostable.  It can also be recycled into rich mineral paper again.

 

Given that it does not collect static charge, is acid-free with a neutral pH, has no grain, is water, grease, and insect resistant; stone paper is a specialist paper product.

 

PG paper specialises in sourcing and delivering your paper needs with ease and comfort, wherever you are in the world.

 
https://www.pgpaper.com/eco-friendly-paper-products/

 

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FiberStone | Creating Eco-Friendly Paper

 

How Fiberstone® Paper is Made

 

FiberStone® Natural Stone Paper, also known as “stone paper” or “rock paper,” is made from 80% Calcium Carbonate (CaCO) with a small quantity (20%) of non-toxic resin (HDPE- High Density Polyethylene). The Calcium Carbonate in the stone paper comes from limestone collected as waste material from existing quarries for the building and construction industry. It is ground down to a fine powder like chalk and the HDPE acts as a binder for the Calcium Carbonate. So amazingly, 80% of this new paper replacement product is from recycled, reused materials and it’s using no trees, no water, and doesn’t even emit toxic air!

 

Together these materials create a tough, durable, tear resistant paper that is also a water proof/grease proof paper! Waterproofing paper normally requires a film; now imagine, a soft, smooth, bright white paper that performs like a film but without all the petroleum! It is chlorine free, bleach (commonly used in paper products) free, acid free and totally safe for the environment.

https://ethosolutions.org/fiberstone-creating-eco-friendly-paper/

 

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Tree-free paper

 

Tree-free paper, also known as no tree paper, offers an alternative to traditional wood-pulp paper^[1] due to its unique raw material^[2] composition. This type of paper is considered more eco-friendly especially when evaluating its entire life cycle. 

 

Sources of fiber for tree-free paper

 

Tree-free paper fibers are derived from various sources: 

 

• Agricultural residues: These include sugarcane bagasse, husks and straw
• Fiber crops and wild plants: Common sources are bamboo, kenaf, hemp,^[6]Coir,^[7][8] jute, coffee husk, corn husk, lemongrass, rice stubble, spent barley and flax
• Textile and cordage wastes: Upcycling textile fibers also contribute to tree-free paper production.

https://en.wikipedia.org/wiki/Tree-free_paper

 

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Engineers Incorporate Optoelectronic Diodes Into Washable Fabrics

August 9, 2018

 

 

For the first time, the researchers from MIT and AFFOA have produced fibers with embedded electronics that are so flexible they can be woven into soft fabrics and made into wearable clothing. 

 

The latest development in textiles and fibers is a kind of soft hardware that you can wear: cloth that has electronic devices built right into it. 

 

Researchers at MIT have now embedded high-speed optoelectronic semiconductor devices, including light-emitting diodes (LEDs) and diode photodetectors, within fibers that were then woven at Inman Mills, in South Carolina, into soft, washable fabrics and made into communication systems. This marks the achievement of a long-sought goal of creating “smart” fabrics by incorporating semiconductor devices — the key ingredient of modern electronics — which until now was the missing piece for making fabrics with sophisticated functionality.

 

This discovery, the researchers say, could unleash a new “Moore’s Law” for fibers — in other words, a rapid progression in which the capabilities of fibers would grow rapidly and exponentially over time, just as the capabilities of microchips have grown over decades.

 

The findings are described this week in the journal Nature in a paper by former MIT graduate student Michael Rein; his research advisor Yoel Fink, MIT professor of materials science and electrical engineering and CEO of AFFOA (Advanced Functional Fabrics of America); along with a team from MIT, AFFOA, Inman Mills, EPFL in Lausanne, Switzerland, and Lincoln Laboratory.

 
https://scitechdaily.com/engineers-incorporate-optoelectronic-diodes-into-washable-fabrics/

 

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Chapter 4: Sustainable Paints & coatings 

 

____________________________________
____________________________________

 

 

 



____________________________________

 

 
The people want a sustainable methods that we can use in paints, including coatings for vehicles, tools, machines, medical applications and everyday uses. We can see natural coatings such as crystalline coatings and patinas. We can look at nature to make better and more sustainable coatings and finishes for many items.




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Patina

 Patina  is a thin layer that variously forms on the surface of stone; on copper, bronze and similar metals (tarnish produced by oxidation or other chemical processes); on wooden furniture (sheen produced by age, wear, and polishing); or any such acquired change of a surface through age and exposure. Patinas can provide a protective covering to materials that would otherwise be damaged by corrosion or weathering. They may also be aesthetically appealing.

 On metal, patina is a coating of various chemical compounds such as oxides, carbonates, sulfides, or sulfates formed on the surface during exposure to atmospheric elements (oxygen, rain, acid rain, carbon dioxide, sulfur-bearing compounds), a common example of which is rust which forms on iron or steel when exposed to oxygen. Patina also refers to accumulated changes in surface texture and colour that result from normal use of an object such as a coin or a piece of furniture over time.

https://en.wikipedia.org/wiki/Patina

 

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Many firearms with a thin layer of green patinas are often considered highly valuable, that is if the firearm still is in good condition. The firearm can last for a very long time once a layer of green patina collects on a firearm. This means that the firearm could be preserved for many hundreds of years, with the patina now protecting the metal from accelerated rust. 

Some question if we could improve this type of natural technology, for certain types of natural finishes for paints and powder coatings.



____________________________________

 

Copper in architecture

https://en.wikipedia.org/wiki/Copper_in_architecture#Finishes

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Graphene layer could quadruple rate of condensation heat transfer in generating plants

Jun 01, 2015

Most of the world's electricity-producing power plants—whether powered by coal, natural gas, or nuclear fission—make electricity by generating steam that turns a turbine. That steam then is condensed back to water, and the cycle begins again.

But the condensers that collect the steam are quite inefficient, and improving them could make a big difference in overall power plant efficiency.

Now, a team of researchers at MIT has developed a way of coating these condenser surfaces with a layer of graphene, just one atom thick, and found that this can improve the rate of heat transfer by a factor of four—and potentially even more than that, with further work. And unlike polymer coatings, the graphene coatings have proven to be highly durable in laboratory tests.

http://phys.org/news/2015-06-graphene-layer-quadruple-condensation.html#jCp

____________________________________

Graphene used to rust-proof steel

  

May 29, 2012

Hexavalent chromium compounds are a key ingredient in coatings used to rust-proof steel. They also happen to be carcinogenic. Researchers, therefore, have been looking for non-toxic alternatives that could be used to keep steel items from corroding. Recently, scientists from the University at Buffalo announced that they have developed such a substance. It’s a varnish that incorporates graphene, the one-atom-thick carbon sheeting material that is the thinnest and strongest substance known to exist.

http://www.gizmag.com/graphene-anti-rust-coating/22731/?li_source=LI&li_medium=default-widget


____________________________________ 

Slick coating keeps steel clean and tough

 

October 21, 2015

When liquids stick to steel for long enough, the steel corrodes or becomes contaminated. Unfortunately, however, porous surface coatings that repel liquids also tend to make steel weaker … until now, that is. Scientists at Harvard University have recently discovered that their existing SLIPS (Slippery Liquid Porous Surfaces) technology not only causes liquids to roll right off, but it actually makes steel stronger.

Led by Prof. Joanna Aizenberg, the Harvard team utilized electrochemical deposition to apply a a surface coating of rough nanoporous tungsten oxide to small sheets of steel. This coating took the form of an utra-thin film, actually made up of hundreds of thousands of separate microscopic tungsten oxide "islands." The resulting surace roughness keeps liquid from sticking to the steel.
Additionally, because they're not connected to one another, if any of the islands are damaged by abrasion to the film, that damage stays localized instead of affecting the whole coating.


http://www.gizmag.com/slips-steel-coating/39982/?li_source=LI&li_medium=default-widget

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Tin-based stanene could conduct electricity with 100 percent efficiency

 

December 1, 2013

A team of theoretical physicists from the US Department of Energy’s (DOE) SLAC National Accelerator Laboratory and Stanford University is predicting that stanene, a single layer of tin atoms laid out in a two-dimensional structure, could conduct electricity with one hundred percent efficiency at room temperature. If the findings are confirmed they could pave the way for building computer chips that are faster, consume less power, and won't heat up nearly as much.
Stanene is an example of a topological insulator, a class of materials that conduct electricity only on their outside edges or surfaces. When topological insulators are just one atom thick, their edges conduct electricity with 100 percent efficiency, forcing electrons to move in defined lanes, without resistance.

http://www.gizmag.com/stanene-topological-insulator/29976/



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Nano Coatings

http://www.voyle.net/Nano%20Coatings/%20Nano%20Coating1.htm



____________________________________


Many different paints and coatings are used for different applications. It debated what are some of the most sustainable type of coatings out there. Many people say that we should start using medical grade type coatings for different industrial applications. It can be very expensive to produce many types of medical grade and sustainable type coatings.


____________________________________

 

Physical vapor deposition

http://en.wikipedia.org/wiki/Physical_vapor_deposition

 

____________________________________

Titanium nitride

 http://en.wikipedia.org/wiki/Titanium_nitride

 

____________________________________

Ion plating

 

http://en.wikipedia.org/wiki/Ion_plating

 
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Ion implantation

  

http://en.wikipedia.org/wiki/Ion_implantation

____________________________________

Indium tin oxide

https://en.wikipedia.org/wiki/Indium_tin_oxide


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Cathodic arc deposition

 http://en.wikipedia.org/wiki/Cathodic_arc_deposition

 

____________________________________

Plasma-immersion ion implantation

 http://en.wikipedia.org/wiki/Plasma-immersion_ion_implantation

 

____________________________________ 

Thin film

 http://en.wikipedia.org/wiki/Thin_film


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Thermal spraying

Several variations of thermal spraying are distinguished:

• Plasma spraying
• Detonation spraying
• Wire arc spraying
• Flame spraying
• High velocity oxy-fuel coating spraying (HVOF)
• Warm spraying
• Cold spraying

http://en.wikipedia.org/wiki/Thermal_spraying

 


____________________________________

 


People have used zinc, copper and phosphate coatings. Yet people will always try to find ways to make different types of sustainable coatings that last longer, and even coatings that conduct electricity.



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Transparent ceramics

 

Nanomaterials

It has been shown fairly recently that laser elements (amplifiers, switches, ion hosts, etc.) made from fine-grained ceramic nanomaterials—produced by the low temperature sintering of high purity nanoparticles and powders—can be produced at a relatively low cost. These components are free of internal stress or intrinsic birefringence, and allow relatively large doping levels or optimized custom-designed doping profiles. This highlights the use of ceramic nanomaterials as being particularly important for high-energy laser elements and applications.


http://en.wikipedia.org/wiki/Transparent_ceramics


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New nanowire structure absorbs light efficiently

Feb 25, 2015

 Researchers at Aalto University have developed a new method to implement different types of nanowires side-by-side into a single array on a single substrate. The new technique makes it possible to use different semiconductor materials for the different types of nanowires.


 'We have succeeded in combining nanowires grown by the VLS (vapor-liquid-solid) and SAE (selective-area epitaxy) techniques onto the same platform. The difference compared with studies conducted previously on the same topic is that in the dual-type array the different materials do not grow in the same nanowire, but rather as separate wires on the same substrate', says Docent Teppo Huhtio.

The research results were published in the Nano Letters journal on 5 February 2015.



The new fabrication process has many phases. First, gold nanoparticles are spread on a substrate. Next, the substrate is coated with silicon oxide, into which small holes are then patterned using electron beam lithography. In the first step of growth, (SAE), nanowires grow from where the holes are located, after which the silicon oxide is removed. In the second phase different types of nanowires are grown with the help of the gold nanoparticles (VLS). The researchers used metalorganic vapor phase epitaxy reactor in which the starting materials decompose at a high temperature, forming semiconductor compounds on the substrate.

'In this way we managed to combine two growth methods into the same process', says doctoral candidate Joona-Pekko Kakko.


'We noticed in optical reflection measurements that light couples better to this kind of combination structure. For instance, a solar cell has less reflection and better absorption of light', Huhtio adds.

In addition to solar cells and LEDs, the researchers also see good applications in thermoelectric generators.  Further processing for component applications has already begun.

Nanowires are being intensely researched, because semiconductor components that are currently in use need to be made smaller and more cost-effective. The nanowires made out of semiconductor materials are typically 1-10 micrometres in length, with diameters of 5-100 nanometres.


Read more at: http://phys.org/news/2015-02-nanowire-absorbs-efficiently.html#jCp



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 Calculations reveal how mixtures of different elements can control the thermal properties of nanowires

Apr  2015

A mathematical model of heat flow through miniature wires could help develop thermoelectric devices that efficiently convert heat—even their own waste heat—into electricity.

Read more at: http://phys.org/news/2015-04-reveal-mixtures-elements-thermal-properties.html#jCp


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Stretchable ceramics made by flame technology

 

June 8th, 2015

 Synthesizing nanoscale materials takes place within high-tech laboratories, where scientists in full-body suits keep every grain of dust away from their sensitive innovations. However, scientists at Kiel University proved that this is not always necessary. They have successfully been able to transfer the experience from furnace to laboratory while synthesizing nanoscale materials using simple and highly efficient flame technology. This "baking" of nanostructures has already been a great success using zinc oxide. The recent findings concentrate on tin oxide, which opens up a wide field of possible new applications. The material scientists published their latest research data in today's issue (Friday, 5 June) of the renowned scientific journal Advanced Electronic Materials.

http://phys.org/news/2015-06-stretchable-ceramics-flame-technology.html#jCp



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New Iron-Based Material Could Be The Best High Temperature Superconductor

 

 http://www.greenoptimistic.com/new-iron-based-material-could-be-the-best-high-temperature-superconductor-20100120/#.VSFdkeG-2zk

 

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Team announces breakthrough observation of Mott transition in a superconductor

 

September 11, 2015 

 

An international team of researchers, including the MESA+ Institute for Nanotechnology at the University of Twente in The Netherlands and the U.S. Department of Energy's Argonne National Laboratory, announced today in Science the observation of a dynamic Mott transition in a superconductor.

The discovery experimentally connects the worlds of classical and quantum mechanics and illuminates the mysterious nature of the Mott transition. It also could shed light on non-equilibrium physics, which is poorly understood but governs most of what occurs in our world. The finding may also represent a step towards more efficient electronics based on the Mott transition.

 http://phys.org/news/2015-09-team-breakthrough-mott-transition-superconductor.html#jCp




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Quantum scientists break aluminium 'monopoly' (Update)

 

May 25, 2015 

 

 

 A Majorana fermion, or a Majorana particle, is a fermion that is its own antiparticle. Discovering the Majorana was the first step, but utilizing it as a quantum bit (qubit) still remains a major challenge. An important step towards this goal has just been taken by researchers from TU Delft in today's issue of Nature Physics. It is a nearly thirty-year-old scientific problem that has just been resolved: demonstrating the difference between the even and odd occupation of a superconductor in high magnetic fields. Thus far, this was only possible in aluminium, which is incompatible with Majoranas. This result enables the read out and manipulation of quantum states encoded in prospective Majorana qubits.

 

http://phys.org/news/2015-05-monopoly-aluminium-broken.html#ajTabs

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Superconductor breaks high-temperature record

 

Iron-based crystal regains conducting properties under pressure.

 22 February 2012

http://www.nature.com/news/superconductor-breaks-high-temperature-record-1.10081

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 New microfiber emitters boost production of versatile fibers fourfold, cut energy consumption by 92 percent
 

Jun 05, 2015

 http://phys.org/news/2015-06-microfiber-emitters-boost-production-versatile.html?utm_source=menu&utm_medium=link&utm_campaign=item-menu

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Passive cooling paint sweats off heat to deliver 10X cooling and 30% energy savings

June 18, 2025 

A new cement-based paint can cool down the building by sweating off the heat. The cooling paint, named CCP-30, was designed by an international team of researchers and features a nanoparticle-modified porous structure composed of a calcium silicate hydrate (C-S-H) gel network.

https://techxplore.com/news/2025-06-passive-cooling-10x-energy.html

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Laser-assisted cold spray: A new generation of innovative manufacturing technology

July 2, 2025 

The Center for Industrial Photonics (CIP) at the Institute for Manufacturing (IfM) has developed an additive manufacturing technique—laser-assisted cold spray (LACS).

The process uses localized heating of a supersonic powder stream with a laser to deposit metals and cermets to build, coat or repair parts, overcoming the high-temperature and material limitations of comparable techniques such as thermal spraying.

The CIP team has demonstrated the effectiveness of LACS in aerospace applications, where high-precision and localized material deposition are critical. This technique enables on-demand fabrication of high-quality coatings and component repairs, extending aircraft lifespan. Additionally, LACS reduces material waste and energy consumption compared to traditional methods, supporting the industry's transition towards net-zero emissions.

https://techxplore.com/news/2025-07-laser-cold-spray-generation-technology.html


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Nanomaterial advanced smart coatings: Emerging trends shaping the future

2024

Abstract

Advancements in nanotechnology have positioned coatings as a pivotal field with the potential to significantly impact both industry and society. This review delves into nanomaterials and their potential to create smart coatings capable of real-time monitoring and flexible electronics applications. The mechanisms of conductivity and sensing capabilities within these coatings are emphasized to highlight their importance in the context of artificial intelligence. Furthermore, the current trends shaping the coatings industry are summarized, such as the concept of electronic skin (E-skin) and increasing focus on sustainability. In the digital era, the integration of the Internet of Things (IoT) is set to transform the future of coatings, enhancing their intelligence and environmental interactivity. Smart coatings are poised to revolutionize our interaction with the environment, spanning applications from consumer goods to robotics and sensors. The ongoing development of these materials and technologies promises to unlock new and exciting possibilities. By discussing the above aspects in detail, this review positions itself as a forward-looking contribution that summarizes the state-of-the-art and anticipates future directions for smart coatings, offering insights into how ongoing advancements can unlock new possibilities for both industrial applications and societal impact.

1. COATINGS: an overview of state-of-the-art

Coatings have played a significant role throughout history, from prehistoric cave paintings to advanced coatings in various industries. It is a crucial topic in the scientific community, and the reasons for this widespread attention are its potential to combine the bulk properties of a substrate with the tailored capabilities of a layer at the surface and the availability of various deposition techniques [1,2]. Coatings can provide enhanced functionality by incorporating functional additives in low concentrations. By utilising these additives, the properties of the coatings are improved significantly, making them versatile and suitable for a wide range of applications. In addition, coatings reduce maintenance costs and extend the lifetime of products. Stimuli-responsive materials in coatings enable them to sense and react to environmental alterations, including temperature, force, sound, pH, electric and magnetic field (Fig. 1) [3]. Though the selection of strategy for the synthesis of coatings depends highly on the desired application, the most common methods used for the fabrication of coatings include electrochemical plating, conversion coatings, chemical and physical vapour depositions, thermal spray coating, sol-gel coatings, micro- and nanocapsule based coatings. Amongst, electrochemical plating is the simplest and most cost-effective method for coating metals to a substrate [4,5]. Aoki et al. reported a reversible electrochromic mirror for smart window applications by utilising the electroplating method to coat a film of Ag onto a transparent ITO electrode [6]. Kim et al. employed the electroplating technique to deposit nickel nanocones and zinc oxide nanosheets onto fabric, producing multifunctional materials that are wearable, stretchable, washable, hydrophobic, and antibacterial. Additionally, these materials exhibited sensing, heating, and supercapacitive properties [7]. They are widely used in self-cleaning [8], optically active [9], anti-corrosion [10], anti-bacterial, and anti-fouling applications [11] in various industries, such as automotive, military, biomedical, building, and construction (Fig. 2). The introduction of nanotechnology boosted the coating industry by creating novel coating formulations, resulting in the development of multifunctional coating systems [12]. Carbon nanotubes (CNTs) are used for enhancing physical reinforcement and conductivity properties; nanoclays for improved barrier properties and low cost; titanium, cerium, and zinc oxide nanoparticles for UV absorption properties due to their combination of efficiency and lack of migration from the film are few examples of such nanomaterials [[13], [14], [15]].

2. Nanomaterials for smart coatings

2.1. Carbonaceous materials: CNTs & graphene

The utilization of carbon-based materials has generated significant interest in the development of smart coatings. Carbon, the fundamental element for life on Earth, plays a crucial role in a multitude of technological applications. This is due to carbon's exceptional ability to bind to itself and all other elements in countless ways. The two natural allotropes of elemental carbon are diamond and graphite, which consist of extended networks of sp3- and sp2-hybridized carbon atoms, respectively. Both forms exhibit unique physical properties such as hardness, thermal conductivity, lubrication behavior, and electrical conductivity. The discovery of fullerenes in 1985 by Kroto et al. marked the beginning of a growing family of synthetic carbon allotropes, including the synthesis of CNTs in 1991 and graphene in 2004 (Fig. 3) [39].

 

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[3] A comprehensive review of stimuli-responsive smart polymer materials—recent advances and future perspectives

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[5]Strength comparison of topology optimized lattice from printed SLA resin, electroplated resin and PBF aluminum alloy

[6] Reversible Ag electroplating onto ITO electrode for smart window
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[7] Wearable sensors and supercapacitors using electroplated-Ni/ZnO antibacterial fabric

[8] Improved self-cleaning properties of an efficient and easy to scale up TiO2 thin films prepared by adsorptive self-assembly

[9] HfO2-based nanostructured thin-films (i.e., low-e coatings) with robust optical performance and energy efficiency

[10] A comprehensive review on smart anti-corrosive coatings

[11] Enabling antibacterial and antifouling coating via grafting of a nitric oxide-releasing ionic liquid on silicone rubber

[12] Ulaeto, S.B., et al., Smart Coatings. 2018. p. 341–372.

[13] Transparent, conductive carbon nanotube films

[14] Graphene: status and prospects

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[17] Self-cleaning transparent superhydrophobic coatings through simple sol–gel processing of fluoroalkylsilane

[18] Smart-Sensing polymer coatings with autonomously reporting corrosion dynamics of self-healing systems

[19] Military Applications: Development of Superomniphobic Coatings, Textiles and Surfaces
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[20] An overview of controlled-biocide-release coating based on polymer resin for marine antifouling applications

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[39] The era of carbon allotropes

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[51] Fabrication and analysis of integrated multifunctional MWCNTS sensors in glass fiber reinforced polymer composites

[52] Multifunctional pressure/temperature/bending sensor made of carbon fibre-multiwall carbon nanotubes for artificial electronic application

[53] Interlaminar properties of carbon nanotubes modified carbon fibre fabric reinforced polyimide composites

[54] Nano-graphene E-glass fibre epoxy polymer composite thermal and mechanical characteristics study
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[58] Nanoindentation mapping of multiscale composites of graphene-reinforced polypropylene and carbon fibres

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[60] Measurement of the elastic properties and intrinsic strength of monolayer graphene

[61] Superior thermal conductivity of single-layer graphene

[62] Recent advances of graphene-based materials for emerging technologies

[63] Evolving strategies for producing multiscale graphene-enhanced fiber-reinforced polymer composites for smart structural applications

[64] Electrical property of graphene and its application to electrochemical biosensing

[65] Graphene oxide composite membranes for water purification

[66] MoS2/Graphene composites as promising materials for energy storage and conversion applications

[67] Ag-fiber/graphene hybrid electrodes for highly flexible and transparent optoelectronic devices

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[84] Production of conductive PEDOT-coated PVA-GO composite nanofibers

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[86] Colorimetric thermometer from graphene oxide platform integrated with red, green, and blue emitting, responsive block copolymers

[87] High Thermal Responsiveness of a Reduced Graphene Oxide Field-Effect Transistor

[88] Multifunctional light-responsive graphene-based polyurethane composites with shape memory, self-healing, and flame retardancy properties

[89] Near-infrared light-responsive poly (N-isopropylacrylamide)/graphene oxide nanocomposite hydrogels with ultrahigh tensibility

[90] Near-infrared light-responsive graphene oxide composite multilayer capsules: a novel route for remote controlled drug delivery

[91] High-performance strain sensors with fish-scale-like graphene-sensing layers for full-range detection of human motions

[92] Stretchable and highly sensitive graphene-on-polymer strain sensors

[93] Super-elastic graphene ripples for flexible strain sensors

[94] Detection of individual gas molecules adsorbed on graphene

[95] Direct power generation from a graphene oxide film under moisture

[96] Ultrahigh humidity sensitivity of graphene oxide

[97] Highly stable, concentrated dispersions of graphene oxide sheets and their electro-responsive characteristics

[98] A pH and Electric Responsive Graphene Oxide Based Composite hydrogel. in Adv. Mater. Research

[99] A rationally-designed synergetic polypyrrole/graphene bilayer actuator

[100] Fabrication of smart magnetite/reduced graphene oxide composite nanoparticles and their magnetic stimuli-response

[101] Water-dispersible magnetite-reduced graphene oxide composites for arsenic removal

[102] Recent studies on dispersion of graphene–polymer composites

[103] Applications of graphene-based composite hydrogels: a review

[104] MXene and graphene coated multifunctional fiber reinforced aerospace composites with sensing and EMI shielding abilities

[105] Graphene as a piezoresistive material in strain sensing applications

[106] In-situ monitoring of crack growth and fracture behavior in composite laminates using embedded sensors of rGO coated fabrics and GnP paper

[107] 2D transition metal dichalcogenide nanomaterials: advances, opportunities, and challenges in multi-functional polymer nanocomposites

[108] Large-area synthesis of transition metal dichalcogenides via CVD and solution-based approaches and their device applications

[109] The chemistry of two-dimensional layered transition metal dichalcogenide nanosheets

[110] Recent development of two-dimensional transition metal dichalcogenides and their applications

[111] Transition metal dichalcogenides-based flexible gas sensors

[112] MoS2-decorated laser-induced graphene for a highly sensitive, hysteresis-free, and reliable piezoresistive strain sensor

[113] A detailed comparative performance analysis of the Transition Metal Di-chalcogenides (TMDs) based strain sensors through experimental realisations and first principle calculations

[114] Flexible electronics based on 2D transition metal dichalcogenides

[115] High gauge factor strain sensors based on vanadium doped molybedenum disulfide 2D films

[116] A noncovalent functionalization approach to improve the dispersibility and properties of polymer/MoS2 composites

[117] In situ growth of 0D silica nanospheres on 2D molybdenum disulfide nanosheets: towards reducing fire hazards of epoxy resin

[118] Design of nacre-inspired 2D-MoS2 nanosheets assembled with mesoporous covalent organic frameworks (COFs) for smart coatings

[119] Recent advancements in the fabrication of transition metal dichalcogenides-polymer nanocomposites: focused on molybdenum diselenide for various applications

[120] MoSe2 nanosheet/poly(3,4-ethylenedioxythiophene): poly(styrenesulfonate) composite film as a Pt-free counter electrode for dye-sensitized solar cells

[121] MAX phases – Past, present, and future

[122] The world of two-dimensional carbides and nitrides (MXenes)

[123] MXenes for energy harvesting

[124] Polypyrrole–MXene coated textile-based flexible energy storage device

[125] Fabrication of MXene transparent conductive films via transfer process

[126] MXene-Based energy devices: from progressive to prospective

[127] The rise of MXenes

[128] MXenes: two-dimensional building blocks for future materials and devices

[129] MXenes and their applications in wearable sensors

[130] Recent advances in MXene-based sensors for structural health monitoring applications: a review

[131] High electrical conductivity and breakdown current density of individual monolayer Ti3C2Tx MXene flakes

[132] Simplified synthesis of fluoride-free Ti3C2Tx via electrochemical etching toward high-performance electrochemical capacitors

[133] Fluorine-free synthesis of high-purity Ti3C2Tx (T= OH, O) via alkali treatment

[134] A Family of 2D-MXenes: synthesis, Properties, and Gas Sensing Applications

[135] Recent advances in 2D metal carbides and nitrides (MXenes): synthesis and biological application

[136] Electrically conductive 2D material coatings for flexible and stretchable electronics: a comparative review of Graphenes and MXenes

[137] Flexible and high-sensitivity piezoresistive sensor based on MXene composite with wrinkle structure

[138] A wearable transient pressure sensor made with MXene nanosheets for sensitive broad-range human–machine interfacing

[139] Highly sensitive, reliable and flexible piezoresistive pressure sensors featuring polyurethane sponge coated with MXene sheets

[140] 3D synergistical MXene/reduced graphene oxide aerogel for a piezoresistive sensor

[141] Health monitoring of repaired composite structure using MXene sensor

[142] Why Would You Need Conductive Coatings? 

[143] Electrically Conductive Coatings for Fiber-Based E-Textiles

[144] Introduction to nano-hybrid smart coatings

[145] Durable and multifunctional superhydrophobic coatings with excellent joule heating and electromagnetic interference shielding performance for flexible sensing electronics

[146] Electrical behavior of carbon black-filled polymer composites: effect of interaction between filler and matrix

[147] Self-Healing mechanism and conductivity of the hydrogel flexible sensors: a review

[148] 10 Electrical and Electromagnetic Properties of CNT/Polymer Composites, in Carbon Nanotube-Reinforced Polymers

[149] Fractal Dimension Analysis of muscle fatigue with muscle surface pressure measures with compression garments. In 2nd International Conference in Sports Science & Technology (ICSST)

[150] 8 Synthesis and properties of percolative metal oxide-polymer composites

[151] Electrical percolation in graphene-polymer composites

[152] Electrical percolation in graphene–polymer composites

[153] 2D Materials towards sensing technology: from fundamentals to applications

[154] Applications of graphene-based materials in sensors: a review

[155] Graphene-based wearable piezoresistive physical sensors

[156] Wearable Multi-Functional Sensing Technology for Healthcare Smart Detection

[157] Anisotropic conductive networks for multidimensional sensing

[158] Flexible multifunctional sensors for wearable and robotic applications

[159] Morphological engineering of sensing materials for flexible pressure sensors and artificial intelligence applications

[160] 2D material-based sensing devices: an update

[161] Optimizing diamond-like carbon coatings From experimental era to artificial intelligence

[162] Graphene nanoparticles as data generating digital materials in industry 4.0

[163] A state-of-the-art review on sensors and signal processing systems in mechanical machining processes

[164] Structural health monitoring using wireless smart sensor network – An overview

[165] Digital twin-based structural health monitoring by combining measurement and computational data: an aircraft wing example

[166] A Digital Twin concept for the prescriptive maintenance of protective coating systems on wind turbine structures

[167] Cloud-Based digital twinning for structural health monitoring using deep learning

[168] Digitization of manufacturing processes: from sensing to twining

[169] Muscle Activity Analysis with a Smart Compression Garment

[170] Muscle performance investigated with a novel smart compression garment based on pressure sensor force myography and its validation against EMG

[171] Discovery of a sweet spot on the foot with a smart wearable soccer boot sensor that maximizes the chances of scoring a curved kick in soccer

[172] Additively fabricated electronic skin with high performance in dynamic sensing as human skin

[173] Future green chemistry and sustainability needs in polymeric coatings

[174] Neuro-inspired electronic skin for robots

[175] Electronic Skin: recent Progress and Future Prospects for Skin-Attachable Devices for Health Monitoring, Robotics, and Prosthetics

[176] Recent advances in carbon material-based multifunctional sensors and their applications in electronic skin systems

[177] Novel low-carbon energy solutions for powering emerging wearables, smart textiles, and medical devices

[178] Recent progress in electronic skin

[179] 25th anniversary article: the evolution of electronic skin (E-Skin): a brief history, design considerations, and recent progress

[180] Research on the preparation and thermal stability of silicone rubber composites: a review

[181] PEDOT:PSS for flexible and stretchable electronics: modifications, strategies, and applications

[182] A comprehensive review on CNTs and CNT-reinforced composites: syntheses, characteristics and applications

[183] A stretchable array of high-performance electrochromic devices for displaying skin-attached multi-sensor signals

[184] Stretchable micromotion sensor with enhanced sensitivity using serpentine layout

[185] The more and less of electronic-skin sensors

[186] Water-Modulated biomimetic hyper-attribute-gel electronic skin for robotics and skin-attachable wearables

[187] Energy autonomous electronic skin with direct temperature-pressure perception

[188] A direction-aware and ultrafast self-healing dual network hydrogel for a flexible electronic skin strain sensor

[189] Nanomaterials: fingertip skin-inspired microstructured ferroelectric skins discriminate static/dynamic pressure and temperature stimuli

[190] A chameleon-inspired stretchable electronic skin with interactive colour changing controlled by tactile sensing

[191] An ultra-low hysteresis, self-healing and stretchable conductor based on dynamic disulfide covalent adaptable networks

[192] Barbaz-Isfahani, R., S. Saber-Samandari, and M. Salehi, Experimental and numerical research on healing performance of reinforced microcapsule-based self-healing polymers using nanoparticles. 

[193] Disulfide bond and Diels–Alder reaction bond hybrid polymers with high stretchability, transparency, recyclability, and intrinsic dual healability for skin-like tactile sensing

[194] Artificial optoelectronic synaptic characteristics of Bi2FeMnO6 ferroelectric memristor for neuromorphic computing

[195] Synaptic properties of a PbHfO3 ferroelectric memristor for neuromorphic computing

[196] Passivating contacts for crystalline silicon solar cells

[197] Andreani, L.C., et al., Silicon solar cells: toward the efficiency limits. 

[198] Design rules for high-efficiency both-sides-contacted silicon solar cells with balanced charge carrier transport and recombination losses

[199] Carbon nanotubes for photovoltaics: from lab to industry

[200] High-efficiency CNT-Si solar cells based on a collaborative system enabled by oxide penetration

[201] CdTe-Based thin film solar cells: past, present and future

[202] A review of primary technologies of thin-film solar cells

[203] Tin-Lead perovskite fabricated via ethylenediamine interlayer guides to the solar cell efficiency of 21.74%

[204] Promoting charge separation resulting in ternary organic solar cells efficiency over 17.5%

[205] Low-bandgap mixed tin–lead iodide perovskites with reduced methylammonium for simultaneous enhancement of solar cell efficiency and stability

[206] Room-Temperature sputtered SnO2 as robust electron transport layer for air-stable and efficient perovskite solar cells on rigid and flexible substrates

[207] Advanced alkali treatments for high-efficiency Cu(In,Ga)Se2 solar cells on flexible substrates

[208] Surface and interface science. Surface and Interface Science, 2020.

[209] Saygili, Y., Copper Bipyridyl Redox Mediators for High Performance Dye-Sensitized Solar Cells. 2019.

[210] Novel Epitaxial Lift-Off for Flexible, Inexpensive GaAs Solar Cells

[211] Influence of water and precursor molarity on the tio2 thin films deposited from solventless sol-gel

[212] Choice of precursor not affecting the size of anatase TiO2 nanoparticles but affecting morphology under broader view

[213] Defective MWCNT enabled dual interface coupling for carbon-based perovskite solar cells with efficiency exceeding 22%

[214] Hole Transport Materials Based on 6,12-Dihydroindeno[1,2-b]fluorine with Different Periphery Groups: a New Strategy for Dopant-Free Perovskite Solar Cells

[215] The future of spirobifluorene-based molecules as hole-transporting materials for solar cells

[216] Oxidation of Spiro-OMeTAD in high-efficiency perovskite solar cells

[217] Generation of electrical power under human skin by subdermal solar cell arrays for implantable bioelectronic devices

[218] Efficient exploration of the composition space in ternary organic solar cells by combining high-throughput material libraries and hyperspectral imaging

[219] The energy level conundrum of organic semiconductors in solar cells

[220] Fiber/Fabric-Based piezoelectric and triboelectric nanogenerators for flexible/stretchable and wearable electronics and artificial intelligence

[221] Recent progress in flexible–wearable solar cells for self-powered electronic devices

[222] Mineralized soft and elastic polymer dot hydrogel for a flexible self-powered electronic skin sensor

[223] Spectrally robust series/parallel-connected triple-junction photovoltaic cells used for artificial photosynthesis

[224] Solution-processed monolithic all-perovskite triple-junction solar cells with efficiency exceeding 20%

[225] Reaching the ultimate efficiency of solar energy harvesting with a nonreciprocal multijunction solar cell

[226] Progress and challenges in perovskite photovoltaics from single- to multi-junction cells

[227] A triboelectric-electromagnetic hybrid nanogenerator with broadband working range for wind energy harvesting and a self-powered wind speed sensor

[228] A mobile and self-powered micro-flow pump based on triboelectricity driven electroosmosis

[229] Design of a self-powered triboelectric face mask

[230] Nanopillar-array architectured PDMS-based triboelectric nanogenerator integrated with a windmill model for effective wind energy harvesting

[231] A CNT-PDMS wearable device for simultaneous measurement of wrist pulse pressure and cardiac electrical activity

[232] Artificial tactile perception smart finger for material identification based on triboelectric sensing


[233] Ambulatory cardiovascular monitoring via a machine-learning-assisted textile triboelectric sensor

[234] Wearable triboelectric sensors enabled gait analysis and waist motion capture for IoT-based smart healthcare applications

[235] Review of power converter impact of electromagnetic energy harvesting circuits and devices for autonomous sensor applications

[236] High-performance cycloid inspired wearable electromagnetic energy harvester for scavenging human motion energy

[237] Enhanced swing electromagnetic energy harvesting from human motion

[238] The optimization of an electromagnetic vibration energy harvester based on developed electromagnetic damping models

[239] Constituting abrupt magnetic flux density change for power density improvement in electromagnetic energy harvesting

[240] A low-frequency rotational electromagnetic energy harvester using a magnetic plucking mechanism

[241] Ultraflexible, highly efficient electromagnetic interference shielding, and self-healable triboelectric nanogenerator based on Ti3C2Tx MXene for self-powered wearable electronics

[242] Magnetized microcilia array-based self-powered electronic skin for micro-scaled 3D morphology recognition and high-capacity communication

[243] Three-dimensional AgNps@Mxene@PEDOT:PSS composite hybrid foam as a piezoresistive pressure sensor with ultra-broad working range

[244] Biocompatible poly(lactic acid)-based hybrid piezoelectric and electret nanogenerator for electronic skin applications

[245] Human skin interactive self-powered piezoelectric e-skin based on PVDF/MWCNT electrospun nanofibers for non-invasive health care monitoring

[246] Enhanced electromagnetic wrist-worn energy harvester using repulsive magnetic spring

[247] Smart Magnetotactic Bacteria Enable the Inhibition of Neuroblastoma under an Alternating Magnetic Field

[248] Expanding magnetic organelle biogenesis in the domain bacteria

[249] Electrically contacted bienzyme-functionalized mesoporous carbon nanoparticle electrodes: applications for the development of dual amperometric biosensors and multifuel-driven biofuel cells

[250] Soft–Hard Composites for Bioelectric Interfaces

[251] Energy harvesting using two-dimensional magnesiochromite (MgCr2O4)

[252] Flame-retardant and leakage-proof phase change composites based on MXene/polyimide aerogels toward solar thermal energy harvesting

[253] Simultaneous solar-thermal energy harvesting and storage via shape stabilized salt hydrate phase change material

[254] Anisotropically conductive phase change composites enabled by aligned continuous carbon fibers for full-spectrum solar thermal energy harvesting

[255] High-Performance thermally conductive phase change composites by large-size oriented graphite sheets for scalable thermal energy harvesting

[256] High-performance thermally conductive phase change composites by large-size oriented graphite sheets for scalable thermal energy harvesting

[257] Full spectrum solar thermal energy harvesting and storage by a molecular and phase-change hybrid material an integrated hybrid system for simultaneous harvesting and storage of solar thermal energy. Full spectrum solar thermal energy harvesting and storage by a molecular and phase-change hybrid material

[258] Carbon nanotube bundles assembled flexible hierarchical framework based phase change material composites for thermal energy harvesting and thermotherapy

[259] Constructing flexible film electrode with porous layered structure by MXene/SWCNTs/PANI ternary composite for efficient low-grade thermal energy harvest

[260] High Power Density Thermoelectric Generators with Skutterudites

[261] Half-Heusler-like compounds with wide continuous compositions and tunable p- to n-type semiconducting thermoelectrics

[262] Dramatically reduced lattice thermal conductivity of Mg2Si thermoelectric material from nanotwinning

[263] Performance comparison of hybrid functionals for describing narrow-gap semiconductors: a study on low-temperature thermoelectric material α-SrSi2

[264] Toward self-powered real-time health monitoring of body fluid components based on improved enzymatic biofuel cells

[265] Redox-Mediated gold nanoparticles with glucose oxidase and egg white proteins for printed biosensors and biofuel cells

[266] Engineering hybrid nanotube wires for high-power biofuel cells

[267] Insights into the role of nanotechnology on the performance of biofuel cells and the production of viable biofuels: a review

[268] Flexible biofuel cell-in-a-tube (iezTube): an entirely self-contained biofuel cell for wearable green bio-energy harvesting

[269] A bendable biofuel cell-based fully integrated biomedical nanodevice for point-of-care diagnosis of scurvy

[270] A screen-printed circular-type paper-based glucose/O2 biofuel cell

[271] Self-Powered electrochemical lactate biosensing

[272] Printed-scalable microstructure BaTiO3/ecoflex nanocomposite for high-performance triboelectric nanogenerators and self-powered human-machine interaction

[273] Ultra-high dielectric tuning performance and double-set resistive switching effect achieved on the Bi2NiMnO6 thin film prepared by sol–gel method

[274] Electrocatalytic response of the modified ZnO-G electrodes towards the oxidation of serotonin with multi metallic corrosion protection

[275] Hybrid electrochemical behaviour of La1-xCaxMnO3 nano perovskites and recycled polar interspersed graphene for metal-air battery system

[276] Towards sustainable fuel cells and batteries with an AI perspective

[277] Growth mechanism of micro/nano metal dendrites and cumulative strategies for countering its impacts in metal ion batteries: a review

[278] Li-ion batteries: basics, progress, and challenges

[279] Recent advances in polymer electrolytes for zinc ion batteries: mechanisms, properties, and perspectives

[280] Electrolytes for rechargeable lithium–air batteries

[281] Beyond garnets, phosphates and phosphosulfides solid electrolytes: new ceramic perspectives for all solid lithium metal batteries

[282] Reddy, M.V., et al., Sulfide and oxide inorganic solid electrolytes for all-solid-state Li batteries: a review.


[283] Review—progress in electrolytes for rechargeable aluminium batteries

[284] Dendrite-Free zinc deposition induced by multifunctional CNT frameworks for stable flexible Zn-Ion batteries

[285] Brief history of early lithium-battery development

[286] Carbon materials as a cathode for aluminum-ion battery

[287] Synthesis and Characterization of Silicon Based Anode Materials

[288] Hybrid silicon-carbon nanostructured composites as superior anodes for lithium ion batteries

[289] High performance air breathing flexible lithium–air battery

[290] A flexible aqueous Al ion rechargeable full battery

[291] From Li-Ion batteries toward na-ion chemistries: challenges and opportunities

[292] Hard carbon anodes: fundamental understanding and commercial perspectives for Na-Ion batteries beyond Li-Ion and K-Ion counterparts

[293] (Invited) a nature-inspired porous electrode for flexible, stretchable supercapacitors and lithium-ion batteries

[294] Waterborne Coatings Market Size, Share & Trends Analysis Report By Resin (Acrylic, PU, Epoxy, Polyester), By Application (Architectural, General Industrial, Marine), By Region, And Segment Forecasts, 2023 2030. Available from: https://www.grandviewresearch.com/industry-analysis/waterborne-coatings-market

[295] Plastic waste upcycling: a sustainable solution for waste management, product development, and circular economy

[296] Closing the carbon loop in the circular plastics economy

[297] Reaching circular economy through circular chemistry: the basis for sustainable development

[298] Bioplastics

[299] Advance of design and application in self-healing anticorrosive coating: a review

[300] Sustainable smart anti-corrosion coating materials derived from vegetable oil derivatives: a review

 

[301] Sustainable secondary-raw materials, natural substances and eco-friendly nanomaterial-based approaches for improved surface performances: an overview of what they are and how they work

[302] Sustainable coatings on metallic alloys as a nowadays challenge

[303] Hopkinson, P., et al., Accelerating the transition towards a net zero NHS: delivering a sustainable and resilient UK healthcare sector. 2022.

[304] Life cycle gaps: interpreting LCA results with a circular economy mindset

[305] Biotoxicity and life cycle assessment of two commercial antifouling coatings in marine systems

[306] Environmental assessment of antimicrobial coatings for packaged fresh milk

[307]

Aqueous anionic polyurethane dispersions from castor oil

[308] Bio-based self-healing coating material derived from renewable castor oil and multifunctional alamine

[309] Sustainable and multifunctional composites of graphene-based natural jute fibers

[310] MWCNTs/CB waterborne conductive smart coating for damage monitoring of composites: design, fabrication, characterization, and verification

[311] Bioplastic materials.

[312] A review on bio-based graphene derived from biomass wastes

[313] Translucent lignin-based omniphobic polyurethane coating with antismudge and UV-blocking dual functionalities

[314] Facile fabrication of fluorine-free slippery antifouling coatings with self-cleaning and anti-microorganism properties

[315] An overview of recycling wastes into graphene derivatives using microwave synthesis; trends and prospects

[316] Sustainable use of cruciferous wastes in nanotechnological applications

[317] A systematic literature review on the conversion of plastic wastes into valuable 2D graphene-based materials

[318] Flash graphene from plastic waste

[319] Flash graphene from rubber waste

[320] Conducting graphene synthesis from electronic waste

[321] Preparation and characterization of biobased graphene from Kraft lignin

[322] Lightweight and flexible reduced graphene oxide/water-borne polyurethane composites with high electrical conductivity and excellent electromagnetic interference shielding performance

[323] Incorporation of carbon nanofillers tunes mechanical and electrical percolation in PHBV: PLA blends

[324] Influence of textile fabrics structures on thermal, UV shielding, and mechanical properties of textile fabrics coated with sustainable coating

[325] Sustainable and multifunctional composites of graphene-based natural jute fibers

[326] Towards Greener and More Sustainable Synthesis of MXenes: a Review

[327] Sustainable MXenes-based membranes for highly energy-efficient separations

[328] Green'synthesis of metals and their oxide nanoparticles: applications for environmental remediation

[329] Solution combustion synthesis: towards a sustainable approach for metal oxides

[330] Life cycle impact assessment of solution combustion synthesis of titanium dioxide nanoparticles and its comparison with more conventional strategies

[331] Application of ZnO nanoparticles in a self-cleaning coating on a metal panel: an assessment of environmental benefits

[332] Sustainable synthesis of Cr7C3, Cr2AlC, and their derived porous carbons in molten salts

Cited by (8)

    Flame-retardant coatings: Recent advances in materials, mechanisms, and multifunctional applications

Extraction of biomolecular polyphenols for nanoparticles fabrication: Mechanistic insights environmental mitigation

Evaluation of different antimicrobial polymeric coatings for food contact surfaces

Advanced risk management software for multi-criteria decision-making in uncertain scenarios

Lignin from Plant-Based Agro-Industrial Biowastes: From Extraction to Sustainable Applications

The Role of Lightweight AI Models in Supporting a Sustainable Transition to Renewable Energy 

 
https://www.sciencedirect.com/science/article/pii/S2352940724005195 

 

 

____________________________________

 

 

____________________________________
____________________________________



Chapter 5: Plastics & Polymer technology 


____________________________________
____________________________________

 

 

 



____________________________________

 

We can see the problems with many consumer items not being able to biodegrade properly. We need new type of sustainable bio-cellulose and silicone.


____________________________________

Scientists Discover New Rock Made From Human Plastic Waste and Ocean Debris

 

06/08/14

Just in time for World Environment Day, Canadian scientists have announced the discovery of a new type of rock made from the scraps of melted plastic waste and ocean debris. According to researchers at the University of Western Ontario, this new material, known as plastiglomerate, is formed when melted plastic waste on beaches mixes with sediment, lava fragments and organic debris. These virtually indestructible plastiglomerates may become part of the Earth’s geologic record forever and could one day act as a sad geological marker for humanity’s impact on the planet.

http://inhabitat.com/scientists-discover-new-rock-made-from-human-plastic-waste-and-ocean-debris/

____________________________________

 

 

Making Plastic from Carbon Dioxide, Water, and Electricity

June 24, 2025
 

https://www.caltech.edu/about/news/making-plastic-from-carbon-dioxide-water-and-electricity

 

____________________________________

Turning poop into plastic at Paris climate talks

 

December 13, 2015 

 

 A small piece of dung was on proud display at global climate-saving talks in Paris, just a few steps away from being transformed into a plastic bottle or fuel for a car.

Along with scraps from slaughterhouses and dinner tables, it is the raw material for an innovative process to turn waste into a range of new products.

"This is the third Industrial Revolution. It changes the world from using oil products to using biomass," Regis Nouaille, founder of biotech startup Afyren, told AFP at the UN conference where 195 nations agreed a historic climate rescue pact.
 

http://phys.org/news/2015-12-poop-plastic-paris-climate.html

____________________________________

  

Eight Million Tons of Plastic Dumped in Ocean Every Year

 

February 13, 2015

 

It's equal to five grocery bags per every foot of coastline around the globe, says new study.

http://news.nationalgeographic.com/news/2015/02/150212-ocean-debris-plastic-garbage-patches-science/

____________________________________

Plastic Water Bottles: Harmful to the Ocean, Air, and You

http://www.algalita.org/plastic-water-bottles-harmful-to-the-ocean-air-and-you/

____________________________________

Plastic Pollution in the World's Oceans: More than 5 Trillion Plastic Pieces Weighing over 250,000 Tons Afloat at Sea

 

December 10, 2014

http://journals.plos.org/plosone/article?id=10.1371/journal.pone.0111913

____________________________________

The Great Plastic Tide

 

2009 

 

http://coastalcare.org/2009/11/plastic-pollution/



____________________________________

This solar water wheel could be the solution to plastic ocean debris

 July 30, 2014

As much as we love highlighting new and interesting technologies, sometimes old technologies prove to be the best. This is definitely the case in Baltimore where a giant water wheel is removing tons of trash every day from the water, keeping it from ending up in the ocean. This centuries-old technology is quickly becoming the best solution yet for keeping plastic out of the oceans.

 http://www.treehugger.com/clean-technology/solar-water-wheel-could-be-solution-plastic-ocean-debris.html



____________________________________




Japanese Scientists Create World’s First Renewable, Bio-Based Polyester


http://www.ecouterre.com/japanese-scientists-create-worlds-first-renewable-bio-based-polyester/

 

 
____________________________________

 

New developments and investments foreseen in bio-based polymer production by 2020 in Europe

http://www.plastemart.com/Plastic-Technical-Article.asp?LiteratureID=1999&Paper=new-developments-investments-in-bio-based-polymer-production-by-2020-in-europe

 Europe’s current position in producing bio-based polymers is limited to a few polymers. However, new developments and investments are foreseen: the first European industrial-scale PLA plant by 2014, the introduction of PET production facilities by 2015, recent developments in the commercialization of bio-based PBT and further advancements in the field of high-value fine chemicals for PA, PUR and thermosets production. Although Europe shows a strong demand for bio-based polymers, production tends to take place elsewhere-largely the consequence of an unfavourable political framework for the industrial material use of biomass.

____________________________________

 

Cellulose-Based Bio- and Nanocomposites: A Review

http://www.hindawi.com/journals/ijps/2011/837875/

Cellulose macro- and nanofibers have gained increasing attention due to the high
strength and stiffness, biodegradability and renewability, and their production and
application in development of composites. Application of cellulose nanofibers for the development of composites is a relatively new research area. Cellulose macro- and nanofibers can be used as reinforcement in composite materials because of enhanced mechanical, thermal, and biodegradation properties of composites. Cellulose fibers are hydrophilic in nature, so it becomes necessary to increase their surface roughness for the development of composites with enhanced properties. In the present paper, we have reviewed the surface modification of cellulose fibers by various methods. Processing methods, properties, and various applications of nanocellulose and cellulosic composites are also discussed in this paper.


____________________________________


Improvement of plant based natural fibers for toughening green composites

http://www.deepdyve.com/lp/elsevier/improvement-of-plant-based-natural-fibers-for-toughening-green-1WjKrnx3tZ

____________________________________

 

ARCHIVED - Lighter, Stronger, "Greener" Plastics

 

2005

For several years, the NRC-IMI team has been perfecting techniques involving the use of clay nanoparticles to create new nanocomposite plastics. Nanocomposites have been proven to dramatically increase the strength of polymer materials. Just last year, NRC-IMI launched a joint industry partnership group focused on nanocomposites to further explore the use of such materials. It is hoped that nanoclays will add critical strength to already lightweight foamed materials. As well, nanoparticles have been shown to enhance the growth of foam cells, a process known as nucleation. In the past year, a NRC-ICPET research team, in collaboration with University of Ottawa, became the second group in the world to publish results on the fundamental interaction of CO2 with nanocomposites - an emerging area of study.

http://www.nrc-cnrc.gc.ca/eng/achievements/highlights/2005/polymer_foams.html




____________________________________

Cellulose Nanopaper – Strong, Light and Green Alternative to Metals

  

August 3, 2015

 New paper-like material made of cellulose is much stronger than metal, and could one day replace it.
Alternative eco-friendly materials that can replace metals are of high demand. The reasons behind this are many, including polluting mining processes, expensive manufacturing of products made of metals, and of course, the need of making everything lighter yet still tough and strong.

 http://www.greenoptimistic.com/cellulose-nanopaper/#.Ve-vFJe-2zk

 

____________________________________

 

A green and efficient method for preparing acetylated cassava stillage residue and the production of all-plant fibre composites

 Cassava stillage residue (CSR), a kind of agro-industrial plant fibres, was directly acetylated and converted into thermoplastic material by mechanical activation-assisted solid phase reaction (MASPR) in a stirring ball mill without the use of organic solvent and additives. As combining mechanical activation and chemical modification in the same equipment, the destruction of hydrogen bonds and crystalline structure of CSR induced by intense milling improved the reactivity of CSR, leading to the effective acetylation of CSR. After acetylation by MASPR, the modified CSRs possessed thermoplasticity, ascribing to the introduction of acetyl groups and the destruction of high crystallinity structure of cellulose. The self-reinforced all-plant fibre composites (APFC) were successfully produced with the modified CSRs as both matrix and reinforcement by hot pressing technology. The direct acetylation of CSR and successful production of APFC suggested that MASPR was a simple, efficient and environmentally friendly method for chemical modification of agro-industrial lignocellulose biomass.



http://www.researchgate.net/publication/264981183_A_green_and_efficient_method_for_preparing_acetylated_cassava_stillage_residue_and_the_production_of_all-plant_fibre_composites

____________________________________

Progress in bio-based plastics and plasticizing modifications

Over the coming few decades bioplastic materials are expected to complement and gradually replace some of the fossil oil based materials. Multidisciplinary research efforts have generated a significant level of technical and commercial success towards these bio-based materials. However, extensive application of these bio-based plastics is still challenged by one or more of their possible inherent limitations, such as poor processability, brittleness, hydrophilicity, poor moisture and gas barrier, inferior compatibility, poor electrical, thermal and physical properties. The incorporation of additives such as plasticizers into the biopolymers is a common practice to improve these inherent limitations. Generally, plasticizers are added to both synthetic and bio-based polymeric materials to impart flexibility, improve toughness, and lower the glass transition temperature. This review introduces the most common bio-based plastics and provides an overview of recent advances in the selection and use of plasticizers, and their effect on the performance of these materials. In addition to plasticizers, we also present a perspective of other emerging techniques of improving the overall performance of bio-based plastics. Although a wide variety of bio-based plastics are under development, this review focuses on plasticizers utilized for the most extensively studied bioplastics including poly(lactic acid), polyhydroxyalkanoates, thermoplastic starch, proteinaceous plastics and cellulose acetates. The ongoing challenge and future potentials of plasticizers for bio-based plastics are also discussed.


 http://www.researchgate.net/publication/264614759_Progress_in_bio-based_plastics_and_plasticizing_modifications

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Effect of biodegradable plasticizers on thermal and mechanical properties of poly(3-hydroxybutyrate)

The effects of biodegradable plasticizers on the thermal and mechanical properties of poly (3-hydroxybutyrate-co-3-hydroxyvalerate) (PHBV) were studied using thermal and mechanical analyses. Soybean oil (SO), epoxidized soybean oil (ESO), dibutyl phthalate (DBP) and triethyl citrate (TEC) were used as plasticizing additives. PHBV/plasticizer blends were prepared by evaporating solvent from blend solutions. The content of plasticizer in the blends was kept at 20wt%. Compatibility of plasticizer with PHBV was examined with differential scanning calorimetry (DSC) and scanning electron microscopy (SEM). DPB and TEC were more effective than soybean oils (SO and ESO) in depression of the glass transition temperatures as well as in increasing the elongation at break and the impact strength of the films. From the thermal and mechanical properties of the plasticized PHBV, it could be concluded that TEC or DBP are better plasticizers than SO and ESO for PHBV.



http://www.researchgate.net/publication/232382906_Effect_of_biodegradable_plasticizers_on_thermal_and_mechanical_properties_of_poly%283-hydroxybutyrate%29

 

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IBM discovers first new class of polymers in decades

 

May 15, 2014

http://www.gizmag.com/ibm-polymer-discovery-plastic/32088/?li_source=LI&li_medium=default-widget

 The IBM polymers consist of two related classes of plastic materials. They’re formed by combining paraformaldehyde and 4,4ʹ-oxydianiline in what’s called a condensation reaction. When heated to 250⁰ C (482⁰ F) the material becomes very strong as covalent bonds form and the solvent is forced out, forming the first of two versions of the polymer. Both versions are highly elastic, resistant to solvents, and are recyclable. One version can even self-heal.

These polymers also show new physical properties. The first version is lightweight, stiff, resistant to cracking, shows more strength than bone, and can also turned into new polymer structures with half again as much strength. However, it is very brittle, like glass. When mixed with carbon nanofibers and heated, it forms an extremely strong, lightweight composite material that is similar to metal, yet has a degree of self-healing when cracked.



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Characteristics of biodegradable polylactide/gelatinized starch films: Effects of starch, plasticizer, and compatibilizer

Polylactide (PLA) blends with 0–40 wt % gelatinized starches (GSs) in the presence of plasticizers and compatibilizer for improving interfacial bonding between two phases were prepared. The effects of compatibilizer, type and amount of starch, including type and concentration of plasticizer on the physical, morphological, thermal, and mechanical properties of these films were investigated. Two types of starch (corn and tapioca) were added as fillers, whereas the glycerol amount was varied from 0 to 35 wt % based on starch content. Polyethylene glycol (PEG400) and propylene glycol (PG) were added as plasticizers at four different amounts (5–20 wt %) based on PLA content, while methylenediphenyl diisocyanate was used as a compatibilizer at 1.25 wt % of GS. The results indicated that the presence of glycerol had no effect on the thermal degradation of GS. For PLA plasticization, the plasticized PLA with PEG400 had better properties than that with PG. Water absorption isotherm of the blend films increased as the amount of starches increased; in contrast, the tensile properties decreased progressively with the addition of the GS content. The blend films with gelatinized corn starch had higher tensile properties than those with gelatinized tapioca starch.

http://onlinelibrary.wiley.com/doi/10.1002/app.36736/abstract

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Porous Biodegradable Starch-Based Polymer: Effects of Plasticizers on the Physical Properties

The effect of the plasticizer content (mixture of water and glycerol) on the cellular structure of the considered material and its influence on the resulting properties, such as mechanical stiffness, are investigated by means of optical microscopy, X-ray diffraction, thermogravimetry and standard mechanical testing. Adding glycerol leads to larger cell walls and smaller pores but it does not significantly affect the elastic tangent modulus and strength under compression for deformations up to 50%; only a tendency to promote elastic recovery is observed.

http://onlinelibrary.wiley.com/doi/10.1002/masy.201300134/abstract



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Handbook of Plasticizers

  

By George Wypych


This book talks about many different types of plasticizers. This includes the simulation of different plasticizers that could be used, in the colonization of space.

Chapter 10.14 Biodegradation in the presence of plasticizers


Chapter 10.15 Crystallization, structure, and orientation of Macromolecules


Chapter 10.17 Plasticizer effect on contact with other materials


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 The Complete Book on Biodegradable Plastics and Polymers (Recent Developments, Properties, Analysis, Materials & Processes)

 By NIIR Board of Consultants & Engineers



2. RECENT DEVELOPMENTS IN THE BIOPOLYMER INDUSTRY

3. RECENT ADVANCES IN SYNTHESIS OF BIOPOLYMERS BY "TRADITIONAL" METHODS

4. POLYMERS, ENVIRONMENTALLY DEGRADABLE


5. SYNTHETIC BIODEGRADABLE POLYMERS AS MEDICAL DEVICES

6. BIOBASED PACKAGING MATERIALS FOR THE FOOD INDUSTRY



 https://books.google.com/books?id=BS-hAgAAQBAJ&pg=PA159&lpg=PA159&dq=biodegradable+plasticizers&source=bl&ots=bSdeUdExnq&sig=zp4tjgZOQ0lgHLNMvXuQzLtYue8&hl=en&sa=X&ei=tUnYVICRPM39yQSKk4KABQ&ved=0CDkQ6AEwBjgU#v=onepage&q=biodegradable%20plasticizers&f=false

 

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 AN INTRODUCTION TO THE APPLICATIONS OF INDUSTRIAL (WHITE) BIOTECHNOLOGY EUROPA BIO's BIOTECHNOLOGY INFORMATION KIT

The soya bean: an important renewable resource

The soya bean has long been used to develop products ranging from foiod and diesel fuels to polymers,fabric softeners, solvents, adhesives, linoleum, rubber substitutes, printing inks, and plastics. Recent advances in recombinant genetic biotechnology have made it possible to alter the lipid composition of soya beans to increase the variety of biohydrocarbons available for industrial applications. Amides, esters and acetates of biohydrocarbons are currently used as plasticisers, blocking/slip agents and mold-release agents for synthetic polymers. Biohydrocarbons linked to amines, alcohols, phosphates and sulfur groups are used as fabric softeners, surfactants, emulsifiers, corrosion inhibitors, anti-static agents, hair conditioners, ink carriers, biodegradable solvents, cosmetic bases and perfumes. In combination with aluminum and magnesium, the soya bean is used to produce greases and marine lubricating materials.

2. Biotechnology in industrial sectors

Various parts of the industry are experimenting with the new tools offered by biotechnology. Of particular interest is the possibility of using biobased resources as feedstocks in the larger volume sectors. While biobased manufacturing will not necessarily always be cleaner, it is certain that wastes from biobased manufacturing will be more compatible with conventional wastewater treatment systems.

Pharmaceuticals

Today, many pharmaceuticals are semi-synthetic molecules, in that part of their structure is synthesised by a living organism and later modified by chemical processing. Thanks to biocatalysis optimised fermentation, and replacement of organic solvents by water, modern biotechnology contributes to cleaner production of such semi-synthetic antibiotics.

 http://www.scribd.com/doc/243514826/Intro-to-the-Applications-of-White-Biotechnology#scribd



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Bio-Based PEF Bottles to Hit Market by 2016

http://www.foodproductdesign.com/news/2013/06/bio-based-pef-bottles-to-hit-market-by-2016.aspx


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ITKE Constructs New ArboSkin Pavilion with 388 Recyclable Bioplastic Pyramids

 

by Lidija Grozdanic, 11/11/13

 http://inhabitat.com/itke-constructs-new-arboskin-pavilion-with-388-recyclable-bioplastic-pyramids/


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Good plastics, bioplastics and greenwashing

 

 2013

 

Plastic is not inert

 

Conventional plastic contains a large number, and sometimes a large proportion, of chemical additives which can be endocrine disruptors, carcinogenic or provoke other toxic reactions and can, in principle, migrate into the environment, though in small quantities. Persistent organic pollutants (POPs), such as pesticides like DDT and polychlorinated biphenyls (PCBs), can attach themselves from the surrounding water to plastic fragments which can be harmful and enter the food chain via marine fauna.


http://www.zerowasteeurope.eu/2013/06/good-plastics-bioplastics-and-greenwashing/


____________________________________

Will Bioplastics Contaminate Conventional Plastics Recycling?

http://www.sustainableplastics.org/bioplastics/issues-with-recycling


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Producing plastic from seaweed

 

August 28th, 2014 

 

 http://phys.org/wire-news/170671262/producing-plastic-from-seaweed.html

____________________________________

The Bioplastic Concept Car: Seaweed

  

April 23, 2014

 http://www.conceptcarseries.com/car-news/the-bioplastic-concept-car-seaweed-by-toyota/

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New strain of seaweed tastes like bacon

 

July 16, 2015

Seaweed is widely considered to be a health food. Bacon, on the other hand ... well, bacon isn't. There may yet be hope for pork belly lovers around the world, however. Scientists at Oregon State University (OSU) have patented a lab-bred strain of dulce seaweed, that they claim has "a strong bacon flavor" when fried.

http://www.gizmag.com/dulce-seaweed-bacon/38503/



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'Mutarium' prototype is the perfect farm for edible plastic-eating fungi

  

December 15th 2014

 Biodegradable plastics exist because traditional ones take between 20 and 1,000 years to break down in the wild, often blocking waterways and killing animals as that all happens. That's why two industrial designers and a group of microbiologists have designed a way to break down plastic -- and create edible mushrooms in the process.

 http://www.engadget.com/2014/12/15/fungi-mutarium-plastic/

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Can mushrooms replace plastic?

As it turns out, they are equally versatile outside of the food world. They can produce packaging, home insulation, fiberboard for furniture, even a surfboard.


 http://www.theguardian.com/sustainable-business/mushrooms-new-plastic-ecovative

 

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Diaper-grown mushrooms to cut down waste

 

September 3, 2014

While their contents might be considered an environmental hazard by many, disposable diapers themselves pose a more significant problem for the environment. According to the EPA, the average baby will work their way through 8,000 of them before they end up in landfill where they'll take centuries to break down. In an effort to reduce the problem, scientists at Mexico's Autonomous Metropolitan University, Azcapotzalco (UAM-A), have turned used diapers to the task of growing mushrooms.

http://www.gizmag.com/diaper-grown-mushrooms/33633/?li_source=LI&li_medium=default-widget

 

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Coffee and mushroom spores make a green plastic alternative

March 31st, 2025

https://www.futurity.org/coffee-grounds-mushrooms-3d-printing-plastic-alternative-3275412/

 

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Tequila waste combined with recycled plastic to form wood substitute

 

January 21, 2015

When the sap from plants such as sugar cane is extracted for commercial use, what's left over is a fibrous material known as bagasse. This is commonly used as biofuel, or is compressed into a wood substitute. Now, Mexican startup Plastinova is using agave bagasse from the tequila industry to make a wood-like material of its own, although it's also incorporating recycled plastic.

 http://www.gizmag.com/agave-bagasse-plastic-wood/35710/?li_source=LI&li_medium=default-widget



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How does Yulex compare with neoprene wetsuits?

Surfers have used wetsuits for decades, with neoprene as their core material. But the paradigm is shifting. Meet Yulex, the natural rubber that promises to revolutionize insulation and the sport.

 

You've probably heard about it. Yulex is the game-changer in the world of wetsuits.

At its core, it's a 100 percent plant-based, renewable, and biodegradable substance.

 

It's not just an alternative to traditional wetsuit materials - it's a leap forward. It is also 100 percent free of petroleum, limestone, and acetylene.

 

Extracted from certified deforestation-free rubber trees, Yulex doesn't just stop at wetsuits.

 

The versatile material is used in footwear, automotive items, bags and accessories, braces and sleeves, yoga gear, biking equipment, and triathlon suits, just to name a few.

 

The partner factories working with Yulex are subject to yearly internal audits.

 

Several surf brands, including Patagonia, Billabong, Slater Designs, VF Corporation, SRFACE, Finisterre, needessentials, Seea, MDNS, and Firewire, have already adopted Yulex in their manufacturing processes.

 

From Arizona to the World

 

The vision behind Yulex - the material - is spearheaded by Jeff Martin, a recognized figure in the natural rubber polymer industry and CEO and co-founder of the Yulex Corporation.

 

It all started in 2000 in the company's Guayule natural rubber farm in Arizona.

 

From there, Yulex pioneered the production of natural rubber latex in the United States.

 

With a legacy of innovative and culture-driven leadership, Martin's drive to increase the use of certified natural rubber is evident in Yulex's initiatives.

 

Today, only about 3 percent of the natural rubber worldwide is certified, but Yulex, with its commitment and partnerships, aims to amplify this figure.

 

As the demand surged, notably from Patagonia, Yulex pivoted to producing foam from the hevea brasiliensis rubber tree, another renewable treasure of nature.

 

Cultivated in Guatemala since the 1940s, hevea trees are first tapped at seven years of age.

 

Properly treated, they can produce rubber latex for the next 30 years.

 

As their yields diminish, the trees are cut and milled.

 

Hevea is a dense hardwood that can be built into furniture or household goods, giving each tree another life after it's felled.

 

New saplings are then spliced onto the stumps.

 

https://www.surfertoday.com/surfing/yulex-vs-neoprene-the-differences-between-wetsuit-materials

 

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Yulex® wetsuit with natural rubber

https://srface.com/pages/yulex-wetsuit

____________________________________

 

Introducing YULASTIC® — A new, natural, and sustainable alternative to elastane

https://www.yulex.com/

 

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MIT Develops Beaver-inspired Furry Wetsuits to Keep Surfers Warm

 

Oct 07, 2016

 

 

MIT engineers have developed rubbery pelts inspired by the fur of beavers and sea otters, which trap pockets of air to keep the animals warm and dry while diving. 

 

MIT researchers looked at beavers to investigate how the small creatures stay warm in the icy-cold water. Now, they’re applying the beaver’s protection to develop a furry wetsuit to keep surfers warm. Beavers most commonly live in Northern areas which experience incredibly cold winter temperatures.

https://scitechdaily.com/new-beaver-inspired-wetsuits-may-help-keep-surfers-warm/

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This Water-Resistant Paper Could Revolutionize Packaging and Replace Plastic

  

January 5, 2025

 

A groundbreaking study showcases the creation of sustainable hydrophobic paper, enhanced by cellulose nanofibres and peptides, presenting a biodegradable alternative to petroleum-based materials, with potential uses in packaging and biomedical devices. 

 

https://scitechdaily.com/this-water-resistant-paper-could-revolutionize-packaging-and-replace-plastic/ 

 

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Scientists Create New Supermaterial That Could Replace Plastic

July 16, 2025

 

Improved bacterial cellulose could help create tougher, greener materials for things we use every day.

 

As plastic waste continues to accumulate across the globe, creating serious environmental challenges, researchers are turning to nature for sustainable solutions. Maksud Rahman, an assistant professor of mechanical and aerospace engineering at the University of Houston, has developed an innovative method for transforming bacterial cellulose, a biodegradable material, into a versatile substance that could serve as a replacement for plastic.

 

https://scitechdaily.com/scientists-create-new-supermaterial-that-could-replace-plastic/

 

____________________________________

 

Learn how PLA Bioplastic can be recycled

 

https://www.youtube.com/watch?v=S_C4x-jjZBc



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Sensor detects toxins leaching from plastic

 

December 10, 2015 

 

 Engineers from Massey University have developed a highly sensitive device able to detect synthetic compounds that leach from plastic food packaging into the contained food or beverage. These kind of compounds are a major health concern worldwide as they have been linked to genetic, developmental and fertility defects in humans.


Dr Asif Zia, together with Professor Subhas Mukhopadhyay, both from the School Engineering and Advanced Technology developed an electrochemical sensing system that is able to rapidly quantify a synthetic compound – di(2-ethylhexyl)phthalate or DEHP for short.

DEHP is used to induce flexibility in the plastic products but, because of its molecular structure, it does not attach itself covalently to the plastic's lattice structure and may leach into the surrounding environment. It is classed as a teratogenic, or malformation causing, compound as well as an endocrine-disrupter, which interferes with the body's natural hormonal system. The World Health Organization refers concentrations of DEHP greater than six parts per billion as hazardous for human health.

http://phys.org/news/2015-12-sensor-toxins-leaching-plastic.html

 

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Self-healing bioplastic – just add water

 

September 2, 2015

Imagine if things like undersea cables or medical implants could simply heal themselves back together if severed – it would certainly be easier than having to go in and fix them. Well, scientists at Pennsylvania State University are bringing such a possibility closer to reality. They've created a moldable polymer that heals itself when exposed to water – and it's based on squid sucker ring teeth.
Led by Prof. Melik Demirel, the researchers started by studying sucker ring teeth collected from squid in various locations around the world. Although the exact composition of the teeth varied between species, it was found that the same proteins which allow them to self-heal were always present

 http://www.gizmag.com/self-healing-bioplastic-squid/39220/?li_source=LI&li_medium=default-widget


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This edible water blob could replace plastic bottles

Mar 27, 2014

 Designers Rodrigo García González, Guillaume Couche and Pierre Paslier call their creation "Ooho," a gelatinous blob that is actually a membrane that encapsulates water like a bladder. When you're thirsty, just puncture the membrane and drink. Or, if you also have an appetite, just pop a bite-sized Ooho in your mouth and chomp down for a burst of hydration. The gooey membrane, made from brown algae and calcium chloride, is edible, hygienic and biodegradable.

http://www.mnn.com/food/beverages/stories/this-edible-water-blob-could-replace-plastic-bottles

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Brazilian Lab Turns Fruits, Veggies Into Edible Plastic

 

 January 14, 2015



BRASILIA, Brazil, January 14, 2015 (ENS) – Imagine putting a pizza in the oven without having to remove the plastic casing that protects the pizza from contamination. The plastic film consists of tomatoes and, when heated, it will become part of the pizza.

This edible plastic has been developed by researchers at the Brazilian Agricultural Research Corporation, Embrapa Instrumentation, a state-owned company affiliated with the Brazilian Ministry of Agriculture.

In fact, the researchers have made edible plastic films from foods such as spinach, papaya and guava as well as tomatoes.


http://ens-newswire.com/2015/01/14/brazilian-lab-turns-fruits-veggies-into-edible-plastic/


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From fungi to furniture: the future of sustainable design?

https://from.ncl.ac.uk/from-fungi-to-furniture-future-of-sustainable-design?utm_source=research-gate&utm_medium=display&utm_campaign=reputation-ranking&utm_term=image&utm_content=bioknit-project

 
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Could spent coffee grounds provide an alternative to plastic packaging?

September 21, 2023

https://www.sdstate.edu/news/2023/09/could-spent-coffee-grounds-provide-alternative-plastic-packaging

 

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Open for Discussion: Goodbye Plastic, Hello Edible Wrappers—or Nothing at all!

WikiCell Designs produces ultra-thin flavored membranes, called WikiCells, that surround liquids or solids shielding them from oxygen, oils, and moisture to extend their shelf life. Unlike Monosol pouches, WikiCells are washable, so the outer container can act like the skin of a fruit. You just wash and eat them.
A WikiCell is made of two sustainable layers. Eat the inner wrapping, compost the shell; no plastic is involved. The inner edible membrane, like a grape skin, is held together by intermolecular electrostatic forces. Positively charged calcium ions bind with alginate, an anionic (negatively charged) polysaccharide from brown algae (Fig. 1). The outer compostable shell is made of the residue from sugarcane crushing.

http://www.acs.org/content/acs/en/education/resources/highschool/chemmatters/past-issues/archive-2012-2013/edible-wrappers.html

 
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A possible replacement for plastic: Spinning bacteria create improved cellulose

 

July 8, 2025 

 

In a world overrun with plastic garbage, causing untold environmental woes, University of Houston assistant professor of mechanical and aerospace engineering, Maksud Rahman, has developed a way to turn bacterial cellulose—a biodegradable material—into a multifunctional material with the potential to replace plastic. 

 

https://phys.org/news/2025-07-plastic-bacteria-cellulose.html

 

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Medical Device Components 2.0: The Trend Towards a Healthier, PVC-Free Alternative

 01 January 2014

System Health

If you aren’t convinced of PVC’s harmful effects in medical devices up until this point, there remains one last detriment to using this insulation powerhouse. A recent study released by Teknor Apex material science company in October 2013 determined that PVC and plasticizers alongside non-PVC components in devices can migrate when they come into contact with each other, resulting in softening, cracks, and other defects in the system. Their study tested ten different types of plasticizers, including DEHP, and determined it may have adverse effects on non-PVC plastics.

http://www.medicaldesignbriefs.com/component/content/article/1105-mdb/features/18924

 
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Scientists Develop Plastic Substitute That Could Fight Ocean Pollution

 

July 29, 2025

 

Plastic pollution continues to pose a major threat to marine ecosystems, with UNESCO reporting that it accounts for 80 percent of all ocean pollution. Each year, an estimated 8 to 10 million metric tons of plastic end up in the sea. In a promising development, researchers from the USC Viterbi School of Engineering have identified a natural substance found in seashells that may help create a safer and more sustainable alternative to conventional plastic.

 

The study is led by Eun Ji Chung, who holds the Dr. Karl Jacob Jr. and Karl Jacob III Early-Career Chair at USC Viterbi. Chung is recognized for her expertise in engineered nanoparticles for medical use. Drawing from her background in biomaterials, she and her research team recently created a new type of biodegradable plastic alternative. By incorporating calcium carbonate, a mineral found in seashells, into poly (1,8-octanediol-co-citrate) (POC), a biodegradable polymer approved by the FDA for orthopedic fixation, the team engineered a material that may help reduce reliance on traditional plastics. The results were published in MRS Communications.

 

https://scitechdaily.com/scientists-develop-plastic-substitute-that-could-fight-ocean-pollution/ 

 

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The 20-Year-Old With a Plan to Rid the Sea of Plastic

  

Sep 24, 2014
 

https://www.youtube.com/watch?v=hmPHBhYaCR4



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Company unlocks secret to making plastic out of air

 

 July 30, 2014

"We're not the first people to have the idea of turning greenhouse gas into plastic," Herrera said. "The thing that was missing was that no one had figured out how to do it cost-effectively."

Here's how it works: Carbon emissions are captured from farms, landfills, and energy facilities and are fed into a 50-foot-tall reactor at Newlight's plant. A bundle of enzymes strips out the carbon and oxygen and rearranges them into a substance they call air carbon.

The product is then melted down and cooled inside tubes and sliced into little plastic pellets that can be molded into anything.

Herrema calls it "a disruptive technology that's gonna change the world."

 http://www.cbsnews.com/news/company-unlocks-secret-to-making-plastic-out-of-air/

 

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Self-healing material can build itself from carbon in the air

 

October 11, 2018

 

 

Taking a page from green plants, new polymer “grows” through a chemical reaction with carbon dioxide.

 

https://news.mit.edu/2018/self-healing-material-carbon-air-1011


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New catalyst paves way for bio-based plastics, chemicals

 

December 11, 2015

 http://phys.org/news/2015-12-catalyst-paves-bio-based-plastics-chemicals.html

 Washington State University researchers have developed a catalyst that easily converts bio-based ethanol to a widely used industrial chemical, paving the way for more environmentally friendly, bio-based plastics and products.

The researchers have published a paper online describing the catalyst in the Journal of the American Chemical Society and have been granted a U.S. patent.

The chemical industry is interested in moving away from fossil fuels to bio-based products to reduce environmental impacts and to meet new regulations for sustainability, said Yong Wang, Voiland Distinguished Professor in the Gene and Linda Voiland School of Chemical Engineering and Bioengineering.

The catalyst works on bio-based ethanol to create isobutene used in plastics and other products.

The industry has traditionally made a widely used chemical called isobutene - used in everything from plastic soda bottles to rubber tires - by superheating crude oil. But in collaboration with the Archer Daniels Midland (ADM) Company, Wang and his colleagues developed a catalyst to convert bio-based ethanol, which is made from corn or other biomass, to isobutene in one easy production step.



____________________________________

 

It is questionable if we should genetically modify animals to make plastic out of the materials from their DNA. We still are not for certain how this type of plastic would react in the wild and with other natural organisms. 

 
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Cheap, biodegradable, biocompatible "Shrilk" is a potential plastic replacement

 

 December 14, 2011



 http://www.gizmag.com/shrilk-bioinspired-material/20858/?li_source=LI&li_medium=default-widget

Web-slinging arachnids already have researchers toiling away looking to replicate the remarkable properties of spider silk. Now spiders, along with their insect and crustacean arthropod cousins, have provided inspiration for a new material that is cheap to produce, biodegradable, and biocompatible. Its creators say the material, dubbed "Shrilk," has the potential to replace plastics in consumer products and could also be used safely in a variety of medical applications, such as suturing wounds or serving as scaffolding for tissue regeneration.
Arthropods have an outer skeleton made up of a composite material called cuticle that consists of layers of a polysaccharide polymer called chitin and protein organized in a laminar, plywood-like structure. In its unmodified form, which can be seen in the body wall of a caterpillar, chitin is translucent, pliable, resilient and quite tough, but arthropods are able to modify its properties to make it tough and rigid, as seen in the body wall of a beetle, or to make it elastic, as seen in arthropod limb joints. Not only does cuticle protect the arthropod's internal components and provide structure for muscles and wings, it does so without adding weight or bulk.

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Plastic Roadways BUSTED!

Feb 14, 2017

https://www.youtube.com/watch?v=Sj_FZduqblo

 
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Rubber meets the road with new ORNL carbon, battery technologies

 

August 27, 2014 

 

Recycled tires could see new life in lithium-ion batteries that provide power to plug-in electric vehicles and store energy produced by wind and solar, say researchers at the Department of Energy's Oak Ridge National Laboratory.
By modifying the microstructural characteristics of carbon black, a substance recovered from discarded tires, a team led by Parans Paranthaman and Amit Naskar is developing a better anode for lithium-ion batteries. An anode is a negatively charged electrode used as a host for storing lithium during charging.

http://phys.org/news/2014-08-rubber-road-ornl-carbon-battery.html#nRlv

 

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New production process makes PLA bioplastic cheaper and greener

 

July 21, 2015


Polylactic acid (PLA) is a biodegradable bioplastic that is already used to produce a variety of everyday items, such as cups, trays, bowls and vegetable wrapping foil. Unfortunately, the current PLA production process is expensive and produces waste. Researchers at the KU Leuven Centre for Surface Chemistry and Catalysis in Belgium have now developed a new production technique that is cheaper and greener and makes PLA a more attractive alternative to petroleum-based plastics.
PLA boasts a number of advantages over petroleum-based plastic. It is one of the few plastics suitable for use in 3D printers, it is biocompatible, making it suitable for medical use, and it biodegrades in a few years in certain environments, and is industrially compostable and recyclable. But when it comes to cost, PLA can't compete with petroleum-based plastics due to the intermediary steps required to produce it.

As its name suggests, lactic acid is a main building block of PLA. This can be obtained by the fermentation of sugar that can be sourced from renewable resources such as corn starch, tapioca and sugarcane.

http://www.gizmag.com/bioplastic-pla-cheaper-production-process/38498/?li_source=LI&li_medium=default-widget

 
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AI helps chemists develop tougher plastics

August 9, 2025

 

Researchers created polymers that are more resistant to tearing by incorporating stress-responsive molecules identified by a machine-learning model.

 

A new strategy for strengthening polymer materials could lead to more durable plastics and cut down on plastic waste, according to researchers at MIT and Duke University.

 

https://nanodigest.in/ai-helps-chemists-develop-tougher-plastics/ 

 

____________________________________

 

MIT Engineers Develop “Impossible” Polymer Material That is 2-Times Stronger Than Steel, But as Light as Plastic

 

February 6, 2022

 

 

MIT chemical engineers have created a new “impossible” material that is stronger than steel and as light as plastic, and can be easily manufactured in large quantities, thanks to a new novel polymerization process. Unlike other polymers that form one-dimensional, spaghetti-like chains, this new material is essentially a two-dimensional polymer capable of being self-assembled into sheets. 

https://www.techeblog.com/mit-impossible-polymer-steel-plastic/

 

____________________________________

 

 

Model tackles key obstacle to efficient plastic recycling

June 24, 2025

https://news.illinois.edu/model-tackles-key-obstacle-to-efficient-plastic-recycling/

 

____________________________________

 

It is debated if we should use natural or synthetic materials for the use of materials in roads. This includes the use of natural vs synthetic rubber, and the impact that this has on the environment. 

 


____________________________________

 

Microplastics in road dust and surrounding environment: Sources, fate and analytical approaches

 

2024

 

https://www.sciencedirect.com/science/article/abs/pii/S2214158824000321 

 

 
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Chapter 6: Conductivity in polymers and rubbers


____________________________________
____________________________________

 

  

 

 



____________________________________

 

Solving mysteries of conductivity in polymers

 

July 15, 2015

Materials known as conjugated polymers have been seen as very promising candidates for electronics applications, including capacitors, photodiodes, sensors, organic light-emitting diodes, and thermoelectric devices. But they've faced one major obstacle: Nobody has been able to explain just how electrical conduction worked in these materials, or to predict how they would behave when used in such devices.

Now researchers at MIT and Brookhaven National Laboratory have explained how electrical charge carriers move in these compounds, potentially opening up further research on such applications. A paper presenting the new findings is being published in the journal Advanced Materials.
 

http://phys.org/news/2015-07-mysteries-polymers.html#jCp

 

____________________________________

 

Switchable Optical Nanoantennas Made From a Conducting Polymer

December 9, 2019

 

Creating switchable plasmons in plastics: Conductive polymer nanoantennas for dynamic organic plasmonics.

 

Researchers in the Organic Photonics and Nano-optics group at the Laboratory of Organic Electronics have developed optical nanoantennas made from a conducting polymer. The antennas can be switched on and off, and will make possible a completely new type of controllable nano-optical components...

 

The researchers have shown that both the diameter and the thickness of the disks determine the frequency of light to which they react. It is thus possible to control this wavelength by changing the geometry of the disk. The thicker the disk, the higher the frequency. They are also hoping that they can increase the range of wavelengths to which the nanoantennas react by changing the polymer used.

 

Another innovation they have explored is the ability to switch the organic nanoantennas on and off, which is difficult with conventional metals. The material manufactured in the laboratory is initially in an oxidized state, and the nanoantennas are switched on.

 

“We have shown that when we reduce the material by exposing it to a vapor, we can switch off the conduction and in this way also the antennas. If we then reoxidize it using, for example, sulphuric acid, it regains its conductivity and the nanoantennas switch on again. This is a relatively slow process at the moment, but we have taken the first steps and shown that it is possible,” says Magnus Jonsson.

 

“While this is basic research, our results make possible a new type of controllable nano-optical components that we believe can be used for many applications.”

https://scitechdaily.com/switchable-optical-nanoantennas-made-from-a-conducting-polymer/

 

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Kekulé's shattered dream: snakes become ladders

 

November 2021

 

The Universities of Bonn and Regensburg create novel molecules that serve as ziplines for energy

 

Researchers from the Universities of Bonn and Regensburg move packets of energy along a molecular ladder made of hundreds of benzene rings. Such polymers can potentially be used to design new displays based on organic light-emitting diodes, or for solar cells. The extraordinary material is now described in the journal Nature Communications.

https://www.uni-bonn.de/en/news/286-2021


____________________________________

 

 

Selective electrified polyethylene upcycling by pore-modulated pyrolysis 

 

22 July 2025

https://www.nature.com/articles/s44286-025-00248-0

 

____________________________________

 

 

Researchers discover new fundamental quantum mechanical property

 

January 6, 2016

Nanotechnologists at the University of Twente research institute MESA+ have discovered a new fundamental property of electrical currents in very small metal circuits. They show how electrons can spread out over the circuit like waves and cause interference effects at places where no electrical current is driven. The geometry of the circuit plays a key role in this so called nonlocal effect. The interference is a direct consequence of the quantum mechanical wave character of electrons and the specific geometry of the circuit. For designers of quantum computers it is an effect to take account of. The results are published in the British journal Scientific Reports.
 

http://phys.org/news/2016-01-fundamental-quantum-mechanical-property.html#jCp



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Natural rubber from the rubber tree can be a sustainable material, if natural rubber is not over-harvested. Many groups have turned to using synthetic rubber to strengthen rubber materials. This type of synthetic rubber can be found in shoes, rubber seals and tires. Synthetic rubber is actually a form of plastic. Many people are concerned with how current synthetic rubber biodegrades in the wild. This includes the added chemicals found in synthetic rubber that have been known to have harmful chemicals. Even when someone tries to handle certain chemicals that make certain types of synthetic rubber, that individual is at risk for absorbing those chemicals through their blood system.


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TOXICOLOGY AND EXPOSURE GUIDELINES

 http://ehs.unl.edu/documents/tox_exposure_guidelines.pdf

"All substances are poisons; there is none which is not a poison.

 The right dose differentiates a poison and a remedy."

This early observation concerning the toxicity of chemicals was made by Paracelsus (1493-1541). The classic connotation of toxicology was "the science of poisons." Since that time, the science has expanded to encompass several disciplines. Toxicology is the study of the interaction between chemical agents and biological systems. While the subject of toxicology is quite complex, it is necessary to understand the basic concepts in order to make logical decisions

concerning the protection of personnel from toxic injuries. Toxicity can be defined as the relative ability of a substance to cause adverse effects in living

organisms. This "relative ability is dependent upon several conditions.

 Routes of Exposure

Skin (or eye) absorption: Skin (dermal) contact can cause effects that are relatively innocuous such as redness or mild dermatitis; more severe effects include destruction of skin tissue or other debilitating conditions. Many chemicals can also cross the skin barrier and be absorbed into the blood system. Once absorbed, they may produce systemic damage to internal organs. The eyes are particularly sensitive to chemicals. Even a short exposure can cause severe effects to the eyes or the substance can be absorbed through the eyes and be transported to other parts of the body causing harmful effects.

  Industrial Toxicants

 Carbon disulfide: Solvent in rayon and rubber industries.

Aniline, used in manufacture of rubber accelerators and antioxidants, resins, and

varnishes.

 Chloroprene, used in production of synthetic rubber.




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Carbon nanotubes replace metal coils for ultra-lightweight electric motors

June 10, 2025

https://phys.org/news/2025-06-carbon-nanotubes-metal-ultra-lightweight.html

 ____________________________________

Ricoh develops energy-generating rubber

May 22, 2015

 http://www.gizmag.com/ricoh-energy-generating-rubber/37590/


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Road to supercapacitors for scrap tires

 

Date:

September 25, 2015

Source:

DOE/Oak Ridge National Laboratory

Summary:

Some of the 300 million tires discarded each year in the United States alone could be used in supercapacitors for vehicles and the electric grid using a technology.

 http://www.sciencedaily.com/releases/2015/09/150925112114.htm

 

____________________________________ 

Simple Leonardo da Vinci experiments combined with advanced theory reveal new atomic-level insights into rubber

May 15, 2015


Read more at: http://phys.org/news/2015-05-simple-leonardo-da-vinci-combined.html#jCp


____________________________________

These Futuristic Car Tires Never Go Flat

 

 14.07.15

http://www.wired.com/2015/07/futuristic-car-tires-never-go-flat/

 

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Researchers discover importance of using right rubber for the job

 May 28th, 2015

http://phys.org/news/2015-05-importance-rubber-job.html#jCp

 The types of surface that scientists and engineers make copies of include skin, teeth, superconductor components in particle accelerators, and various tools, including forensic and archaeological investigations. Surfaces are carefully measured to quantify their roughness and texture, but this can be surprisingly tricky.

The importance of a surface's roughness can be seen in car engines, where if the walls of the engine's cylinders are too smooth they will seize, meaning that the surface needs to be just rough enough to carry a film of lubricant to maintain a smooth piston action.

Techniques have now been developed that can make measurements of ridges, bumps and dimples, down to the nanometre scale - less than 1/100 the thickness of a human hair...

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Reconfiguring hot-hole flux via polarity modulation of p-GaN in plasmonic Schottky architectures

 

7 Mar 2025

 

Abstract

 

While energetic plasmonic hot carriers in nonthermal equilibrium states have pushed the limits of energy conversion efficiency in plasmon-driven photocatalysts and optoelectronics, the acceleration of plasmonic hot-hole flux remains a challenge. Here, we demonstrate an approach to control the generation and injection nature of plasmonic hot holes released from Au nanomesh/p-type GaN (p-GaN) Schottky architecture by modulating polarity of p-GaN. This polarity modulation enhances the flux of hot holes into the plasmonic platform, thereby accelerating Landau damping stemming from increased effective heat capacity of hot electrons in the metallic nanomaterial. We observed that this strategy drives the intensified hot-hole flux even in non–hot spot areas, hinting at the prospect of leveraging the complete potential of the plasmonic device beyond usual hot spots. The polarity modulation in plasmonic Schottky device gives rise to opportunities for manipulating the nature of plasmonic hot carriers for future energy conversion devices.

https://www.science.org/doi/10.1126/sciadv.adu0086

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Rubber Conductivity: A Comprehensive Exploration

2015

https://neuralooms.com/articles/rubber-conductivity-comprehensive-exploration/

 
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CONDUCTING POLYMERS FOR ELECTRONIC APPLICATIONS

2024

https://iipseries.org/assets/docupload/rsl2024E7DBDB251520BED.pdf 

 

____________________________________

 

Recent progress on thermally conductive and electrical insulating rubber composites: Design, processing and applications

2020

https://www.sciencedirect.com/science/article/abs/pii/S2452213920301583

____________________________________

 

Creation of Electrically Conductive Rubbers as a Promising Area in Chemistry and Technology of Processing Elastomers

23 August 2023

https://link.springer.com/article/10.1134/S1995421223020144

____________________________________

 

Electrical Resistivity of Common Polymers and Plastics

https://matmake.com/properties/electrical-resistivity-of-polymers-and-plastics.html

____________________________________

 

Understanding Rubber Conductivity: A Guide to Conductive Rubber Properties

2024

https://www.rubber-tools.com/is-rubber-conductive-guide-in-depth/

____________________________________

 

Top 10 Can rubber conduct electricity China Factory Products Compare

2024

https://www.rubber-tools.com/top-can-rubber-conduct-electricity-china-factory-products-compare/

____________________________________

 

Improving the thermal conductivity of natural rubber by constructing three-dimensional thermal conductivity networks and chemically bonded filler-matrix interaction

2022

https://www.sciencedirect.com/science/article/abs/pii/S092596352200694X

____________________________________

 

Electrical Conductivity of Rubber Composites with Varying Crosslink Density under Cyclic Deformation 

2022

https://www.mdpi.com/2073-4360/14/17/3640

____________________________________

 

Enhanced thermal conductivity of natural rubber based thermal interfacial materials by constructing covalent bonds and three-dimensional networks

2022

https://www.sciencedirect.com/science/article/pii/S1359835X20301676

____________________________________

 

ELECTRICAL AND DIELECTRIC PROPERTIES OF RUBBER

2016

http://polymerphysics.net/pdf/RubChemTech_89_32_2016.pdf

____________________________________

 

Conducting Polymers

Jul 28, 2020

https://www.youtube.com/watch?v=zknwK4aa8os

____________________________________

 

Thermal Conductivity and mechanical properties of Carbon Black Filled Silicone Rubber

2013

https://journals.sagepub.com/doi/epdf/10.1177/096739111402200405

____________________________________

 

 

Tailoring the Thermal Conductivity of Rubber Nanocomposites by Inorganic Systems: Opportunities and Challenges for Their Application in Tires Formulation

2022

Abstract

The development of effective thermally conductive rubber nanocomposites for heat management represents a tricky point for several modern technologies, ranging from electronic devices to the tire industry. Since rubber materials generally exhibit poor thermal transfer, the addition of high loadings of different carbon-based or inorganic thermally conductive fillers is mandatory to achieve satisfactory heat dissipation performance. However, this dramatically alters the mechanical behavior of the final materials, representing a real limitation to their application. Moreover, upon fillers’ incorporation into the polymer matrix, interfacial thermal resistance arises due to differences between the phonon spectra and scattering at the hybrid interface between the phases. Thus, a suitable filler functionalization is required to avoid discontinuities in the thermal transfer. In this challenging scenario, the present review aims at summarizing the most recent efforts to improve the thermal conductivity of rubber nanocomposites by exploiting, in particular, inorganic and hybrid filler systems, focusing on those that may guarantee a viable transfer of lab-scale formulations to technological applicable solutions. The intrinsic relationship among the filler’s loading, structure, morphology, and interfacial features and the heat transfer in the rubber matrix will be explored in depth, with the ambition of providing some methodological tools for a more profitable design of thermally conductive rubber nanocomposites, especially those for the formulation of tires.

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157. The role of filler networking in dynamic properties of filled rubber. 

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159. Improved thermal conductivity and AC dielectric breakdown strength of silicone rubber/BN composites. 

160. Properties of thermally conductive micro and nano size boron nitride reinforced silicon rubber composites. 

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162. Synergistic improvement of thermal conductivities of polyphenylene sulfide composites filled with boron nitride hybrid fillers. 

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164. Boron nitride nanotubes and nanosheets. ACS Nano. 

165. High thermal conductivity of high-quality monolayer boron nitride and its thermal expansion. 

166. Cotton Candy-Templated Fabrication of Three-Dimensional Ceramic Pathway within Polymer Composite for Enhanced Thermal Conductivity. 

167. Self-healing, recoverable epoxy elastomers and their composites with desirable thermal conductivities by incorporating BN fillers via in-situ polymerization. 

168. Highly Thermoconductive, Thermostable, and Super-Flexible Film by Engineering 1D Rigid Rod-Like Aramid Nanofiber/2D Boron Nitride Nanosheets. 

169. An Anisotropically High Thermal Conductive Boron Nitride/Epoxy Composite Based on Nacre-Mimetic 3D Network. 

170. Nitrides for Electronic and Optoelectronic Applications. 

171. Fabrication of Highly Oriented Hexagonal Boron Nitride Nanosheet/Elastomer Nanocomposites with High Thermal Conductivity. 

172. Largely Enhanced Thermal Conductivity and High Dielectric Constant of Poly(vinylidene fluoride)/Boron Nitride Composites Achieved by Adding a Few Carbon Nanotubes. 

173. Improved thermal conductivity and dielectric properties of hBN/PTFE composites via surface treatment by silane coupling agent. 

174. Covalent coupling regulated thermal conductivity of poly(vinyl alcohol)/boron nitride composite film based on silane molecular structure. 

175. Improvement of thermal conductivities for silicone nanocomposite via incorporating poly(Γ-methacryloxypropyltrimethoxy silane) grafted graphene fillers.

176. Enhancing the heat and load transfer efficiency by optimizing the interface of hexagonal boron nitride/elastomer nanocomposites for thermal management applications. 

177. Enhanced Thermal Conductivity in Polymer Nanocomposites via Covalent Functionalization of Boron Nitride Nanotubes with Short Polyethylene Chains for Heat-Transfer Applications.

178. Multilayer Graphene Enables Higher Efficiency in Improving Thermal Conductivities of Graphene/Epoxy Composites. 

179. Mussel-inspired modification of boron nitride for natural rubber composites with high thermal conductivity and low dielectric constant. 

180. Novel nitrile-butadiene rubber composites with enhanced thermal conductivity and high dielectric constant. 

181. Scalable fabrication of thermally conductive elastomer/boron nitride nanosheets composites by slurry compounding. 

182. Fabrication of b-cyclodextrin-crosslinked epoxy polybutadiene/hydroxylated boron nitride nanocomposites with improved mechanical and thermal-conducting properties.

183. Development of ZnO/Al2O3 catalyst for reverse-water-gas-shift reaction of CAMERE (carbon dioxide hydrogenation to form methanol via a reverse-water-gas-shift reaction)

184. Morphology Related Defectiveness in ZnO Luminescence: From Bulk to Nano-Size. 

185. One-step preparation of SnO2 and Pt-doped SnO2 as inverse opal thin films for gas sensing.

186. New insights into the SnO2 sensing mechanism based on the properties of shape controlled tin oxide nanoparticles. Chem. Mater. 

187. Zinc Oxide—From Synthesis to Application: A Review.

188. Titanium dioxide and zinc oxide nanoparticles in sunscreens: Focus on their safety and effectiveness. 

189. The structure, composition, and dimensions of TiO2 and ZnO nanomaterials in commercial sunscreens. 

190. Synthesis, optimization and applications of ZnO/polymer nanocomposites. 

191. International Rubber Study Group—Reports. 

192. Scotti Zinc-Based Curing Activators: New Trends for Reducing Zinc Content in Rubber Vulcanization Process. 

193. Thermal characterization of Al2O3 and ZnO reinforced silicone rubber as thermal pads for heat dissipation purposes. Thermochim. 

194. Thermal conductivity of micro/nano filler filled polymeric composites. 

195. Preparation of nano-zinc oxide/EPDM composites with both good thermal conductivity and mechanical properties. 

196. Catalytic effect of ZnO anchored silica nanoparticles on rubber vulcanization and cross-link formation. 

197. Experimental investigation of thermal conductivity behavior of MWCNTS-Al2O3/ethylene glycol hybrid Nanofluid: Providing new thermal conductivity correlation. 

198. Silver nanoparticles decorated 3D reduced graphene oxides as hybrid filler for enhancing thermal conductivity of polystyrene composites. 

199. Thermally conductive cyanate ester nanocomposites filled with graphene nanosheets and multiwalled carbon nanotubes.

200. High cross-plane thermally conductive hierarchical composite using graphene-coated vertically aligned carbon nanotubes/graphite. 

201. Formation of more efficient thermally conductive pathways due to the synergistic effect of boron nitride and alumina in poly(3-hydroxylbutyrate) 

202. Enhancement of thermal conductivity of carbon fiber-reinforced polymer composite with copper and boron nitride particles. 

203. Electrically insulating ZnOs/ZnOw/silicone rubber nanocomposites with enhanced thermal conductivity and mechanical properties. 

204. Construction of interconnected Al2O3 doped rGO network in natural rubber nanocomposites to achieve significant thermal conductivity and mechanical strength enhancement. 

205. Fabrication of carboxyl nitrile butadiene rubber composites with high dielectric constant and thermal conductivity using Al2O3@PCPA@GO hybrids. 

206. Improved thermal conductivity and electromechanical properties of natural rubber by constructing Al2O3-PDA-Ag hybrid nanoparticles. 

207. Effect of carbon nanotubes decorated with silver nanoparticles as hybrid filler on properties of natural rubber nanocomposites. 

208. Shape controlled spherical (0D) and rod-like (1D) silica nanoparticles in silica/styrene butadiene rubber nanocomposites: Role of the particle morphology on the filler reinforcing effect. 

209. Hybrid filler systems in rubber nanocomposites. 

210. Size-controlled self-assembly of anisotropic sepiolite fibers in rubber nanocomposites. 

211. Effect of mineral fillers on physico-mechanical properties and heat conductivity of carbon black-filled SBR/butadiene rubber composite. 

212. Song S.H. Synergistic Effect of Clay Platelets and Carbon Nanotubes in Styrene-Butadiene Rubber Nanocomposites. 

213. High-performance tires based on graphene coated with Zn-free coupling agents. 

214.Song S.H. Graphene-Silica Hybrids Fillers for Multifunctional Solution Styrene Butadiene Rubber. 

https://pmc.ncbi.nlm.nih.gov/articles/PMC8230438/

 

 
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Chapter 7: Strongest fibers & materials 

 

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____________________________________

 

 

In this chapter we will talk about some of the strongest materials in the world, this includes carbon fiber and graphene. We can even make some of the strongest materials in the world from these sustainable sources. 



____________________________________

3D-printed composite is lighter than wood and stiffer than concrete

  June 27, 2014

 Reseachers at Harvard University have developed a way to 3D-print a cellular composite with record lightness and stiffness using an epoxy resin. This marks the first time that epoxy is used for 3D-printing, and the advance could lead to the development of new lightweight architectures for more efficient wind turbines, faster cars, and lighter airplanes...


 http://www.gizmag.com/3d-printed-strong-composite/32738/?li_source=LI&li_medium=default-widget

____________________________________ 

Engineering The Strongest Foam in the World

 Mar 13, 2015

https://www.youtube.com/watch?v=HfAovWHbO88

____________________________________

Superplasticizer

 http://en.wikipedia.org/wiki/Superplasticizer


____________________________________

Plasticizer

http://en.wikipedia.org/wiki/Plasticizer

Plasticizers (UK: plasticisers) or dispersants are additives that increase the plasticity or fluidity of a material. The dominant applications are for plastics, especially polyvinyl chloride (PVC). The properties of other materials are also improved when blended with plasticizers including concrete, clays, and related products.

Effect on health

 

Substantial concerns have been expressed over the safety of some plasticizers, especially because several ortho-phthalates have been classified as potential endocrine disruptors with some developmental toxicity reported.^[11]

 

Appendix: various specific plasticizers

 

Dicarboxylic/tricarboxylic ester-based plasticizers

 

• Phthalate-based plasticizers are used in situations where good resistance to water and oils is required. Some common phthalate plasticizers are:
  • Bis(2-ethylhexyl) phthalate (DEHP), used in construction materials and medical devices
  • Diisononyl phthalate (DINP), used in flooring materials, found in garden hoses, shoes, toys, and building materials
  • Di-n-butyl phthalate (DnBP, DBP), used for cellulose plastics, food wraps, adhesives, perfumes, and cosmetics - about a third of nail polishes, glosses, enamels, and hardeners contain it, together with some shampoos, sunscreens, skin emollients, and insect repellents
  • Butyl benzyl phthalate (BBzP) is found in vinyl tiles, traffic cones, food conveyor belts, artificial leather, and plastic foams
  • Diisodecyl phthalate (DIDP), used for insulation of wires and cables, car undercoating, shoes, carpets, pool liners
  • Dioctyl phthalate (DOP or DnOP), used in flooring materials, carpets, notebook covers, and high explosives, such as Semtex. Together with DEHP it was the most common plasticizers
  • Diisooctyl phthalate (DIOP), all-purpose plasticizer for polyvinyl chloride, polyvinyl acetate, rubbers, cellulose plastics, and polyurethane.
  • Diethyl phthalate (DEP)
  • Diisobutyl phthalate (DIBP)
  • Di-n-hexyl phthalate, used in flooring materials, tool handles, and automobile parts

 

Trimellitates

 

• Trimellitates are used in automobile interiors and other applications where resistance to high temperature is required. They have extremely low volatility.
  • Trimethyl trimellitate (TMTM)
  • Tri-(2-ethylhexyl) trimellitate (TEHTM-MG)
  • Tri-(n-octyl,n-decyl) trimellitate (ATM)
  • Tri-(heptyl,nonyl) trimellitate (LTM)
  • n-octyl trimellitate (OTM)

 

Adipates, sebacates, maleates

 

• Adipate-based plasticizers are used for low-temperature or resistance to ultraviolet light. Some examples are:
  • Bis(2-ethylhexyl)adipate (DEHA)
  • Dimethyl adipate (DMAD)
  • Monomethyl adipate (MMAD)
  • Dioctyl adipate (DOA)
  • Dibutyl sebacate (DBS)
  • Dibutyl maleate (DBM)
  • Diisobutyl maleate (DIBM)

 

Other plasticizers

 

• Benzoates
• Terephthalates such as Dioctyl terephthalate/DEHT (Eastman Chemical Company Trademark: Eastman 168).
• 1,2-Cyclohexane dicarboxylic acid diisononyl ester (BASF trademark: DINCH).
• Epoxidized vegetable oils
• alkyl sulphonic acid phenyl ester (ASE).
• Sulfonamides
  • N-ethyl toluene sulfonamide (o/p ETSA), ortho and para isomers
  • N-(2-hydroxypropyl) benzene sulfonamide (HP BSA)
  • N-(n-butyl) benzene sulfonamide (BBSA-NBBS)

• Organophosphates
  • Tricresyl phosphate (TCP)
  • Tributyl phosphate (TBP)

• Glycols/polyethers
  • Triethylene glycol dihexanoate (3G6, 3GH)
  • Tetraethylene glycol diheptanoate (4G7)

• Polymeric plasticizers
• Polybutene

 

Bio-based plasticizers

 

Safer plasticizers with better biodegradability and fewer biochemical effects are being developed. Some such plasticizers are:

• Acetylated monoglycerides; these can be used as food additives

• Alkyl citrates, used in food packagings, medical products, cosmetics and children toys
  • Triethyl citrate (TEC)
  • Acetyl triethyl citrate (ATEC), higher boiling point and lower volatility than TEC
  • Tributyl citrate (TBC)
  • Acetyl tributyl citrate (ATBC), compatible with PVC and vinyl chloride copolymers
  • Trioctyl citrate (TOC), also used for gums and controlled release medicines
  • Acetyl trioctyl citrate (ATOC), also used for printing ink
  • Trihexyl citrate (THC), compatible with PVC, also used for controlled release medicines
  • Acetyl trihexyl citrate (ATHC), compatible with PVC
  • Butyryl trihexyl citrate (BTHC, trihexyl o-butyryl citrate), compatible with PVC
  • Trimethyl citrate (TMC), compatible with PVC

 

Plasticizers for energetic materials

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How products are made: Rope


 http://www.madehow.com/Volume-2/Rope.html#ixzz3guBY88YM


 Although the origin of rope is unknown, the Egyptians were the first people to develop special tools to make rope. Egyptian rope dates back to 4000 to 3500 B.C. and was generally made of water reed fibers. Other Egyptian rope was made from the fibers of date palms, flax, grass, papyrus, leather, or camel hair. The use of such ropes pulled by thousands of slaves allowed the Egyptians to move the heavy stones required to build the pyramids. By about 2800 B.C. , rope made of hemp fibers was in use in China.

Raw Materials

 

Rope may be made either from natural fibers, which have been processed to allow them to be easily formed into yarn, or from synthetic materials, which have been spun into fibers or extruded into long filaments.

Natural fibers include hemp, sisal, cotton, flax, and jute. Another natural material is called manila hemp, but it is actually the fibers from a banana plant. Sisal was used extensively to make twine, but synthetic materials are replacing it. Manila rope is still used by traditionalists, but it can rot from the inside, thus losing its strength without giving any outward indication.

Synthetic fibers include nylon, polyester, polypropylene and aramid. Polypropylene costs the least, floats on water, and does not stretch appreciably. For these reasons it makes a good water ski tow rope. Nylon is moderately expensive, fairly strong, and has quite a bit of stretch. It makes a good mooring and docking line for boats because of its ability to give slightly, yet hold. Aramid is the strongest, but is also very expensive. Nylon and polyester may be spun into fibers about 4-10 inches (10-25 cm) long. Ropes made from spun synthetic fibers feel fuzzy and are not as strong as ropes made from long, continuous filaments. Some ropes use two different synthetic materials to achieve a combination of high strength and low cost or high strength and smooth surface finish.
Wire rope may be made from iron or steel wires. This is commonly referred to as cable and is used in bridges, elevators, and cranes. It is made by a different process than fiber or filament ropes. 


____________________________________

 

Difference Between Synthetic & Natural Fiber Rope

Environmental Effects

    Synthetic rope is created using plastics with dangerous chemical byproducts, while natural fiber ropes are woven from jute, sisal, and, hemp--all renewable and biodegradable resources with no chemical byproduct.


http://www.ehow.com/facts_5669626_difference-synthetic-natural-fiber-rope.html#ixzz2cL95eMcQ


____________________________________

 

Scientists are concerned with the use of genetically modified bacteria, this bacteria can be used to heal structures such as rope and concrete.


____________________________________ 

The 'living concrete' that can heal itself

 

May 14, 2015

http://www.cnn.com/2015/05/14/tech/bioconcrete-delft-jonkers/

- The bioconcrete is mixed just like regular concrete, but with an extra ingredient -- the "healing agent." It remains intact during mixing, only dissolving and becoming active if the concrete cracks and water gets in.

Jonkers, a microbiologist, began working on it in 2006, when a concrete technologist asked him if it would be possible to use bacteria to make self-healing concrete.

It took Jonkers three years to crack the problem -- but there were some tricky challenges to overcome.

"You need bacteria that can survive the harsh environment of concrete," says Jonkers. "It's a rock-like, stone-like material, very dry."

Concrete is extremely alkaline and the "healing" bacteria must wait dormant for years before being activated by water.

Jonkers chose bacillus bacteria for the job, because they thrive in alkaline conditions and produce spores that can survive for decades without food or oxygen.

"The next challenge was not only to have the bacteria active in concrete, but also to make them produce repair material for the concrete -- and that is limestone," Jonkers explains.

In order to produce limestone the bacilli need a food source. Sugar was one option, but adding sugar to the mix would create soft, weak, concrete.

In the end, Jonkers chose calcium lactate, setting the bacteria and calcium lactate into capsules made from biodegradable plastic and adding the capsules to the wet concrete mix.

When cracks eventually begin to form in the concrete, water enters and open the capsules.

The bacteria then germinate, multiply and feed on the lactate, and in doing so they combine the calcium with carbonate ions to form calcite, or limestone, which closes up the cracks.

Now Jonkers hopes his concrete could be the start of a new age of biological buildings.

 

____________________________________

  

Many people want an environmentally friendly version of rope with high tensile strength. 

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Ultimate tensile strength

http://en.wikipedia.org/wiki/Tensile_strength

Ultimate tensile strength (UTS), often shortened to tensile strength (TS) or ultimate strength, is the maximum stress that a material can withstand while being stretched or pulled before failing or breaking. Tensile strength is distinct from compressive strength.

Typical tensile strengths

Ultimate strength (MPa)

Epoxy adhesive

-

12 - 30

Human hair

380

Bone (limb)

130

Wood, pine (parallel to grain)

40

Bamboo 350-500

Steel, structural ASTM A36 steel

-

400-550

Steel, Micro-Melt 10 Tough Treated Tool (AISI A11)

5205

First carbon nanotube ropes      3600
Carbon nanotube - 11000-63000
Carbon fiber    1600 for Laminate, 4137 for fiber alone
Boron Nitride Nanotube - 33000
Silicon, monocrystalline (m-Si) - 7000
Basalt fiber   4840

Diamond

2800

Graphene

130000

Boron nitride nanotube

33000

UHMWPE fibers (Dyneema or Spectra)      2300-3500
Aramid (Kevlar or Twaron) - 3757
Polypropylene   19.7-80
Polyester resin (unreinforced) 55
Nylon, type 6/6 - 75

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Study shows how calcium carbonate forms composites to make strong materials such as in shells and pearls

January 8, 2016

Seashells and lobster claws are hard to break, but chalk is soft enough to draw on sidewalks. Though all three are made of calcium carbonate crystals, the hard materials include clumps of soft biological matter that make them much stronger. A study today in Nature Communications reveals how soft clumps get into crystals and endow them with remarkable strength.


http://phys.org/news/2016-01-calcium-carbonate-composites-strong-materials.html#nRlv

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Carbyne is stronger than any known material

 

August 20, 2013

A paper on Arxiv presents a detailed look at the properties of carbyne, stronger than graphene and diamond, a true supermaterial. The paper is titled, "Carbyne from first principles: Chain of C atoms, a nanorod or a nanorope?" Authors are Mingjie Liu, Vasilii I. Artyukhov, Hoonkyung Lee, Fangbo Xu, and Boris I. Yakobson, from Rice University, in Houston, from the departments of mechanical engineering and materials science, chemistry, and the Smalley Institute for Nanoscale Science and Technology. They have calculated the properties of carbyne. Described as a chain of carbon atoms that are linked by alternate triple and single bonds or by consecutive double bonds, carbyne is of special interest, chemists find, because it is stronger, and stiffer than anything that they have seen before. The discovery of carbyne is not entirely new. Explorations of carbyne have their own history.

http://phys.org/news/2013-08-carbyne-stronger-material.html


____________________________________

 

 

Theorists calculate atom-thick carbyne chains may be strongest material ever

  

Oct 09, 2013

https://scitechdaily.com/atom-thick-carbyne-nanorods-may-strongest-material-ever/

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Russian Scientists Synthesize a New Ultra-Hard Material

 

May 13, 2022

 

Russian scientists have synthesized a new ultra-hard material containing scandium and carbon. It consists of polymerized fullerene molecules with scandium and carbon atoms inside. 

 
https://scitechdaily.com/russian-scientists-synthesize-a-new-ultra-hard-material/

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Artificial graphene could outperform the real thing

 

February 14, 2014



 Graphene is truly a 21st-century wonder material, finding use in everything from solar cells to batteries to tiny antennas. Now, however, a group of European research institutes have joined forces to create a graphene knock-off, that could prove to be even more versatile.

Conventional graphene takes the form of a one-atom-thick sheet of carbon atoms, linked together in a honeycomb pattern. Along with being transparent and conductive, it is also both the world's thinnest material, and the strongest.

The artificial graphene has the same honeycomb structure, but is made from nanometer-thick semiconductor crystals instead of carbon atoms. The chemical makeup, size and shape of those crystals can be tweaked, essentially custom-tuning the properties of the material to the desired application.

It could conceivably be used in many of the same places in which graphene is currently utilized, but with even better performance. According to project partner the University of Luxembourg, “'Artificial graphene' should lead to faster, smaller and lighter electronic and optical devices of all kinds, including higher performance photovoltaic cells, lasers or LED lighting."

http://www.gizmag.com/artificial-graphene/30845/?li_source=LI&li_medium=default-widget

 
 
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MIT has a new method for producing large quantities of graphene

May 21, 2015

(The new technique involves wrapping a substrate around an inner tube and passing gas through an outer tube).

http://www.gizmag.com/mit-graphene-large-quantities/37635/




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For faster, larger graphene add a liquid layer

 

July 15, 2015 

 

 

Millimetre-sized crystals of high-quality graphene can be made in minutes instead of hours using a new scalable technique, Oxford University researchers have demonstrated.In just 15 minutes the method can produce large graphene crystals around 2-3 millimetres in size that it would take up to 19 hours to produce using current chemical vapour deposition (CVD) techniques in which carbon in gas reacts with, for example, copper to form graphene.

 

Graphene promises to be a 'wonder material' for building new technologies because of its combination of strength, flexibility, electrical properties, and chemical resistance. But this promise will only be realised if it can be produced cost-effectively on a commercial scale.
 

http://phys.org/news/2015-07-faster-larger-graphene-liquid-layer.html#jCp


____________________________________

Unexpected catalytic activity of nanorippled graphene

March 13, 2023

 

Significance

 

Graphene, an isolated atomic plane of graphite, is generally expected to inherit most of graphite’s properties. These expectations are reported to be wrong as far as chemical activity of the two materials is concerned. Indeed, graphite is one of the most inert materials known in nature. In contrast, graphene is shown here to dissociate molecular hydrogen as strongly as the best catalysts known for this reaction. This is attributed to the fact that graphene monolayers are not flat (as within graphite) but unavoidably have nanoscale ripples that serve as active sites for hydrogen splitting. The results have implications for all two-dimensional (2D) materials that being inherently nonflat may exhibit chemical and catalytic properties very different from their bulk counterparts.

 

Abstract

 

Graphite is one of the most chemically inert materials. Its elementary constituent, monolayer graphene, is generally expected to inherit most of the parent material’s properties including chemical inertness. Here, we show that, unlike graphite, defect-free monolayer graphene exhibits a strong activity with respect to splitting molecular hydrogen, which is comparable to that of metallic and other known catalysts for this reaction. We attribute the unexpected catalytic activity to surface corrugations (nanoscale ripples), a conclusion supported by theory. Nanoripples are likely to play a role in other chemical reactions involving graphene and, because nanorippling is inherent to atomically thin crystals, can be important for two-dimensional (2D) materials in general.

 

 https://www.pnas.org/doi/10.1073/pnas.2300481120

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Breaking the surface: How damage reshapes ripples in graphene

 

March 7, 2025

 

Scientists discover how defects in the surface of two-dimensional sheets alter ripple effects, even freezing the sheet's motion altogether

 

Rippling is a crucial property of 2D materials and influences strength, conductivity, chemical activity and fluid interactions. Understanding the relationship between rippling and defects is essential for key technologies such as flexible electronics, energy storage, catalysis and nanofluidics. The research is published in PNAS.

 

Dr Fabian Thiemann, the first author on this paper, started this research during his PhD between UCL, the University of Cambridge and Imperial College London, and is now a Research Scientist at IBM.

https://www.sciencedaily.com/releases/2025/03/250303141638.htm

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High-efficiency, semi-transparent perovskite/graphene solar cells created at low cost

September 11, 2015

With the continued rise in the uptake of solar cells, consumers are now looking at less obtrusive ways to incorporate these in buildings and vehicles. Transparent or semi-transparent cells provide greater flexibility and visual appeal than standard, opaque silicon solar cells, however their relatively high-cost and poor efficiencies have meant that their adoption has been slow. To help remedy this, researchers working at the Hong Kong Polytechnic University (PolyU) have created semi-transparent, efficient, low-cost perovskite solar cells with graphene electrodes.

http://www.gizmag.com/transparent-perovskite-solar-cells-graphene-electrodes/39349/?li_source=LI&li_medium=default-widget

 

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Conductive graphene yarn is lighter and stretchier than copper wire

 

June 23, 2014

 

 

The researchers started by chemically exfoliating flakes of graphene from a block of graphite. Those flakes were then mixed with water, and that mixture was concentrated into a slurry using a centrifuge. That slurry was then spread across a plate and allowed to dry, forming into a thin transparent film of graphene oxide.

The film was subsequently peeled off the plate and cut into narrow strips, those strips in turn getting wound together using an automatic fiber scroller.

The resulting yarn can be knotted and stretched without fracturing, and is said to be much stronger than other types of carbon fibers – this quality could be due to the presence of tiny air pockets within it.

Removing oxygen from the material boosts its electrical conductivity, and adding silver nanorods to it in the film-fabricating stage could reportedly boost that conductivity further, to the point of matching that of copper. Its stretchability and lighter weight, however, could make it a better alternative in many applications.

 

http://www.gizmag.com/stretchable-graphene-yarn/32657/?li_source=LI&li_medium=default-widget

 
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New Carbon Nanotube Yarn Harvests Mechanical Energy

 

Jan. 26, 2023

 

Twistrons, made from spun carbon nanotubes (CNTs), convert mechanical movement into electricity. Scanning electron microscope images show how UT Dallas researchers made a new kind of twistron by intertwining three individual strands of spun carbon nanotube fibers to make a single yarn, similar to the way conventional yarns used in textiles are constructed. A previous version of a harvester (right) was made by coiling the CNT fibers. The scale bars indicate 100 micrometers.

 

Nanotechnology researchers at The University of Texas at Dallas have made novel carbon nanotube yarns that convert mechanical movement into electricity more effectively than other material-based energy harvesters.

 

In a study published Jan. 26 in Nature Energy, UT Dallas researchers and their collaborators describe improvements to high-tech yarns they invented called “twistrons,” which generate electricity when stretched or twisted. Their new version is constructed much like traditional wool or cotton yarns.

 

Twistrons sewn into textiles can sense and harvest human motion; when deployed in salt water, twistrons can harvest energy from the movement of ocean waves; and twistrons can even charge supercapacitors.

 

First described by UTD researchers in a study published in 2017 in the journal Science, twistrons are constructed from carbon nanotubes (CNTs), which are hollow cylinders of carbon 10,000 times smaller in diameter than a human hair. To make twistrons, the nanotubes are twist-spun into high-strength, lightweight fibers, or yarns, into which electrolytes can also be incorporated. 

https://news.utdallas.edu/science-technology/carbon-nanotube-yarn-2023/

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Caltech engineers have developed an unusually hard new material

 

March 27, 2023

 

 Complex materials, constructed from polymers, exhibit tensile toughness far superior to uncomplicated but structurally identical materials, including materials in which individual strands are intertwined rather than knotted.

 

Caltech engineers have made a major breakthrough in the field of nano- and nano-engineered materials by creating a new material consisting of many interconnected infinitesimal nodes.

 

Compared to materials that are structurally similar but do not interlock, the presence of knots in this new material greatly enhances its durability by enabling it to absorb more energy and deform more before returning to its original shape without any damage. These complex new materials may find applications in biomedicine as well as in aerospace applications because of their robustness, potential biocompatibility, and high deformability.

https://www.electriccitymagazine.ca/caltech-engineers-have-developed-an-unusually-hard-new-material/

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New technique builds super-hard metals from nanoparticles

 

 January 22, 2021

 

Brown University researchers have shown a way to make bulk metals by smashing tiny metal nanoparticles together, which allows for customized grain structures and improved mechanical and other properties.

https://www.brown.edu/news/2021-01-22/metals

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Graphene could find use in lightweight ballistic body armor

 

December 1st, 2014

While graphene is already known for being the world's strongest material, most studies have focused on its tensile strength – that's the maximum stress that it can withstand while being pulled or stretched, before failing. According to studies conducted at Houston's Rice University, however, its ability to absorb sudden impacts hadn't previously been thoroughly explored. As it turns out, the material is 10 times better than steel at dissipating kinetic energy. That could make it an excellent choice for lightweight ballistic body armor.

http://www.gizmag.com/graphene-bulletproof-armor/35004/?li_source=LI&li_medium=default-widget




____________________________________

 

Graphene used to rust-proof steel

 

May 29, 2012


Hexavalent chromium compounds are a key ingredient in coatings used to rust-proof steel. They also happen to be carcinogenic. Researchers, therefore, have been looking for non-toxic alternatives that could be used to keep steel items from corroding. Recently, scientists from the University at Buffalo announced that they have developed such a substance. It’s a varnish that incorporates graphene, the one-atom-thick carbon sheeting material that is the thinnest and strongest substance known to exist.

http://www.gizmag.com/graphene-anti-rust-coating/22731/?li_source=LI&li_medium=default-widget


____________________________________

 

 

Graphene shown to safely interact with neurons in the brain

 

January 29, 2016 

 

 Researchers have successfully demonstrated how it is possible to interface graphene - a two-dimensional form of carbon - with neurons, or nerve cells, while maintaining the integrity of these vital cells. The work may be used to build graphene-based electrodes that can safely be implanted in the brain, offering promise for the restoration of sensory functions for amputee or paralysed patients, or for individuals with motor disorders such as epilepsy or Parkinson's disease.

http://phys.org/news/2016-01-graphene-shown-safely-interact-neurons.html

 

____________________________________ 

A new way to make higher quality bilayer graphene

 

February 8, 2016

 A team of researchers with members from institutions in the U.S., Korea and China has developed a new way to make bilayer graphene that is higher in quality than that produced through any other known process. In their paper published in Nature Nanotechnology, the team describes the technique they developed and the possible uses for the bilayer graphene that is produced.

Graphene is, of course, a flat material made from just single carbon atoms; it forms in a honeycomb pattern and has been found to have excellent electrical properties—one hindrance to using graphene in many applications has been the lack of a bandgap. That hindrance was partially overcome back in 2009 when a team working in the U.S. found that creating two layers of graphene bonded together and then applying electricity could cause a bandgap to occur. Since that time, researchers have been looking for ways to create such bilayer graphene in a way that could be commercialized. In this latest effort, the researchers report on a new technique they have developed that they claim produces the highest quality bilayer graphene yet.

 http://phys.org/news/2016-02-higher-quality-bilayer-graphene.html


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2D self-assembling semiconductor could beat out graphene

May 2, 2014

Graphene may be talked about as the future wonder material (and for that matter, the present one), but it has one critical deficiency. It lacks a natural bandgap, the physical trait that puts the “semi” in “semiconductor," so it has to be doped to become effective. Enter Ni3(2,3,6,7,10,11-hexaiminotriphenylene)2 ... well, you can refer to it as a metal-organic graphene analogue for now. In addition to having a natural band gap, it’s able to self-assemble and represents a whole family of compounds that’s exciting to researchers for its novel properties.

Nickel (the metal) and HITP (the organic compound) are represented in the diagram at the top of the page, with nickel colored in green, amino groups in purple, and carbon rings in grey. The amino groups in the carbon rings are attracted to the nickel, and because of the symmetry and geometry in HITP, the overall organometallic complex almost has a fractal nature that allows this new semiconductor to self-organize perfectly. A band gap is created in the “hole” where electrons aren’t, a space that's just about 2 nm across.

http://www.gizmag.com/2d-self-assembling-semiconductor-graphene/31879/?li_source=LI&li_medium=default-widget

 
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New alloy claimed to have higher strength-to-weight ratio than any other metal

 December 11, 2014

 When it comes to metal that's being used in the automotive or aerospace industries, the higher its strength-to-weight ratio, the better. With that in mind, researchers from North Carolina State University and Qatar University have developed a new alloy that reportedly has a low density similar to that of aluminum, but that's stronger than titanium.

 http://www.gizmag.com/high-entropy-alloy-strength-to-weight/35170/


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 6 of the lightest and strongest materials on Earth


Mar 18, 2017

https://inhabitat.com/6-of-the-lightest-and-strongest-materials-on-earth/


3D Graphene
Carbyne
Aerographite
Aerographene
Metallic microlattice
Limpet teeth



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World's lightest solid material, known as 'frozen smoke', gets even lighter

 

January 13, 2011

Researchers have created a new aerogel that boasts amazing strength and an incredibly large surface area. Nicknamed ‘frozen smoke’ due to its translucent appearance, aerogels are manufactured materials derived from a gel in which the liquid component of the gel has been replaced with a gas, resulting in a material renowned as the world’s lightest solid material. The new so-called “multiwalled carbon nanotube (MCNT) aerogel” could be used in sensors to detect pollutants and toxic substances, chemical reactors, and electronics components.

Although aerogels have been fabricated from silica, metal oxides, polymers, and carbon-based materials and are already used in thermal insulation in windows and buildings, tennis racquets, sponges to clean up oil spills, and other products, few scientists have succeeded in making aerogels from carbon nanotubes.

The researchers were able to succeed where so many before them had failed using a wet gel of well-dispersed pristine MWCNTs. After removing the liquid component from the MWCNT wet gel, they were able to create the lightest ever free-standing MWCNT aerogel monolith with a density of 4 mg/cm3.

MWCNT aerogels infused with a plastic material are flexible, like a spring that can be stretched thousands of times, and if the nanotubes in a one-ounce cube were unraveled and placed side-to-side and end-to-end, they would carpet three football fields. The MWCNT aerogels are also excellent conductors of electricity, which is what makes them ideal for sensing applications and offers great potential for their use in electronics components.

 http://www.gizmag.com/worlds-lightest-solid-material-gets-even-lighter/17588/?li_source=LI&li_medium=default-widget

 

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Aerographite claims title of World's Lightest Solid Material

July 12, 2012

http://www.gizmag.com/aerographite-worlds-lightest-material/23295/?li_source=LI&li_medium=default-widget

While they were each once hailed as the lightest solid material ever made, metallic microlattice and aerogel have now been moved back to second and third place (respectively), with aerographite taking the crown. Developed by a team from the Technical University of Hamburg and Germany’s University of Kiel, the material is composed of 99.99 percent air, along with a three-dimensional network of porous carbon nanotubes that were grown into each other.

Aerographite has a density of less than 0.2 milligrams per cubic centimeter, which allows it be compressed by a factor of 1,000, then subsequently spring back to its original state. Despite its extremely low density, it is black and optically-opaque in appearance. By contrast, the density of metallic microlattice sits at 0.9 mg per cubic centimeter.

The scientists discovered the sponge-like material when they were researching three-dimensionally cross-linked carbon structures. It is reportedly much more robust than the relatively fragile aerogel, being able to withstand at least 35 times as much mechanical force for its density. It is grown in a one-step process using zinc oxide templates, which allow blocks of the material to be created in various shapes, in sizes as large as several cubic centimeters.




____________________________________

 

Graphene aerogel takes world’s lightest material crown

 

March 24, 2013

Not even a year after it claimed the title of the world’s lightest material, aerographite has been knocked off its crown by a new aerogel made from graphene. Created by a research team from China’s Zhejiang University in the Department of Polymer Science and Engineering lab headed by Professor Gao Chao, the ultra-light aerogel has a density lower than that of helium and just twice that of hydrogen.

Although first created in 1931 by American scientist and chemical engineer, Samuel Stephens Kistler, aerogels have recently become a hotly contested area of scientific research. A “multiwalled carbon nanotube (MCNT) aerogel” dubbed “frozen smoke” with a density of 4 mg/cm³ lost its world’s lightest material title in 2011 to a micro-lattice material with a density of 0.9 mg/cm³. Less than a year later, aerographite claimed the crown with its density of 0.18 mg/cm³.

Now a new title-holder has been crowned, with the graphene aerogel created by Gao and his team boasting a density of just 0.16 mg/cm³. To create the record-setting material, Gao and his team turned to the wonder material du jour – graphene. Building on experience in developing macroscopic graphene materials, including one-dimensional graphene fibers and two-dimensional graphene films, the team decided to add another dimension and make a three-dimensional porous material out of graphene in an attempt to claim the record.

Instead of the sol-gel method and template-oriented methods generally used to create aerogels, Gao and his team used a new freeze-drying method that involved freeze-drying solutions of carbon nanotubes and graphene to create a carbon sponge that can be arbitrarily adjusted to any shape.

http://www.gizmag.com/graphene-aerogel-worlds-lightest/26784/?li_source=LI&li_medium=default-widget

 


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Newly developed metallic "micro-lattice" material is world's lightest

 

November 17, 2011 

 

Researchers have created a new metallic material that they claim is the world's lightest solid material. With a density of just 0.9 mg/cm3 the material is around 100 times lighter than Styrofoam and lighter than the "multiwalled carbon nanotube (MCNT) aerogel" - also dubbed "frozen smoke" - with a density of 4 mg/cm3 that we looked at earlier this year. Despite being 99.99 percent open volume, the new material boasts impressive strength and energy absorption, making it potentially useful for a range of applications.
The 0.01 percent of the material that isn't air consists of a micro-lattice of interconnected hollow nickel-phosphorous tubes with a wall thickness of 100 nanometers - or 1,000 times thinner than a human hair. These tubes are angled to connect at nodes to form repeating, three-dimensional asterisk-like cells.

 

http://www.gizmag.com/ultralight-micro-lattice-material/20537/?li_source=LI&li_medium=default-widget

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Microstructured materials as strong as steel yet less dense than water

 

April 14, 2014

Researchers in Germany have developed a lightweight, high-strength material inspired by the framework structure of bones and wood and the shell structure of bees' honeycombs. Created using 3D laser polymer printing combined with a ceramic coating, the material is less dense than water but, relative to its size, boasts strength comparable to high-performance steel or aluminum.
Although inspired by nature, the polymer microarchitecture produced by a team at the Karlsruhe Institute of Technology (KIT) outperforms its natural counterparts in terms of strength/density ratio. The underlying structure was produced using a process of 3D laser lithography or polymer printing and hardening.
A number of structures were tested, including triangular, hexagonal and honeycomb. These were then coated by gas deposition to provide extra strength, with coatings of a ceramic material and alumina both tested. The polymer structure measured roughly 50 µm long, wide, and high, while various coating thicknesses were tested ranging from 10 nm to 200 nm.
It was found that a honeycomb polymer structure with an alumina coating of 50 nm yielded the highest stability to density ratio. This microarchitecture outperformed the triangular and hexagonal counterparts produced and tested, while no additional strength was achieved after a coating thickness of 50 nm of alumina was exceeded. This optimized honeycomb structure failed at a pressure of 28 kg/mm², yet only had a density of 810 kg/m³, which the team says exceeds the stability/density ratio of bones, massive steel or aluminum.
"The novel lightweight construction materials resemble the framework structure of a half-timbered house with horizontal, vertical, and diagonal struts,” said study co-author Jens Bauer. "Our beams, however, are only 10 µm in size.”
The team says microstructured materials are often used for insulation or as shock absorbers, and that such open-pore materials can be used as filters in the chemical industry.


 http://www.gizmag.com/microstructured-lightweight-construction-material/31339/?li_source=LI&li_medium=default-widget

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New materials developed that are as light as aerogel, yet 10,000 times stronger

 

June 22, 2014

http://www.gizmag.com/llnl-ultralight-metamaterial/32589/?li_source=LI&li_medium=default-widget

Imagine materials strong enough to use in building airplanes or motor cars, yet are literally lighter than air. Soon, that may not be so hard to do because a team of researchers from MIT and Lawrence Livermore National Laboratory (LLNL) have developed new ultra-lightweight materials that are as light as aerogel, but 10,000 times stiffer, and may one day revolutionize aerospace and automotive designs.

Aerogels are incredibly light, so light that the record holder, aerographene, boasts a density of just 0.16 mg/cm³. Currently, aerogels are used for insulation, tennis racquets, as a means of controlling oil spills, and were used on the NASA Stardust mission to collect samples from a comet’s tail. Unfortunately, despite its seemingly ephemeral nature, its very much a solid and will shatter if pressed hard enough, so its use is limited.
The new materials developed by the MIT/LLNL team aren't aerogels, but are metamaterials. That is, artificial materials with properties that aren't found in nature. The idea is to structure it, so that it has the lightness of aerogel, but is much stronger. The strength of the new materials comes from their geometric structure, not their chemical composition.
The new materials were made using projection micro-stereolithography, a form of desktop 3D printing that works on a microscopic level and can create highly complex, three-dimensional microstructures layer by layer very quickly for easy prototyping. It involves projecting a beam of ultraviolet light into a tank of polymers, responsive hydrogels, shape memory polymers, or bio-materials using the digital stereolithography technique in the form of masks, similar to those used to create microchips, to shape the layers.
Projection micro-stereolithography operates on a very small scale that allows the formation of "microlattices," which are much like trusses and girders. Materials can even be switched during fabrication. According to the team, it can be applied to many different materials, including polymers, metals and ceramics, which is exactly what the team did using a variety of constituent materials.
Firstly, the LLNL/MIT team made a polymer template coated with a metal film 200 to 500 nanometers thick, then the polymer base was melted away, leaving behind the metal in the form of thin-film tubes.
The team then used the same technique but replaced the metal with ceramic to create ceramic tubes about 50 nanometers thick, which produced a material with the properties of an extremely stiff aerogel, four orders of magnitude stiffer than conventional aerogel, but with the same density...





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Flexible, high-strength polymer aerogels deliver "super-insulation" properties

September 27, 2012

 Often called "frozen smoke", aerogels are among the amazing materials of our time, with fifteen Guinness Book of World Records entries to their name. However, despite their list of extreme properties, traditional aerogels are brittle, crumbling and fracturing easily enough to keep them out of many practical applications. A new class of mechanically robust polymer aerogels discovered at NASA's Glenn Research Center in Ohio may soon enable engineering applications such as super-insulated clothing, unique filters, refrigerators with thinner walls, and super-insulation for buildings...

http://www.gizmag.com/polymer-aerogel-stronger-flexible-nasa/23955/?li_source=LI&li_medium=default-widget

 

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New technique leads to creation of elastic high-strength carbon nanotube film

 

February 4, 2016

 

http://phys.org/news/2016-02-technique-creation-elastic-high-strength-carbon.html



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New experimental research exposes the strength of beryllium at extreme conditions

 

 August 5, 2015 

 

http://phys.org/news/2015-08-experimental-exposes-strength-beryllium-extreme.html#jCp

 

 Until recently, there were very little experimental data about the behavior of beryllium (Be) at very high pressures and strain rates, with existing material models predicting very different behaviors in these regimes. In a successful example of international research collaboration, a team of scientists from Lawrence Livermore National Laboratory (LLNL) and the Russian Federal Nuclear Center-All-Russian Research Institute of Experimental Physics (RFNC-VNIIEF) changed this field of knowledge The technique involves setting off a piece of high explosives (HE) near the Be. On the side of the Be facing the HE, the team imposed a sinusoidal ripple pattern designed by co-author Jon Belof. When the expanding HE products load up against the target, the target accelerates. Since there is a low density gas pushing against a higher density metal, the interface is Rayleigh-Taylor unstable and the ripples grow in amplitude as the target accelerates.

If the target has no strength, the ripples will grow indefinitely and become turbulent at some point. However, since the Be does have strength, the ripple growth is limited by the strength of the material itself. The main diagnostic for the experiments is an X-ray image from the side of the target showing the height of the ripples at some time after the HE loading has occurred. The other diagnostic is velocimetry of the target showing its acceleration profile.



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Bamboo inspires new process for making metals tougher

 

July 3, 2014


Steel is a common benchmark against which the strength of materials is measured, with "stronger than steel" a familiar catch cry for those touting the properties of some new space-age material. But now researchers at North Carolina State University have created steel that is stronger than steel using a process that increases the toughness of various metals by altering the microstructures within them.
Inspired by the internal structure of bones and bamboo, which both boast impressive strength-to-weight ratios, the researchers were able to increase the strength and toughness of metals by giving them what the researchers refer to as a "gradient structure." This is a structure where the size of the millions of tightly-packed grains that make up the metal are gradually increased further down into the material...


http://www.gizmag.com/gradient-structure-increase-metal-toughness/32819/ 

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Hemp is another good natural fiber that we can make for many materials such as rope, clothing, industrial fabrics and industrial materials. 

 
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Comparison of composites made from fungal defibrated hemp with composites of traditional hemp yarn  [2007]

Abstract:

 
Aligned epoxy-matrix composites were made from hemp fibres defibrated with the fungi Phlebia radiata Cel 26 and Ceriporiopsis subvermispora previously used for biopulping of wood. The fibres produced by cultivation of P. radiata Cel 26 were more cellulose rich (78%, w/w) than water-retted hemp due to more degradation of pectin and lignin. The defibrated hemp fibres had higher fibre stiffness (88-94 GPa) than the hemp yarn (60 GPa), which the fibre twisting in hemp yarn might explain. Even though mild processing was applied, the obtained fibre strength (643 MPa) was similar to the strength of traditionally produced hemp yarn (677 MPa). The fibre strength and stiffness properties are derived from composite data using the rule of mixtures model. The fibre tensile strength increased linearly with cellulose content to 850 MPa for pure cellulose. The fibre stiffness increased also versus the cellulose content and cellulose crystallinity and reached a value of 125 GPa for pure crystalline cellulose.

 http://agris.fao.org/agris-search/search.do?recordID=US201300749080

 

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Hemp and cannabis also have nutritional value, this is why you can buy hemp seeds at the health food store. Hemp and cannaabis can also help treat people with medical conditions, including cancer.

 
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Cannabis Compound Destroyed Incurable Brain Tumors


 (Modern uses for the hemp plant)


http://www.cureyourowncancer.org/cannabis-compound-destroyed-incurable-brain-tumors.html


____________________________________ 

What is Hemp?

 

http://azmarijuana.com/marijuana-info/what-is-hemp/


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Pollution: Petrol vs Hemp

http://www.hempcar.org/petvshemp.shtml

____________________________________

 

Hemp can even be made for insulation, concrete and foam materials.

 

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Wood foam may be a new form of green home insulation

 

Insulating your home may help the environment by lowering your energy usage, but unfortunately the petroleum-based foam that's typically used as insulation isn't all that eco-friendly itself. Researchers at Germany's Fraunhofer Institute for Wood Research, however, have developed a reportedly greener alternative that they claim works just as well – it's foam made from wood.

To produce the foam, wood particles are first ground so small that they form into a slimy solution. A gas is then added to that slime, causing it to take on a frothy consistency. Once that froth hardens – a process that is "aided by natural substances contained in the wood" – a dry, porous foam is the result. The finished product can take the form of either rigid foam boards, or flexible mats.
The slime can also be converted into foam via induced chemical reactions.

 http://www.gizmag.com/wood-foam-insulation/31133/?li_source=LI&li_medium=default-widget

 

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Even rice can be used for many fibers and paper. We also need to stop the use of pesticide buildup in rice paddies that can harm the ecosystems of the planet. 

 

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Rice husks may find use in cheaper, greener, longer-lasting particleboard

May 27, 2015

http://www.gizmag.com/rice-husk-particleboard/37730/


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We could make a better form of carbon fiber. Instead of making carbon fiber from fossil fuel, we could make carbon fiber out of plant based materials, diamonds, charcoal or ash. Samurai swords were once forged with the method of taking carbon from charcoal, and making a carbon steel blade. 

 
____________________________________

Secrets of the Samurai Sword - Documentary

 https://www.youtube.com/watch?v=XoqVhlFe_EU

____________________________________

 

STUPID things people say about medieval SWORDS 

https://www.youtube.com/watch?v=--qfjf8SSuU

____________________________________

 

 MYSTERIOUS Discoveries Science STILL Can't Explain!

{The Ulfberht Swords}

https://www.youtube.com/watch?v=d8fiXaBm0_k

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The Secrets of Wootz Damascus Steel

2017

A 50-minute documentary about the legendary Al Pendray, together with two swordsmiths from Jordan, and their quest to produce authentic wootz Damascus steel with ores mined from a historical mine in Jordan - a mine that is known to have produced weapons for Saladin himself.

https://www.youtube.com/watch?v=OP8PCkcBZU4


____________________________________

 

 Traditional Crafts of Finland - Episode 1 - Puukko Knife Making

2018

https://www.youtube.com/watch?v=BLnqr6IGVgs

____________________________________ 



 The Mystery Of Tutankhamun's Dagger | What On Earth? 


{A blade made of iron that has not rusted for over 3,000 years}

 https://www.youtube.com/watch?v=98n-DTIwW18

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Impossible Ancient OOPArts Academia Can't Explain

Oct 15, 2019

{The Sword of Goujian}

https://www.youtube.com/watch?v=DzQRjn7Z7fQ


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39 Sword Steel Types: A Guide into Metallurgical Characteristics

January 19, 2024

https://swordis.com/blog/steel-types-for-swords/

____________________________________

 

17 Katanas Destructed to Find the Best Steel

November 13, 2024

https://swordis.com/blog/what-is-the-best-steel-for-a-katana/

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Tetragrammaton - The Most Sacred Knowledge On Our Planet - Nassim Haremin

Aug 29, 2015

https://www.youtube.com/watch?v=peYrSP8cke8

28:30 - Copper scrolls found near the Dead Sea contained
the purest copper ever found on Earth.

 

____________________________________ 

 

90+ Different Types of Metal: A Comprehensive Guide

https://www.machinemfg.com/different-types-of-metals/


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List of Metals

January 18, 2025

https://sciencenotes.org/list-metals/

____________________________________

 

Category: Metals

https://en.wikipedia.org/wiki/Category:Metals

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List of Elements in the Lanthanide Series

December 12, 2019

Key Takeaways
 

Lanthanides are rare earth metals found in the first row below the periodic table's main body.

 

These elements are bright, metallic, and form colorful compounds due to varying oxidation states.

Lanthanides are used in electronics like TV displays, lasers, and even to color glass.

The lanthanides or lanthanoid series is a group of transition metals located on the periodic table in the first row (period) below the main body of the table. The lanthanides are commonly referred to as the rare earth elements (REE), although many people group scandium and yttrium together under this label as well. Therefore, it's less confusing to call the lanthanides a subset of the rare earth metals.

The Lanthanides

Here's a list of the 15 elements that are lanthanides, which run from atomic number 57 (lanthanum, or Ln) and 71 (lutetium, or Lu):

    Lanthanum: symbol Ln, atomic number 57
    Cerium: symbol Ce, atomic number 58
    Praseodymium: symbol Pr, atomic number 59
    Neodymium: symbol Nd, atomic number 60
    Promethium: symbol Pm, atomic number 61
    Samarium: symbol Sm, atomic number 62
    Europium: symbol Eu, atomic number 63
    Gadolinium: symbol Gd, atomic number 64
    Terbium: symbol Tb, atomic number 65
    Dysprosium: symbol Dy, atomic number 66
    Holmium: symbol Ho, atomic number 67
    Erbium: symbol Er, atomic number 68
    Thulium: symbol Tm, atomic number 69
    Ytterbium: symbol Yb, atomic number 70
    Lutetium: symbol Lu, atomic number 71

Note that sometimes lanthanides are considered to be the elements following lanthanum on the periodic table, making it a group of 14 elements. Some references also exclude lutetium from the group because it has a single valence electron in the 5d shell. 

https://www.thoughtco.com/lanthanides-606652

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Rare Earth Elements List

May 02, 2019

The CRC Handbook of Chemistry and Physics and IUPAC list the rare earths as consisting of the lanthanides, plus scandium and yttrium. This includes atomic number 57 through 71, as well as 39 (yttrium) and 21 (scandium):

Lanthanum (sometimes considered a transition metal)
Cerium
Praseodymium
Neodymium
Promethium
Samarium
Europium
Gadolinium
Terbium
Dysprosium
Holmium
Erbium
Thulium
Ytterbium
Lutetium
Scandium
Yttrium

Other sources consider the rare earths to be the lanthanides and actinides:

Lanthanum (sometimes considered a transition metal)
Cerium
Praseodymium
Neodymium
Promethium
Samarium
Europium
Gadolinium
Terbium
Dysprosium
Holmium
Erbium
Thulium
Ytterbium
Lutetium
Actinium (sometimes considered a transition metal)
Thorium
Protactinium
Uranium
Neptunium
Plutonium
Americium
Curium
Berkelium
Californium
Einsteinium
Fermium
Mendelevium
Nobelium
Lawrencium 

 Rare Earth Uses

In general, the rare earths are used in alloys, for their special optical properties, and in electronics. Some specific uses of elements include:

    Scandium: Use to make light alloys for the aerospace industry, as a radioactive tracer, and in lamps
    Yttrium: Used in yttrium aluminum garnet (YAG) lasers, as a red phosphor, in superconductors, in fluorescent tubes, in LEDs, and as a cancer treatment
    Lanthanum: Use to make high refractive index glass, camera lenses, and catalysts
    Cerium: Use to impart a yellow color to glass, as a catalyst, as a polishing powder, and to make flints
    Praseodymium: Used in lasers, arc lighting, magnets, flint steel, and as a glass colorant
    Neodymium: Used to impart violet color to glass and ceramics, in lasers, magnets, capacitors, and electric motors
    Promethium: Used in luminous paint and nuclear batteries
    Samarium: Used in lasers, rare earth magnets, masers, nuclear reactor control rods
    Europium: Used to prepare red and blue phosphors, in lasers, in fluorescent lamps, and as an NMR relaxant
    Gadolinium: Used in lasers, x-ray tubes, computer memory, high refractive index glass, NMR relaxation, neutron capture, MRI contrast
    Terbium: Use in green phosphors, magnets, lasers, fluorescent lamps, magnetostrictive alloys, and sonar systems
    Dysprosium: Used in hard drive disks, magnetostrictive alloys, lasers, and magnets
    Holmium: Use in lasers, magnets, and calibration of spectrophotometers
    Erbium: Used in vanadium steel, infrared lasers, and fiber optics
    Thulium: Used in lasers, metal halide lamps, and portable x-ray machines
    Ytterbium: Used in infrared lasers, stainless steel, and nuclear medicine
    Lutetium: Used in positron emission tomography (PET) scans, high refractive index glass, catalysts, and LEDs

https://www.thoughtco.com/rare-earth-elements-list-606660

 

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Metalloids or Semimetals: Definition, List of Elements, and Properties

September 14, 2019

 Location on the Periodic Table

The metalloids or semimetals are located along the line between the metals and nonmetals in the periodic table. Because these elements have intermediate properties, it's sort of a judgment call as to whether a particular element is a metalloid or should be assigned to one of the other groups. You'll find metalloids are classified differently in different classification systems, depending on the scientist or author. There is no single "right" way to divide the elements. 

 List of Elements That Are Metalloids

The metalloids are generally considered to be:

    Boron
    Silicon
    Germanium
    Arsenic
    Antimony
    Tellurium
    Polonium (usually recognized, sometimes considered a metal)
    Astatine (sometimes recognized, otherwise seen as a halogen)

Element 117, tennessine, has not been produced in sufficient amounts to verify its properties but is predicted to be a metalloid.

Some scientists consider neighboring elements on the periodic table to either be metalloids or to have metalloid characteristics. An example is carbon, which may be considered either a nonmetal or a metalloid, depending on its allotrope. The diamond form of carbon looks and behaves as a nonmetal, while the graphite allotrope has a metallic luster and acts as an electrical semiconductor and so is a metalloid.

Phosphorus and oxygen are other elements that have both nonmetallic and metalloid allotropes. Selenium is considered to be a metalloid in environmental chemistry. Other elements that may behave as metalloids under certain conditions are hydrogen, nitrogen, sulfur, tin, bismuth, zinc, gallium, iodine, lead, and radon. 

https://www.thoughtco.com/metalloids-or-semimetals-606653

 

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Metals: List of Elements

July 23, 2024

https://www.thoughtco.com/metals-list-606655

 Most elements are metals. This group includes alkali metals, alkaline earth metals, transition metals, basic metals, lanthanides (rare earth elements), and actinides. Although separate on the periodic table, lanthanides and actinides are really specific types of transition metals.

Here's a list of all the elements on the periodic table that are metals.
Alkali Metals

Alkali metals are in group IA on the far left side of the periodic table. They are highly reactive elements, distinctive because of their +1 oxidation state and generally low density compared to other metals. Because they are so reactive, these elements are found in compounds. Only hydrogen is found free in nature as a pure element, and that is as diatomic hydrogen gas.

    Hydrogen in its metallic state (usually considered a nonmetal)​
    Lithium
    Sodium
    Potassium
    Rubidium
    Cesium
    Francium

Alkaline Earth Metals

The alkaline earth metals are found in group IIA of the periodic table, which is the second column of elements. All of the alkaline earth metal atoms have a +2 oxidation state. Like the alkali metals, these elements are found in compounds rather than pure form. Alkaline earths are reactive but less so than alkali metals. Group IIA metals are hard and shiny and usually malleable and ductile.

    Beryllium
    Magnesium
    Calcium
    Strontium
    Barium
    Radium

Basic Metals

The basic metals display the characteristics people generally associate with the term "metal." They conduct heat and electricity, have a metallic luster, and tend to be dense, malleable, and ductile. However, some of these elements display nonmetallic characteristics. For example, one allotrope of tin behaves more as a nonmetal. While most metals are hard, lead and gallium are examples of elements that are soft. These elements tend to have lower melting and boiling points than the transition metals (with some exceptions).

    Aluminum
    Gallium
    Indium
    Tin
    Thallium
    Lead
    Bismuth
    Nihonium: probably a basic metal
    Flerovium: probably a basic metal
    Moscovium: probably a basic metal
    Livermorium: probably a basic metal
    Tennessine: in the halogen group but may behave more like a metalloid or metal

Transition Metals

The transition metals are characterized by having partially filled d or f electron subshells. Since the shell is incompletely filled, these elements display multiple oxidation states and often produce colored complexes. Some transition metals occur in pure or native form, including gold, copper, and silver. The lanthanides and actinides are found only in compounds in nature.

    Scandium
    Titanium
    Vanadium
    Chromium
    Manganese
    Iron
    Cobalt
    Nickel
    Copper
    Zinc
    Yttrium
    Zirconium
    Niobium
    Molybdenum
    Technetium
    Ruthenium
    Rhodium
    Palladium
    Silver
    Cadmium
    Lanthanum
    Hafnium
    Tantalum
    Tungsten
    Rhenium
    Osmium
    Iridium
    Platinum
    Gold
    Mercury
    Actinium
    Rutherfordium
    Dubnium
    Seaborgium
    Bohrium
    Hassium
    Meitnerium
    Darmstadtium
    Roentgenium
    Copernicium
    Cerium
    Praseodymium
    Neodymium
    Promethium
    Samarium
    Europium
    Gadolinium
    Terbium
    Dysprosium
    Holmium
    Erbium
    Thulium
    Ytterbium
    Lutetium
    Thorium
    Protactinium
    Uranium
    Neptunium
    Plutonium
    Americium
    Curium
    Berkelium
    Californium
    Einsteinium
    Fermium
    Mendelevium
    Nobelium
    Lawrencium


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Transition Metals: List and Properties

September 05, 2024

 The largest group of elements on the periodic table is that of the transition metals, found in the middle of the table. Also, the two rows of elements below the main body of the periodic table (the lanthanides and actinides) are special subsets of these metals. These elements are called transition metals because electrons in their atoms transition to fill the d subshell or d sublevel orbital. Thus, the transition metals are also known as d-block elements.

Here is a list of elements considered transition metals or transition elements. This list does not include the lanthanides or actinides, only the elements in the main part of the periodic table.

List of Elements That Are Transition Metals

    Scandium
    Titanium
    Vanadium
    Chromium
    Manganese
    Iron
    Cobalt
    Nickel
    Copper
    Zinc
    Yttrium
    Zirconium
    Niobium
    Molybdenum
    Technetium
    Ruthenium
    Rhodium
    Palladium
    Silver
    Cadmium
    Lanthanum, sometimes (often considered a rare earth, lanthanide)
    Hafnium
    Tantalum
    Tungsten
    Rhenium
    Osmium
    Iridium
    Platinum
    Gold
    Mercury
    Actinium, sometimes (often considered a rare earth, actinide)
    Rutherfordium
    Dubnium
    Seaborgium
    Bohrium
    Hassium
    Meitnerium
    Darmstadtium
    Roentgenium
    Copernicium presumably is a transition metal.


https://www.thoughtco.com/transition-metals-list-and-properties-606663

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Researchers find new phase of carbon, make diamond at room temperature

 

November 30, 2015

 

 Researchers from North Carolina State University have discovered a new phase of solid carbon, called Q-carbon, which is distinct from the known phases of graphite and diamond. They have also developed a technique for using Q-carbon to make diamond-related structures at room temperature and at ambient atmospheric pressure in air.

 http://phys.org/news/2015-11-phase-carbon-diamond-room-temperature.html

 

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Diamonds may be the key to future NMR/MRI technologies

 

December 16, 2015

Researchers with the U.S. Department of Energy (DOE)'s Lawrence Berkeley National Laboratory (Berkeley Lab) and the University of California (UC) Berkeley have demonstrated that diamonds may hold the key to the future for nuclear magnetic resonance (NMR) and magnetic resonance imaging (MRI) technologies.

http://phys.org/news/2015-12-diamonds-key-future-nmrmri-technologies.html

 
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Flexible X-ray detector constructed without harmful heavy metals

29 Aug 2021


https://physicsworld.com/a/flexible-x-ray-detector-constructed-without-harmful-heavy-metals/

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Wood pulp extract stronger than carbon fiber or Kevlar

 

September 3, 2012

 http://www.gizmag.com/cellulose-nanocrystals-stronger-carbon-fiber-kevlar/23959/?li_source=LI&li_medium=default-widget

The Forest Products Laboratory of the US Forest Service has opened a US$1.7 million pilot plant for the production of cellulose nanocrystals (CNC) from wood by-products materials such as wood chips and sawdust. Prepared properly, CNCs are stronger and stiffer than Kevlar or carbon fibers, so that putting CNC into composite materials results in high strength, low weight products. In addition, the cost of CNCs is less than ten percent of the cost of Kevlar fiber or carbon fiber. These qualities have attracted the interest of the military for use in lightweight armor and ballistic glass (CNCs are transparent), as well as companies in the automotive, aerospace, electronics, consumer products, and medical industries.


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Biodegradable fibers as strong as steel made from wood cellulose

 

  June 9, 2014

 A team of researchers working at Stockholm's KTH Royal Institute of Technology claim to have developed a way to make cellulose fibers stronger than steel on a strength-to-weight basis. In what is touted as a world first, the team from the institute's Wallenberg Wood Science Center claim that the new fiber could be used as a biodegradable replacement for many filament materials made today from imperishable substances such as fiberglass, plastic, and metal. And all this from a substance that requires only water, wood cellulose, and common table salt to create it.

http://www.gizmag.com/steel-strong-fibers-wood-cellulose/32432/?li_source=LI&li_medium=default-widget

 

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Building a high rise out of wood? Cross-laminated timber could make it possible

July 28, 2025

A new study finds that adopting cross-laminated timber as a primary construction material could have significant environmental benefits, from carbon storage to global reforestation and increased forest cover.

Cross-laminated timber (CLT) is created by stacking multiple layers of timber and then adhering the layers together. This results in strong, light wooden panels up to 60 feet long, big enough to form an entire wall or other structures. These panels are also fire-resistant. When exposed to fire, the outer layer of a CLT panel turns to char, which seals the rest of the wood away and prevents it from igniting.

Because CLT is such a promising construction material, researchers wanted to determine the effects of adopting it more broadly. To do this, they combined an environmental assessment tool known as a life cycle assessment (LCA), which tracks the environmental effects of a product throughout its life cycle, with the Global Timber Model (GTM), an economic model which examines the effects of land use and policy on the global timber market.

https://techxplore.com/news/2025-07-high-wood-laminated-timber.html

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Nanotubes with two walls have singular qualities

 

 April 15, 2015

 

 Rice University researchers have determined that two walls are better than one when turning carbon nanotubes into materials like strong, conductive fibers or transistors.

 

 Rice materials scientist Enrique Barrera and his colleagues used atomic-level models of double-walled nanotubes to see how they might be tuned for applications that require particular properties. They knew from others' work that double-walled nanotubes are stronger and stiffer than their single-walled cousins. But they found it may someday be possible to tune double-walled tubes for specific electronic properties by controlling their configuration, chiral angles and the distance between the walls.

 

 http://phys.org/news/2015-04-nanotubes-walls-singular-qualities.html?utm_source=menu&utm_medium=link&utm_campaign=item-menu

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Two-dimensional materials 'as revolutionary as graphene'

 

July 29, 2016

http://phys.org/news/2016-07-two-dimensional-materials-revolutionary-graphene.html



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Move aside carbon: Boron nitride-reinforced materials are even stronger 

 

 December 22, 2015 

 

 

 A single infusion of a powerful antibody called VRC01 can suppress the level of HIV in the blood of infected people who are not taking antiretroviral therapy (ART), scientists at the National Institutes of Health report in a paper published today. The researchers also found that giving HIV-infected people VRC01 antibodies by infusing them into a vein or under the skin is safe and well tolerated, and the antibodies remain in the blood for an extended period.
While such carbon nanotube-polymer nanocomposites have attracted enormous interest from the materials research community, a group of scientists now has evidence that a different nanotube—made from boron nitride—could offer even more strength per unit of weight. They publish their results in the journal Applied Physics Letters.

http://phys.org/news/2015-12-carbon-boron-nitride-reinforced-materials-stronger.html#jCp


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Not Graphene: New Type of Atomically Thin Carbon Material Discovered

26th, May 2021

 

Carbon exists in various forms. In addition to diamond and graphite, there are recently discovered forms with astonishing properties. For example graphene, with a thickness... The post Not Graphene: New Type of Atomically Thin Carbon Material Discovered appeared first on SciTechDaily.  

 

Structure of the new carbon network. The upper part shows schematically the linking of the carbon atoms, forming squares, hexagons, and octagons. The lower part is an image of the network, obtained with high-resolution microscopy. Credit: University of Marburg, Aalto University.

 

Carbon exists in various forms. In addition to diamond and graphite, there are recently discovered forms with astonishing properties. For example graphene, with a thickness of just one atomic layer, is the thinnest known material, and its unusual properties make it an extremely exciting candidate for applications like future electronics and high-tech engineering. In graphene, each carbon atom is linked to three neighbors, forming hexagons arranged in a honeycomb network. Theoretical studies have shown that carbon atoms can also arrange in other flat network patterns, while still binding to three neighbors, but none of these predicted networks had been realized until now.

 

Researchers at the University of Marburg in Germany and Aalto University in Finland have now discovered a new carbon network, which is atomically thin like graphene, but is made up of squares, hexagons, and octagons forming an ordered lattice. They confirmed the unique structure of the network using high-resolution scanning probe microscopy and interestingly found that its electronic properties are very different from those of graphene.

 

In contrast to graphene and other forms of carbon, the new Biphenylene network — as the new material is named — has metallic properties. Narrow stripes of the network, only 21 atoms wide, already behave like a metal, while graphene is a semiconductor at this size. “These stripes could be used as conducting wires in future carbon-based electronic devices.” said professor Michael Gottfried, at University of Marburg, who leads the team who developed the idea. The lead author of the study, Qitang Fan from Marburg continues, “This novel carbon network may also serve as a superior anode material in lithium-ion batteries, with a larger lithium storage capacity compared to that of the current graphene-based materials.”

 

The team at Aalto University helped image the material and decipher its properties. The group of Professor Peter Liljeroth carried out the high-resolution microscopy that showed the structure of the material, while researchers led by Professor Adam Foster used computer simulations and analysis to understand the exciting electrical properties of the material.

 

The new material is made by assembling carbon-containing molecules on an extremely smooth gold surface. These molecules first form chains, which consist of linked hexagons, and a subsequent reaction connects these chains together to form the squares and octagons. An important feature of the chains is that they are chiral, which means that they exist in two mirroring types, like left and right hands. Only chains of the same type aggregate on the gold surface, forming well-ordered assemblies, before they connect. This is critical for the formation of the new carbon material, because the reaction between two different types of chains leads only to graphene. “The new idea is to use molecular precursors that are tweaked to yield biphenylene instead of graphene” explains Linghao Yan, who carried out the high-resolution microscopy experiments at Aalto University.

 

For now, the teams work to produce larger sheets of the material, so that its application potential can be further explored. However, “We are confident that this new synthesis method will lead to the discovery of other novel carbon networks.” said Professor Liljeroth.

 

 https://statnano.com/world-news/86499/Not-Graphene-New-Type-of-Atomically-Thin-Carbon-Material-Discovered


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Forget Graphene - Borophene may take over the world

 

Apr 11, 2019

 

https://www.youtube.com/watch?v=k0ts_Fi4zC4

 

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Cutting-Edge Borophene Coatings: A Quick Overview

 

 2023

 

 In the ever-evolving field of automotive coatings, borophene has emerged as a groundbreaking material with the potential to revolutionize the industry. This highly technical blog post delves into the intricacies of borophene coatings, exploring their composition, discovery, manufacturing process, and their potential application in automotive paints. We will also address the pressing question: Is it truly worth the hype in real-world applications?

 

https://blog.reflecton.in/pro-blog-the-cutting-edge-world-of-boraphene-coatings/

 

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Progress and future directions in borophene research

 

 07 April 2025

 

 https://www.nature.com/articles/s41557-025-01773-4

 

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The rise of borophene: Inside the design and application of this emerging material system

 

 January 23, 2025

 

 https://ceramics.org/ceramic-tech-today/the-rise-of-borophene/

 

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Engineers Create Double Layer of Borophene for First Time

 

Aug 26, 2021

 

New material maintains borophene’s electronic properties, offers new advantages

 

For the first time, Northwestern University engineers have created a double layer of atomically flat borophene, a feat that defies the natural tendency of boron to form non-planar clusters beyond the single-atomic-layer limit.

 

Although known for its promising electronic properties, borophene — a single-atom-layer-thick sheet of boron — is challenging to synthesize. Unlike its analog two-dimensional material graphene, which can be peeled away from innately layered graphite using something as simple as scotch tape, borophene cannot merely be peeled away from bulk boron. Instead, borophene must be grown directly onto a substrate.

 

And if growing one layer was difficult, growing multiple layers of atomically flat borophene seemed impossible. Because bulk boron is not layered like graphite, growing boron beyond single atomic layers leads to clustering rather than planar films.

 
https://www.mccormick.northwestern.edu/news/articles/2021/08/engineers-create-double-layer-of-borophene-for-first-time/

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Inorganic borophene liquid crystals may provide a superior new material for optoelectronic devices

 

 February 24, 2022

 

https://phys.org/news/2022-02-inorganic-borophene-liquid-crystals-superior.html 

 

____________________________________

 

 

Disorder in surface materials key to better hydrogen storage

 

 November 4, 2021

 

https://phys.org/news/2021-11-disorder-surface-materials-key-hydrogen.html 

 

____________________________________

 

Borophene on silver grows freely into an atomic 'skin'

 

 September 30, 2019

 

https://phys.org/news/2019-09-borophene-silver-freely-atomic-skin.html

 

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News on borophene

 

 https://phys.org/tags/borophene/

 

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Boron can form a purely honeycomb, graphene-like 2-D structure

 

 March 14, 2018

 

https://phys.org/news/2018-03-boron-purely-honeycomb-graphene-like-d.html 

 

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Delicately opening a band gap in graphene enables high-performance transistors

 

September 21, 2015

 

Electrons can move through graphene with almost no resistance, a property that gives graphene great potential for replacing silicon in next-generation, highly efficient electronic devices. But currently it's very difficult to control the electrons moving through graphene because graphene has no band gap, which means the electrons don't need to cross any energy barrier in order to conduct electricity. As a result, the electrons are always conducting, all the time, which means that this form of graphene can't be used to build transistors because it has no "off" state. In order to control the electron movement in graphene and enable "off" states in future graphene transistors, graphene needs a non-zero band gap—an energy barrier that can prevent electrons from conducting electricity when desired, making graphene a semiconductor instead of a full conductor.

http://phys.org/news/2015-09-delicately-band-gap-graphene-enables.html#jCp

 

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Microwave plasma-induced graphene-sheet fibers

from waste coffee grounds

The waste coffee grounds (The remainder of regular coffee powder after being
boiled, UCC) was dried at 100 degrees Celsius  for 6 hours without other treatments. Graphene-sheet fibers (GSFs) were fabricated from dried coffee
grounds loaded in a nickel case using 2.45 GHz microwave plasma system at
the power of 900 W, which was equipped with a rectangular waveguide to couple
the microwave through quartz tube for generating the plasma. In the system, no
additional heater was installed for substrate heating. The substrate temperature was controlled by microwave power and plasma exposure time, and was measured by a thermocouple placed in direct contact with the substrate holder.
After the deposition chamber was pumped down to a base pressure of 1 Torr
by a rotary pump with the pumping gas rate of 300L/s, the hydrogen and argon gases were introduced into the chamber and produced the plasma to irradiate the coffee grounds for 15 min. The maximal temperature was 650 degrees Celsius during the process of microwave plasma irradiation. After deposition, the plasma was shut down and the equipment was naturally cooled to room temperature. The yield of GSFs was found to be 10-20% in all produced nanocarbons.


http://www.rsc.org/suppdata/c5/ta/c5ta03833b/c5ta03833b1.pdf

 

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 Scientists grow high-quality graphene from tea tree extract

August 21, 2015

Graphene has been grown from materials as diverse as plastic, cockroaches, Girl Scout cookies, and dog feces, and can theoretically be grown from any carbon source. However, scientists are still looking for a graphene precursor and growth method that is sustainable, scalable, and economically feasible, since these are all requirements for realizing widespread commercialization of graphene-based devices.

http://phys.org/news/2015-08-scientists-high-quality-graphene-tea-tree.html


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There will always be different combinations of natural and inorganic materials for the discovery of new materials and nanostructures. These discoveries can be used for the creation of new inventions. 

 

____________________________________




Synthesis and characterization of organic-inorganic hybrid materials and nanostructures
 

 Posted: June 24, 2015

 http://www.scientificamerican.com/naturejobs/?method=job&id=533011

The project supported by the Swedish Research Council is aimed at the development of new approaches to building up complex structures of metal oxide nanoparticles to be used as nano reactors and as drug delivery vehicles. The produced particles will be decorated with functional biomolecules, proteins and enzymes, to provide them with ability to act as biocatalysts. It will involve the synthesis of new organic-inorganic hybrid materials, their characterization by a variety of techniques such as electron microscopy, X-ray diffraction and NMR, Atomic Force Microscopy etc., and verification of their functional characteristics. The project will be carried out in an inspiring international environment and will involve active participation in international project meetings.

____________________________________ 




 15 Most Dense Materials on Earth | Volumetric Mass Density


May 15, 2019

15. Molybdenum
14. Silver
13. Lead
12. Thorium
11. Rhodium
10. Mercury
9. Tantalum
8. Uranium
7. Tungsten
6. Gold
5. Plutonium
4. Rhenium
3. Platinum
2. Iridium
1. Osmium


https://www.rankred.com/densest-materials-on-earth/


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National Lab Teams Create Densest Object on Earth

Jan 10, 2020

Applying 30 million atmospheres of pressure lets researchers compress copper into the densest material on the planet, for a brief moment.

Scientists used the National Ignition Facility at Lawrence Livermore National Lab to squeeze a microscopic sample of copper samples under 30 million atmospheres in less than a billionth of a second. This tripled the sample’s density, creating the densest object on the planet for a brief moment in time.


https://www.machinedesign.com/materials/article/21120262/national-lab-teams-create-densest-object-on-earth



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Chapter 8: Glass technology

 

____________________________________
____________________________________

 

 

 

 



____________________________________

 

We can see problems with many of the different types of dyes, paints and chemicals used to make certain types of glass and plastics these days. We often wonder how many chemicals in glass and plastics will interact and biodegrade in the wild. We need an ecologically friendly way of making glass while replacing many chemicals harmful chemicals in glass such as lead.

Many ancient cultures such as the ancient Romans would use lead in glass. Even drinking out of certain glass bottles with harmful chemicals in these ancient cultures could make people ill.


____________________________________


 Carnival Glass 101 


http://carnivalglass101.carnivalheaven.com/id136.ht

 If you look at the recipe that remains from E. A. Dugan's notebook (page 26 of the Dugan/Diamond book by Heacock, Measell & Wiggins), for a turquoise blue opal glass, you have 300 parts sand (silica), 81 parts soda (calcium carbonate), 50 parts lead (most likely lead oxide), 24 parts pearls (potassium phosphate), 54 parts feldspar (most likely potassium aluminum silicate), 50 parts fluorspar (calcium fluoride), 5 parts kryolite (sodium fluoraluminate),-actually used as a stomach insecticide as the crystals punch holes in insect gut cells!), 5 parts arsenic, and 7 oz. of copper scales (for the blue color). As you can tell from this formula, there's a lot more lead and fluoride than arsenic in the batch and the dust during the mixing of the batch would be quite dangerous. However, once fused in the melting process, none of these chemicals would be chemically active. If they were, all of our lead crystal glass would be highly dangerous to use! (That rumor goes around occasionally).

I hear all the time that cobalt (blue), selenium (pink to red) and uranium (yellow) compounds that are used as colorants in glass are highly toxic or are no longer available.



____________________________________

 


Many people sometimes are not aware that some plastics exist in nature. This process is a buildup of natural oil in the ground. When the right type of chemicals combine, it can leave small types of a type of residue of an oily or plastic type of film. Especially in underground pockets or streams of natural oil. This natural type of plastic film may not quite be like the plastic that we use for individual products, this is still a good example of the materials that nature can produce naturally.

Glass can be made from sand that has gone through hot temperatures. Different types of smart glass can contain certain polymer resins as well. Many types of synthetic glass can even be considered a fiberglass, or plastic. Many people want a sustainable way to make extra strong glass that could biodegrade properly. 

 
We could even possibly use atomic fractals in metallic glasses instead of certain types of fiberglass currently out on the market. 

 

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Natural Plastics: Do They Exist?

 

May 01, 2025

 

Plastic is a man-made material that has become a symbol of the world's litter and solid waste disposal problems. However, molecules of plastic have been found outside of Earth, and some trees on our planet release propylene, a chemical used to make plastic, naturally. Natural plastics are not a complete solution to solid waste problems but may have important applications where biodegradability is needed, such as disposable diapers or fast-food containers. 

 

Characteristics	Values
Natural Plastics	Animal horns, tortoiseshell, cellulose, rubber, amber, shellac
Natural Polymers	Condensation polymers
Synthetic Polymers	Radical ad addition polymers
Natural Sources of Propylene	Some trees
Natural Plastic Creation	Boil potatoes and use the leftover water

 

https://shunpoly.com/article/are-there-any-natural-occurring-plastics 

 

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Atomic fractals in metallic glasses

September 21, 2015

Metallic glasses are very strong and elastic materials that appear with the naked eye to be identical to stainless steel. But metallic glasses differ from ordinary metals in that they are amorphous, lacking an orderly, crystalline atomic arrangement. This random distribution of atoms, which is the primary characteristic of all glass materials (such as windowpanes and tableware), gives metallic glasses unique mechanical properties but unpredictable internal structure. Researchers in the Caltech lab of Julia Greer, professor of materials science and mechanics in the Division of Engineering and Applied Science, have shown that metallic glasses do have an atomic-level structure—if you zoom in closely enough—although it differs from the periodic lattices that characterize crystalline metals.

 http://phys.org/news/2015-09-atomic-fractals-metallic-glasses.html#jCp



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Improving bulk metallic glass by maximizing surface

 

December 22, 2015

 Yale University researchers have figured out a way to refine bulk metallic glasses to improve their electrochemical performance.

 Results of the research, based in the lab of chemical and environmental engineering professor André D. Taylor, are published in the Dec. 21 issue of Advanced Materials.

Bulk metallic glass (BMG), also known as amorphous metal alloy, exhibits superior mechanical properties and great formability under low temperature compared with general alloys. Numerous efforts have been applied to develop these materials for biomedical devices, high efficiency transformers, and for products that require high-strength materials, such as golf clubs.

Working with the lab of Yale professor Jan Schroers, Taylor pioneered the use of BMGs as catalysts in fuel cells. BMGs have the strength of metal, but can be shaped like a plastic, so they can be used to form nanowires and achieve high-surface areas. Increasing surface area leads to an increased performance in current density, because all of the electrochemical reactions are on the surface.

http://phys.org/news/2015-12-bulk-metallic-glass-maximizing-surface.html#jCp



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Microscopic animals inspire innovative glass research

 

September 3, 2015

 Prof. Juan de Pablo's 20-year exploration of the unusual properties of glass began, oddly enough, with the microscopic animals known as water bears.

The creatures, which go by the more formal name of tardigrades, have a remarkable ability to withstand extreme environments of hot and cold, and even the vacuum of space. When de Pablo read about what happens when scientists dry out tardigrades, then revive them with water years later, his interest was piqued.

 "When you remove the water, they very quickly coat themselves in large amounts of glassy molecules," says de Pablo, the Liew Family Professor in Molecular Engineering at the University of Chicago. "That's how they stay in this state of suspended animation."

His passion to understand how glass forms in such exotic settings helped lead de Pablo and his fellow researchers to the unexpected discovery of a new type of glass.

 http://phys.org/news/2015-09-microscopic-animals-glass.html#jCp



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Super-tough glass based on mollusk shells

January 29, 2014

In the future, if you drop a glass on the floor and it doesn't break, thank a mollusk. Inspired by shellfish, scientists at Montreal's McGill University have devised a new process that drastically increases the toughness of glass. When dropped, items made using the technology would be more likely to deform than to shatter.

http://www.gizmag.com/mollusk-nacre-tougher-glass/30654/?li_source=LI&li_medium=default-widget




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Tough-as-nails ceramic inspired by mother-of-pearl

 

March 25, 2014

 http://www.gizmag.com/mother-of-pearl-nacre-ceramic/31367/?li_source=LI&li_medium=default-widget

Although you may know it simply as the shiny iridescent stuff on the inside of mollusk shells, mother-of-pearl (or nacre) is a remarkable material. It allows those shells, which otherwise consist almost entirely of brittle calcium carbonate, to stand up to the abuses of life in the sea. Now, a team led by the Laboratoire de Synthèse et Fonctionnalisation des Céramiques (CNRS) in Paris, has copied the structure of nacre to create a ceramic material that's almost 10 times stronger than conventional ceramics.
Natural nacre consists of layers of microscopic tablet-like blocks, that have wavy edges not unlike jig-saw puzzle pieces. This means that when the material is subjected to mechanical stress, any cracks that start to form in the boundary lines between the tablets have to follow a very circuitous route. As a result, all but the largest cracks simply just peter out.
Scientists at Montreal's McGill University recently created super-strong glass, by etching nacre boundary line-like cracks in glass microscope slides. The CNRS team, however, took a different approach with the ceramic.
They started with a ceramic powder, made up of microscopic alumina platelets. That powder was suspended in water, and the resulting solution was then frozen. The ice crystallization process caused the platelets to self-assemble into stacks, the boundaries between which were similar to the wavy boundaries between nacre tablets. A high-temperature process was then used to increase the density of the material, thus removing the water.
In lab tests of the resulting ceramic, it was found that cracks had great difficulty spreading through it – as is the case with real nacre.
Additionally, the scientists state that the process should work with any type of ceramic powder (not just alumina), and it should be easy to scale up to industrial production levels. Besides simply making existing types of ceramic items stronger, the technology could also allow them to stay at the same strength, but be made much smaller.


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New kind of smart-glass changes color and produces electricity

 

April 9, 2015

 

Many types of smart-glass have been created, some that display a tint when it gets sunny out, others that change to prevent heat from coming in, etc. In this new effort, the researchers sought to add something new—production of electricity. Realizing that many types of glass are subjected to rain and wind, they sought to find a way to coat a window that would take advantage of triboelectrics—capturing the energy in static electricity that occurs when two materials meet.

http://phys.org/news/2015-04-kind-smart-glass-electricity.html



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Vanadium dioxide 'smart glass' can be activated to block infrared light while remaining transparent to visible light

Nov 29, 2013


 'Smart glass' can switch from transparent to opaque at the flick of a switch and is increasingly used in cars, aircraft and homes to reduce the Sun's glare and filter out infrared light and heat. Masaki Nakano and colleagues from the RIKEN Center for Emergent Matter Science have now used vanadium dioxide to make a transparent material that can be activated to block infrared light without affecting its transparency for visible light.


Vanadium dioxide is a well-known thermochromic material that is transparent below about 30 °C and reflects infrared light above 60 °C. This transition is related to a change in crystal structure that also results in a shift from electrically insulating properties at lower temperatures to conductive properties at higher temperatures.

http://phys.org/news/2013-11-vanadium-dioxide-smart-glass-block.html#jCp

 

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Mid-infrared irradiation keeps nanocrystals bright

03 December 2021

 

Mid-infrared pulses stimulate fast neutralization of photocharged colloidal nanocrystals, which suppresses blinking of a single nanocrystal’s photoluminescence. 

https://www.nature.com/articles/s41565-021-01029-5

 

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Ultrathin metasurface lenses do things conventional optics can't

 

September 8, 2015

http://www.gizmag.com/ultrathin-metamaterial-lens-jpl-caltech/39298/?li_source=LI&li_medium=default-widget

Once, the only way to manipulate light was with the use of a transparent glass or plastic lens whose shape and makeup determined such things as focus, magnification, and polarity. However, to incorporate all of these properties in the one optical system required a large and complex collection of multiple lenses to achieve. Now researchers working at NASA's Jet Propulsion Laboratory (JPL) and the California Institute of Technology (Caltech) have created a flat silicon metamaterial lens that manages all of these thing in a microminiaure device that electromagnetically controls the properties of any light passing it.

Using an arrangement of silicon nanopillars organized into a honeycomb pattern to form a "metasurface" able to control the direction and attributes of light waves, the new device may one day be mass-produced using much the same methods employed to create computer chips today.
As such, the researchers believe that applications for their creation may include cutting-edge microscopes, displays, sensors, and cameras that could all take advantage of the superior characteristics of high-quality lenses at a fraction of the price.

 

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Processing technology to improve the electrical properties of glass ceramic circuit boards

July 8, 2015

As you ease your foot off the accelerator, a radar sensor detects how far away you are from the other cars and intelligently adjusts your speed appropriately. Technology like this is already helping to improve road safety and is set to become even more commonplace. From an electrical engineering perspective, manufacturing sensors of this kind is an extremely tricky process: the sensors have to be able to operate at very high frequencies but still need to be precise and efficient. TU Wien has now managed to develop a new processing technology for the high-precision nanostructuring of glass ceramic circuit boards. This means that the material properties can be adjusted, thereby significantly improving the electromagnetic behaviour of the sensor.


http://phys.org/news/2015-07-technology-electrical-properties-glass-ceramic.html#nRlv

 
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Scientists make crucial breakthrough that could revolutionize solar energy: '[This] might open up new avenues'

 

April 4, 2024

 

Sunlight is a reliable energy source to supplement our energy needs, and this recent discovery will multiply the benefits of solar power.

 

Solar panels are one of many clean energy solutions that provide much-needed electrical energy to electrical grids worldwide. Solar panels function by allowing sunlight to shine on specialized receptors known as photovoltaic cells, or PV cells, which in turn transform the energy within the sunlight into an electrical current run through wires into the grid. 

 

A research team from Shanghai University of Engineering Science in China has developed a new glass-ceramic material to increase the energy absorption of solar panels, according to The Independent. 

 

But how does this all work? Sunlight contains multiple types of light, or wavelengths, from infrared (heat), to visible (colors), and to ultraviolet (aka UV, which causes sunburns on skin). 

 

https://www.thecooldown.com/green-tech/glass-ceramic-solar-panels-energy-conversion/

 

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Stretchable, transparent heater made from metallic glass

January 7, 2016

Researchers have fabricated a stretchable and transparent electrode that can be used for applications such as heating parts of the body and defrosting the side view mirrors on cars. It is the first stretchable electronics device made from metallic glass, which is a metal that has an amorphous (disordered) structure like that of a glass, instead of the highly ordered crystalline structure that metals normally have.

http://phys.org/news/2016-01-stretchable-transparent-heater-metallic-glass.html

 
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SCHOTT Debuts New Ceramic Cooktop Glass That Can Double as Full Color Video Display

September 16, 2024

https://thespoon.tech/schott-debuts-new-ceramic-cooktop-glass-that-can-double-as-full-color-video-display/

 

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The Glass Age, Part 1: Flexible, Bendable Glass

https://www.youtube.com/watch?v=12OSBJwogFc

 

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Some question the toxicity in some of the glass mentioned in the following video titled "The Glass Age."


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The Glass Age, Part 2: Strong, Durable Glass

 

https://www.youtube.com/watch?v=13B5K_lAabw



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World's Strongest Materials - New Full History HD Documentary

 

Nov 12, 2014

https://www.youtube.com/watch?v=rwVlOLnqNaQ

 
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Yale Engineers Create a New Kind of Metallic Glass

December 7, 2017

 

 

Engineers from Yale University have discovered a method for creating a new kind of metallic glass, a class of materials made from complex alloys.

 
https://scitechdaily.com/yale-engineers-create-a-new-kind-of-metallic-glass/

 

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Micro Fuel Cell of Bulk Metallic Glass

 

November 28, 2012

 

 

Micro fuel cells (MFC) have been identified as promising alternative power sources for portable electronics. Current MFC fabrication technologies rely on complex micromachining of materials such as silicon, stainless steel, and ceramics. The challenge remains to identify effective low-cost materials and fabrication methods.

 

André D. Taylor, Yale University, USA, and colleagues have demonstrated the feasibility of economic fabrication of MFCs using bulk metallic glass (BMG). BMGs are metal alloys with disordered atomic structure, like that of glass, rather than the highly ordered, crystalline structure common to metals. The plastic-like processing ability of BMG allowed it to be molded or embossed into a vast range of complex shapes by thermoplastic forming (TPF). For example, the team used TPF to fabricate the hierarchical architecture of the porous supported Pt-BMG nanowire catalytic layer (pictured). TPF-based embossing of Zr-BMG was used to create flow field channels with high precision and well-defined corners and walls.

 

This plastic-like property of BMG is unique amongst metals due to BMGs’ viscous softening above the glass transition.

 

Such TPF-based techniques can be carried out in parallel in short time frames, which permits a fast and inexpensive manufacturing process that could also find applications in the fields of micro fluidics, heterogeneous catalysis, sensors, and other electrochemical systems.

 
https://www.chemistryviews.org/details/news/3758651/Micro_Fuel_Cell_of_Bulk_Metallic_Glass_/

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 Space-Age Materials, One Atomic Layer at a Time

 08.10.12

 http://www.nasa.gov/topics/technology/features/atomic-layer_prt.htm


 A technologist at NASA's Goddard Space Flight Center in Greenbelt, Md., however, is experimenting with an emerging technology that might provide another, perhaps more effective, technique for defending sensitive spacecraft components from the high-velocity bombardments.

Vivek Dwivedi and his collaborator, chemical engineering professor Raymond Adomaitis from the University of Maryland, College Park, are using atomic layer deposition (ALD) — a rapidly evolving technology for coating plastics, semiconductors, glass, Teflon, and a plethora of other materials — to create a new super-strong, ultra-thin coating made of tiny tubes of boron nitride, similar in appearance to the bristles on a toothbrush.

''Crystalline boron nitride is one of the hardest materials in the world,'' Dwivedi said, making it ideal as a coating to make sensitive spacecraft component less susceptible to damage when struck by space dust, tiny rocks, and high-energy solar particles.

Atomic Layer Deposition

The ALD technique, which the semiconductor industry has adopted in its manufacturing of computer chips, involves placing a substrate material inside a reactor chamber and sequentially pulsing different types of precursor gases to create an ultrathin film whose layers are literally no thicker than a single atom.

ALD differs from other techniques for applying thin films because the process is split into two half reactions, is run in sequence, and is repeated for each layer. As a result, technicians can accurately control the thickness and composition of the deposited films, even deep inside pores and cavities. This gives ALD a unique ability to coat in and around 3-D objects. This advantage — coupled with the fact that technologists can create films at much lower temperatures than with the other techniques — has led many in the optics, electronics, energy, textile, and biomedical-device fields to replace older deposition techniques with ALD.

According to Dwivedi, if technicians use ALD to coat glass with aluminum oxide, for example, they can strengthen glass by more than 80 percent. The resulting thin films act like ''nano putty,'' filling the nanometer-scale defects found in glass — the very same tiny cracks that cause glass to break when struck by an object. ''This ALD application has profound possibilities for the next-generation crew modules,'' Dwivedi said. ''We could decrease the thickness of the glass windows without sacrificing strength.''

 

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9-Ton Slab of Glass Found in the Cave of Beit Shearim

Sep 17, 2017

https://www.youtube.com/watch?v=N_eDWi46h7o

 
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MYSTERY OF THE GREEN GLASS

Dec 26, 2016

https://www.youtube.com/watch?v=vLINtOTAoWI

 

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Is Gold Used in Red Stained Glass?

Dec 2, 2023

The secret behind the red stained glass in ancient cathedrals’ enchantment lies in its precious metal: gold. Red stained glass is captivating, and this article will introduce you to the timeless union of gold and color, from alchemy to modern art. You will discover the magic that shines through these magnificent creations as we embark on this journey together.

The Alchemy of Color: Gold and Red

Gold’s interaction with other elements is a dance of vibrant hues, and in the context of stained glass, this dance is particularly captivating. When combined with certain metal oxides during the molten glass process, gold imparts a range of red shades, each boasting its own unique character. The addition of gold chloride, for instance, infuses the glass with a warm and inviting ruby hue, evoking a sense of passion and romance. On the other hand, when gold and tin oxides are combined, the glass takes on a brilliant scarlet hue, reminiscent of a blazing fire. The alchemy of color is a delicate balance, where minute variations in the composition can yield stunningly different results.

Gilding and Silver Staining: Gold accents are achieved through gilding, where thin leaves of gold are applied to the glass surface. Silver staining is also employed to impart yellow or gold hues to specific glass pieces.

https://learnglassblowing.com/is-gold-used-in-red-stained-glass/

 

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Innovations in glass technology are driving progress in energy, sustainability, and consumer products. Here's what that looks like.

Oct 25, 2024

In laboratories and factories across the globe, developers are creating cutting-edge technologies that could reshape how we live. Behind many of these breakthroughs lies an unexpected hero: a material that has been with us for centuries and is powering the next era of high-tech industries.

Since Otto Schott invented specialty glass in 1884, the simple material has become a cornerstone of modern technology, and driving innovation. Its unique properties make it indispensable across a wide range of industries that shape our daily lives. From semiconductors to clean energy, home tech, and electric vehicles, glass is the silent enabler of progress.

Powering next-generation semiconductors

With AI on the rise, industries need more powerful microchips with increased performance to handle large amounts of data, which must be processed at high speed while consuming energy efficiently.

Glass carriers and substrates are promising materials at the heart of this revolution, enabling remarkable performance gains in chip packaging. Industry analysts predict high-end performance packaging will reach $28.4 billion by 2029, fueled by the growing adoption of AI, 5G and 6G networks, and other data-intensive technologies that will require powerful, efficient chips.

Chips packaged with glass substrates can achieve up to 40% better performance while using only half the power of their plastic-packaged counterparts.

Glass' versatility — such as customizable thermal expansion, high stiffness, ultra-smooth surfaces, electrical properties, and optical transparency — meets the demanding needs of advanced manufacturing and packaging solutions. 

Bringing smart glasses and AR to the masses

Augmented reality (AR) is set to transform industries by merging digital and physical worlds, creating interactive experiences in entertainment and gaming, and enhancing remote collaboration with interactive 3D models. As this technology evolves, its applications will broaden, fostering innovation and efficiency across various sectors, particularly when combined with emerging technologies like 5G, AI, and IoT.  

As the US leads in software and hardware innovation, the photonics industry is poised to become a key enabler of AR optics. Glass, in the form of optical waveguides, channels digital information to the eye when wearing smart glasses. Thanks to its advanced properties and characteristics, glass processing is projected to scale and lower costs in the coming years, paving the way for mass-market smart glasses.

Unlocking fusion energy

The quest for fusion energy — the holy grail of clean, limitless power — has taken a giant leap forward, and glass is at the heart of this breakthrough. Specially engineered laser glass helped researchers achieve what was once thought impossible: creating more energy from a reaction than was put into it. 

In a groundbreaking experiment at Lawrence Livermore National Laboratory, scientists used 192 powerful laser beams to replicate conditions like those at the center of the sun. The light, amplified by active laser glass and focused through precisely crafted optical glass, delivered significant energy to a tiny fuel pellet, triggering a fusion reaction that produced a net energy gain.

The fusion reaction generated 3.15 megajoules of energy, exceeding the 2.05 megajoules of laser energy delivered to the target. This net energy gain, albeit small, demonstrates that with the right technology — including advanced glass — we can replicate the sun's power on Earth. Subsequent experiments have produced even larger yields. As scientists refine fusion energy, glass will be vital in scaling up reactors, helping to focus laser light and withstanding extreme conditions, positioning it at the core of this transformative technology that could revolutionize global energy.

Advancing electric vehicles 

Today's electric cars mostly rely on lithium-ion batteries, a technology that was introduced commercially in the 1990s.  In the future, solid-state battery technology aims to advance electric vehicles even further. 

At the heart of this innovation is a surprising material: glass-ceramic powder. It boasts high conductivity, exceptional chemical and temperature stability, and improved performance. Most importantly, it enables the use of lithium metal anodes, which have ten times the storage capacity of current graphite anodes. This translates to electric vehicles that can travel up to 30% further on a single charge.

Using this technology, charging an EV to 80% in just 10 minutes is on the horizon. The road to commercialization is still long, with mass production of solid-state battery-equipped vehicles forecasted to start around 2030. Glass-ceramic will play an outsized role as adoption continues to grow.

Modernizing everyday kitchens  

Specialty glass is also redefining smart kitchens, allowing advanced technology to blend into sleek, modern designs. Recent breakthroughs in glass ceramics like SCHOTT CERAN Luminoir® TFT have allowed cooktops to display vibrant, high-resolution visuals, beyond traditional white and blue light. These materials can integrate smart displays that remain hidden when not in use, providing a clean, elegant appearance that makes cooktops smarter and more interactive without compromising design for an intelligent user experience.

The true value lies in how these surfaces enhance cooking experiences by featuring fully functional screens with perfect resolution. Information such as cooking temperatures, timers, and step-by-step recipe instructions is clearly displayed on the surface. The glass efficiently transmits light, even at low brightness, ensuring optimal visibility without excess energy consumption. This innovation promises to revolutionize kitchen design by merging cutting-edge technology with the joy of cooking. 

The story of glass in high-tech industries is a testament to human ingenuity and the power of materials science. As we continue to face global energy, sustainability, and healthcare challenges, the innovations emerging from glass-research labs worldwide offer hope and exciting possibilities. The future is as clear as a well-polished window pane — glass will play a crucial role in building a more efficient, sustainable, and innovative world.

https://www.businessinsider.com/sc/glass-technology-innovations-driving-progress-across-energy-sustainability-consumer-products?op=1

 

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The Future of Glass Technology: Innovations Shaping Our World

March 28, 2025

Glass has evolved far beyond its traditional roles in windows and bottles. Today, it’s at the heart of cutting-edge innovations—from smart devices to sustainable architecture. At Glassology, we’re passionate about the transformative potential of glass technology. Here’s a glimpse into the future:

1. Smart Glass: Windows That Think

Gone are the days when glass was just a passive barrier. Today, smart glass (or switchable glass) is redefining functionality, merging transparency with intelligence. By responding to environmental cues or user commands, this dynamic material is transforming industries—from architecture to automotive.
How It Works

Smart glass uses cutting-edge technologies to alter its properties on demand:

    Electrochromic Glass: Changes tint when a low-voltage current is applied (e.g., dimming windows to block glare).

    PDLC (Polymer Dispersed Liquid Crystal): Switches from frosted to clear instantly, ideal for privacy partitions.

    Thermochromic & Photochromic: Reacts to heat or UV light (think transition lenses for buildings).

Applications Changing the Game

    Architecture: Energy-efficient skyscrapers with self-tinting windows reduce cooling costs by up to 40%.

    Automotive: Mercedes’ "Magic Sky Control" sunroofs adjust opacity at the touch of a button.

    Healthcare: Privacy glass in hospitals protects patient confidentiality without curtains.

    Retail: Interactive storefronts display ads or turn into touchscreens.

Glassology’s Innovations

We’re pushing boundaries with:

    AI-Integrated Glass: Predictive tinting based on weather forecasts or user habits.

    Self-Powering Smart Glass: Harvests ambient energy to operate without external power.

2. Ultra-Durable Glass

The Science Behind Unbreakable Glass

Traditional glass is fragile, but next-gen innovations are changing the game:

    Gorilla Glass (Corning®): Chemically strengthened for smartphones, tablets, and automotive displays—resistant to drops and scratches.

    Liquid Glass Nanocoatings: Invisible, flexible layers that make glass self-cleaning, anti-microbial, and highly scratch-resistant.

    Laminated & Tempered Safety Glass: Used in skyscrapers and hurricane-proof windows, designed to withstand extreme impacts without shattering.

Where Ultra-Durable Glass is Making an Impact

    Consumer Electronics

        Crack-resistant smartphone screens (e.g., Gorilla Glass Victus®).

        Foldable display glass for next-gen devices.

    Architecture & Urban Design

        Bomb-resistant windows for high-security buildings.

        Hurricane- and earthquake-proof glazing for disaster-prone areas.

    Automotive & Aerospace

        Windshields that resist rock chips and extreme temperatures.

        Lightweight, ultra-strong cockpit canopies for aircraft.

    Medical & Scientific Applications

        Shatterproof lab equipment and surgical tools.

        Sterile, antimicrobial glass for hospitals.

Glassology’s Role in the Durability Revolution

We’re pioneering the next wave of ultra-strong glass with:
✔ Self-Healing Glass – Microcapsules that repair minor scratches automatically.
✔ Hybrid Glass-Ceramics – Combines the toughness of ceramics with the transparency of glass.
✔ Eco-Durable Glass – Made from recycled materials without sacrificing strength.

3. Energy-Generating Glass

How Energy-Generating Glass Works

This revolutionary technology integrates transparent solar cells into glass surfaces, allowing them to:
✔ Convert sunlight into electricity while maintaining visibility
✔ Store energy for later use through built-in transparent batteries
✔ Reduce building energy costs by up to 30%

Key technologies powering this innovation:

    Transparent Photovoltaics (TPV): Ultra-thin solar films that let light through while capturing energy

    Quantum Dot Glass: Nanocrystals that absorb UV/IR light (invisible to the eye) and convert it to power

    Perovskite Solar Cells: Next-gen materials offering higher efficiency at lower costs

Real-World Applications Changing the Game

1. Solar Skyscrapers

    The Edge in Amsterdam uses energy-generating glass to produce more power than it consumes

    Dubai’s Solar Tower features a facade that powers its entire cooling system

2. Smart Homes & Windows

    Residential windows that power household appliances

    Self-charging smart glass that adjusts tint based on sunlight

3. Transportation Innovations

    Solar glass sunroofs that extend EV range by 15-20%

    Bus stops and train stations with power-generating canopies

4. Consumer Electronics

    Smartphones and tablets with self-charging screens

    Laptop displays that harvest ambient light

Glassology’s Breakthroughs in Energy Glass

We’re pushing boundaries with:

🔋 ClearView PowerGlass™ – Our flagship product with 12% efficiency (industry-leading for transparent PV)
🌱 Eco-Generate Series – Made from 80% recycled materials without performance loss
💡 Adaptive Energy Glass – Automatically optimizes between light transmission and power generation


4. Biodegradable & Eco-Friendly Glass

The Problem with Conventional Glass

    Energy Intensive: Producing 1 ton of glass emits ~500kg of CO₂

    Recycling Limits: Only ~30% of glass gets recycled globally

    Microplastic Alternative: Many "eco" materials (like acrylic) create worse long-term pollution

Next-Gen Sustainable Glass Solutions

1. Bioactive Glass

    How it works: Made from silica and natural compounds (like calcium oxide)

    Applications:

        Medical implants that dissolve as bones heal

        Water-soluble drug capsules

        Marine-safe packaging that breaks down in seawater

2. Plant-Based Glass

    Innovators: Glassology’s PhytoGlass™ uses:

        Bamboo silica

        Algae-derived polymers

    Benefits:

        60% lower carbon footprint

        Compostable in 6-12 months

3. Self-Destructing Smart Glass

    Technology: Light-triggered molecular breakdown

    Uses:

        Temporary building facades

        Disposable medical devices

        Military applications (leave-no-trace optics)

4. Recycled Glass 2.0

Our EcoCycle Process achieves:
♻️ 95% recycled content (vs. industry standard 30%)
🔋 40% less energy than virgin glass production
Where Sustainable Glass is Making Waves

Industry
    
Application
    
Environmental Benefit

Packaging
    
100% biodegradable bottles
    
Eliminates microplastics

Construction
    
Insulation foam glass
    
Uses waste glass as raw material

Consumer Tech
    
Compostable smartphone screens
    
Reduces e-waste

Marine
    
Dissolvable fishing floats
    
Prevents ocean plastic

Glassology’s Green Mission

We’re pioneering:

🌱 Zero-Waste Production: All byproducts repurposed
🌍 Carbon-Negative Glass: Our algae-based variants absorb CO₂
🔬 Nano-Reinforced Bioglass: Strong as steel, gentle as sand

5. Holographic & AR Glass

How Holographic & AR Glass Works

This cutting-edge technology merges advanced optics with digital interfaces:
Core Technologies

    Waveguide Displays: Ultra-thin glass layers that project images directly into the user’s field of view

    Nanostructured Metasurfaces: Microscopic patterns that bend light to create 3D holograms

    AI-Powered Tracking: Real-time environment mapping for seamless AR integration

Key Features

✔ Transparent Displays – Digital overlays without obstructing visibility
✔ Touch & Gesture Control – Interact with holograms mid-air
✔ Adaptive Lighting – Adjusts brightness based on surroundings

Industry Applications

1. Retail & Advertising

    Virtual Try-Ons: See yourself in glasses or makeup via smart mirrors

    Interactive Storefronts: Walk by a display and see products come to life

2. Automotive & Transportation

    AR Windshields: Navigation arrows, hazard alerts, and speed data projected onto the road

    Holographic Dashboards: Floating controls and diagnostics

3. Healthcare & Surgery

    3D Anatomy Projections: Surgeons see real-time holograms of patient scans during operations

    AR-Assisted Diagnostics: Glass wearables that highlight medical anomalies

4. Architecture & Design

    Holographic Blueprints: Architects manipulate 3D building models in mid-air

    Virtual Renovation: See furniture and finishes in your home before buying

5. Entertainment & Gaming

    Immersive AR Concerts: Holographic performers on your coffee table

    Interactive Gaming Tables: Play chess with animated 3D pieces

Glassology’s Innovations in AR Glass

We’re leading the industry with:

🔮 Holovision™ – The world’s first mass-producible holographic glass panel
🖐️ Touchless UI – Control AR elements with hand gestures (no wearables needed)
🌐 Cloud-Connected Glass – Stream real-time data into AR environments

→ Experience our AR glass demos here

Why This Changes Everything

    Revolutionizes Human-Computer Interaction: No more screens—just augmented reality

    Enhances Safety: Critical information appears where you need it (e.g., driving, surgery)

    Reduces Physical Waste: Digital displays replace printed signs and labels

The Future of AR Glass

Coming soon from Glassology R&D:
👓 Social AR Lenses – See friends’ avatars in real-world settings
🛍️ AI Shopping Assistants – Virtual clerks appear in store windows
🏙️ Smart City Glass – Bus stops that show routes, ads, and emergency alerts

Why Glassology?

At Glassology, we blend science, design, and sustainability to push the boundaries of glass technology. Explore our solutions at https://www.glassologytech.com/ and join us in redefining the future—one pane at a time.

What glass innovation excites you most? Comment below!

https://www.glassologytech.com/blogs/news/the-future-of-glass-technology-innovations-shaping-our-world

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Self-cleaning glass uses electric field to remove dust particles within seconds

 

August 7, 2025

 

https://techxplore.com/news/2025-08-glass-electric-field-particles-seconds.html

 

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Scratch-resistant sapphire nanostructures with anti-glare, anti-fogging, and anti-dust properties

2025

 

 
Abstract

Although there has been significant interest in the novel material properties of bio-inspired nanostructures, engineering them to become mechanically durable remains a significant challenge. This work demonstrates the fabrication of sapphire nanostructures with anti-glare, anti-fogging, anti-dust and scratch-resistant properties. The fabricated nanostructures demonstrated a period of 330 nm and an aspect ratio of 2.1, the highest reported for sapphire thus far. The nanostructured sapphire sample exhibited broadband and omnidirectional antireflection properties, with an enhanced transmission of up to 95.8% at a wavelength of 1360 nm. The sapphire nanostructures also exhibited enhanced wetting performance and could mitigate fogging from water condensation or repel water droplets. Furthermore, owing to their sharp features, the fabricated structures could prevent particulate adhesion and maintain a 98.7% dust-free surface area solely using gravity. Furthermore, nanoindentation and scratch tests indicated that the sapphire nanostructures have an indentation modulus and hardness of 182 GPa and 3.7 GPa, respectively, which are similar to those of bulk glass and scratch-resistant metals such as tungsten. These sapphire nanostructures can be fabricated using high-throughput nanomanufacturing techniques and can find applications in scratch-resistant optics for photonics, electronic displays, and protective windows.

https://pubs.rsc.org/en/content/articlelanding/2025/mh/d4mh01844c

 

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Scientists Replicate Self-Cleaning Coating of Insects' Eyes

 

Oct 19, 2020

 

The protective coating might find applications in diverse areas of economics including medicine, nanoelectronics, and the automotive and textile industries

 

https://www.labmanager.com/scientists-replicate-self-cleaning-coating-of-insects-eyes-24108 

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World of Glass 2025 Report

The Decarbonization Equation

January 6, 2025

https://www.glassmagazine.com/article/world-glass-2025-report

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Glass Global News

https://www.glassglobal.com/news/0-0-0-1.html
 

 

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Chapter 9: Light Energy

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 We can use light and energy for an abundance of new technology applications. 

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Physicists make first observation of the pushing pressure of light

 

Jun 02, 2015

 

For more than 100 years, scientists have debated the question: when light travels through a medium such as oil or water, does it pull or push on the medium? While most experiments have found that light exerts a pulling pressure, in a new paper physicists have, for the first time, found evidence that light exerts a pushing pressure.

 http://phys.org/news/2015-06-physicists-pressure.html?utm_source=menu&utm_medium=link&utm_campaign=item-menu


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New route for switching magnets using light

September 16, 2015

An international team led by Radboud University physicists has discovered that reversing the poles of magnets must be possible without a heating or a magnetic field.. A strong pulse of light can have a direct effect on the strong quantum mechanical 'exchange interaction', therefore changing the magnetism (Nature Communications, 16 September 2015).

 http://phys.org/news/2015-09-route-magnets.html#jCp


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Twisting neutrons: Orbital angular momentum of neutron waves can be controlled

September 23, 2015

It's easy to contemplate the wave nature of light in common experience. White light passing through a prism spreads out into constituent colors; it diffracts from atmospheric moisture into a rainbow; light passing across a sharp edge or a diffraction grating creates an interference pattern. It's harder to fathom the wave behavior of things usually thought of as particles, such as electrons and atoms. And yet these matter waves play a role in physics and in technology. For example, electron beams, manifested as waves, provide an important form of microscopy.

Read more at: http://phys.org/news/2015-09-neutrons-orbital-angular-momentum-neutron.html#jCp






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Slow light speeds up the microscopic world

September 17, 2015

A team of researchers from the University of St Andrews and the University of York has slowed down the speed of light in a process which could have major applications in fundamental science and medical diagnosis.

http://phys.org/news/2015-09-microscopic-world.html#jCp



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Physicists stop and store light traveling in an optical fiber

 

 May 11, 2015 

 

  Researchers at the Kastler Brossel Laboratory in Paris have managed to store light that propagates in an optical fiber and to release it later on demand. By causing interaction between the traveling light and a few thousand atoms in the vicinity, they demonstrated an all-fibered memory.

 http://phys.org/news/2015-05-physicists-optical-fiber.html?utm_source=menu&utm_medium=link&utm_campaign=item-menu

 

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Physicists Prove Teleportation of Energy Is Possible

 

February 4, 2010

 Over five years ago, scientists succeeded in teleporting information. Unfortunately, the advance failed to bring us any closer to the Star Trek future we all dream of. Now, researchers in Japan have used the same principles to prove that energy can be teleported in the same fashion as information. Rather than just hastening the dawn of quantum computing, this development could lead to practical, significant changes in energy distribution.

http://www.popsci.com/science/article/2010-02/physicists-prove-teleportation-energy-theoretically-possible

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 Physicists break distance record for quantum teleportation

September 22, 2015
 

Researchers at the National Institute of Standards and Technology (NIST) have "teleported" or transferred quantum information carried in light particles over 100 kilometers (km) of optical fiber, four times farther than the previous record.

 http://phys.org/news/2015-09-physicists-distance-quantum-teleportation.html#jCp

 

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MIT Pioneers Quantum Light Source for Optical Quantum Computers and Teleportation Devices for Communication

 

June 25, 2023

 

https://scitechdaily.com/mit-pioneers-quantum-light-source-for-optical-quantum-computers-and-teleportation-devices-for-communication/

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Image captures light as both wave and particle for very first time

 

March 2, 2015

In 1905, Albert Einstein provided an explanation of the photoelectric effect – that various metals emit electrons when light is shined on them – by suggesting that a beam of light is not simply a wave of electromagnetic radiation, but is also made up of discrete packets of energy called photons. Though a long accepted tenet in physics, no experiment has ever directly observed this wave/particle duality. Now, however, researchers at the École polytechnique fédérale de Lausanne (EPFL) in Switzerland claim to have captured an image of this phenomenon for the first time ever.

To achieve this, a team of researchers led by Assistant Professor Fabrizio Carbone at EPFL has performed an experiment using electrons to image light.
In essence, the team used extremely short (femtosecond) pulses of laser light directed at a miniscule nanowire made of silver and suspended on graphene film that acted as an electrical isolator (or metal-graphene dielectric). The laser light pumped energy into the system that then directly affected the charged particles in the nanowire, causing them to vibrate and effectively making the nanowire behave as what is known as a quasi-1D plasmonic nanoantenna.

In other words, the nanowire acted as a tiny antenna that generated radiation patterns in sympathy with the received laser excitation. This laser light then oscillated back-and-forth between the two ends of the nanoantenna and, in so doing, set up a standing wave of surface plasmon polaritons (electromagnetic waves that travel along the surface of a metal-dielectric or metal-air interface) in the wire.
Put simply, the light traveled along the wire in two opposite directions and, when these waves bounced back to the middle, they intersected with each other to form a new wave that appeared to be standing in place. This standing wave, radiating around the nanowire, then became the source of light used in the experiment.
Next, the researchers aimed a stream of electrons into the field generated around the nanowire, and used them to image the standing wave of light. When the electrons intermingled with the restrained light contained on the nanowire – that is, where they crashed into individual photons – they either sped up (gained energy) or slowed down (lost energy).

The team then used an imaging filter to select out only those electrons that had gained energy, and focused a UTEM (ultrafast transmission electron microscopy) instrument on these to image where each of the changes in energy state occurred, thereby allowing them to visualize the standing wave and make visible the physical makeup of the wave-nature of the light.

Simultaneously, this also demonstrated the particle nature of the imaged light by demonstrating that the change in speed of the interacting electrons and photons shows as an exchange of energy "packets" (quanta) between the electrons and the photons. This demonstrated that the light on the nanowire was also behaving as particles.

"This experiment demonstrates that, for the first time ever, we can film quantum mechanics – and its paradoxical nature – directly," said Professor Carbone.


 http://www.gizmag.com/first-photograph-light-particle-wave/36361/

 

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Video camera could record indefinitely, powered only by light from the image it captures

  

April 16, 2015

 By using the light reflected from the object being recorded, researchers claim to have created a prototype video camera that could potentially record indefinitely under its own power. By incorporating energy-harvesting photodiodes within the pixels of its image-capture array, the new camera produces self-sustaining electrical power while simultaneously capturing video footage.

 http://www.gizmag.com/self-powered-video-camera-photodiode-pixels/37025/

 

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Optical metacage blocks light from entering or escaping

 

December 2, 2015

 

Physicists have built a nanowire cage that blocks one or more wavelengths of light from either entering or escaping, yet allows liquids and gases to pass through the small gaps between the nanowires. The "optical metacage" takes advantage of the optical properties of nanowire structures, and could have applications including protecting microorganisms from radiation, optically shielding nanophotonics components, and laser-driven drug delivery.

http://phys.org/news/2015-12-optical-metacage-blocks.html

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Topological spin textures: Scientists use micro-structured materials to control light propagation

August 16, 2025

 

Topological spin textures, spatially organized patterns linked to the intrinsic angular momentum of particles, have proved to be highly advantageous for the development of spintronics and quantum technologies. One of the most studied among these textures are skyrmionic textures, which are two-dimensional and stable patterns of spin orientation. Recently, the study of skyrmionic textures has gained significant attention in the field of optics and photonics, revealing novel physical properties and promising potential applications. 

 

https://phys.org/news/2025-08-topological-textures-scientists-micro-materials.html 

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Ringing in a new way to measure and modulate trapped light

 

December 22, 2015 

 

 Researchers working at the National Institute of Standards and Technology (NIST) have developed a novel way to noninvasively measure and map how and where trapped light vibrates within microscale optical resonators.

The new technique not only makes for more accurate measurements but also allows scientists to fine-tune the trapped light's frequency by subtly altering the shape of the resonator itself.

 

http://phys.org/news/2015-12-modulate.html

 

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Stopped-light nanolasing in optical magic-angle graphene

 

16 August 2021

 

An optical analogue of magic-angle twisted graphene bilayer gives rise to rigorously stopped light, which coupled with gain allows for a new type of a nanolaser with remarkable figures of merit.

https://www.nature.com/articles/s41565-021-00960-x

 

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Researchers discover new way to turn electricity into light, using graphene

  

 June 13, 2016

 

By slowing down light to a speed slower than flowing electrons, researchers create a kind of optical “sonic boom”

 

When an airplane begins to move faster than the speed of sound, it creates a shockwave that produces a well-known “boom” of sound. Now, researchers at MIT and elsewhere have discovered a similar process in a sheet of graphene, in which a flow of electric current can, under certain circumstances, exceed the speed of slowed-down light and produce a kind of optical “boom”: an intense, focused beam of light. 

 

https://energy.mit.edu/news/researchers-discover-new-way-turn-electricity-light-using-graphene-2/

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Light-matter interaction: broken symmetry drives polaritons

January 12, 2024

 
 An international team of scientists provide an overview of the latest research on light-matter interactions. A team of scientists from the Fritz Haber Institute, the City University of New York and the Universidad de Oviedo has published a comprehensive review article in the scientific journal, Nature Review Materials". In this article, they provide an overview of the latest research on polaritons, tiny particles that arise when light and material interact in a special way.

 

in recent years, researchers worldwide have discovered that there are different types of polaritons. Some of them can trap light in a very small space, about the size of a nanometer. That's about 80,000 times thinner than a human hair!

 

The scientists report in their article that these special polaritons can arise in certain crystals. When the light in these crystals generates special vibrations - the researchers call this "phonons" - these special polaritons are created. Interestingly, they also found that the less symmetric the crystal is, the better the whole thing works. This leads to new and exciting possibilities for controlling light in the smallest space.

 

In their article, the scientists provide an overview of the latest research findings and discuss how these new insights could be used in the future. They believe that this work could help develop new materials that can use light in innovative ways.

 

This fundamental research could therefore have a major impact on many areas, from the development of new technologies to the improvement of existing devices. It's an exciting step forward in the world of nanotechnology!

 

https://www.fhi.mpg.de/1440498/2024-01-12-Light-matter-interaction

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 Tiny gears increase light-to-work conversion efficiency by five orders of magnitude (w/ video)
 

August 17, 2015

 

 

 

 Scientists have demonstrated that pinwheel-shaped microgears floating on a liquid surface can rotate at speeds of up to 300 r.p.m. when illuminated by an ordinary LED. This light-driven motion, which arises because the light creates a tiny temperature difference and, subsequently, a surface tension difference in the surrounding fluid, is about five orders of magnitude more efficient than other mechanisms that convert light into work. As the effect is not size-dependent, the scientists expect that the system could be scaled to both the macroscale and the nanoscale.

http://phys.org/news/2015-08-tiny-gears-light-to-work-conversion-efficiency.html#jCp

 

 

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Microdrones With Light-Driven Nanomotors

April 29, 2022

 

Physicists at the University of Würzburg have propelled micrometer-sized drones significantly smaller than red blood cells, exerting precise control, using only light.

 

A hand-held laser pointer produces no noticeable recoil forces when it is "fired" — even though it emits a directed stream of light particles. The reason for this is its very large mass compared to the very small recoil impulses that the light particles cause when leaving the laser pointer.

 

However, it has long been clear that optical recoil forces can have a very large effect on correspondingly small particles. For example, the tails of comets point away from the Sun partly due to light pressure. The propulsion of light spacecrafts via light sails has also been discussed, most recently in connection with the "Star Shot" project, in which a fleet of miniature spacecrafts is to be sent to Alpha Centauri.

 

In the journal Nature Nanotechnology, Würzburg physicists led by Professor Bert Hecht (Chair of Experimental Physics 5, Nano-Optics Group) have now shown for the first time that it is possible to not only efficiently propel micrometer-sized objects in an aqueous environment with light, but also to control them precisely on a surface with three degrees of freedom (two translational plus one rotational).

 

In doing so, they were inspired by ordinary quadcopter drones, where four independent rotors allow complete control of the movements. Such control possibilities offer completely new options for the usually extremely difficult handling of nano- and micro-objects, for example, for the assembly of nanostructures, for the analysis of surfaces with nanometer precision, or in the field of reproductive medicine.

 

https://www.techbriefs.com/component/content/article/45712-microdrones-with-light-driven-nanomotors

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 A molecular light switch?... Just add water

December 16, 2015

 

 A bit of stray moisture during an experiment tipped off scientists about the strange behavior of a complex oxide material they were studying—shedding light on its potential for improving chemical sensors, computing and information storage. In the presence of a water molecule on its surface, the layered material emits ultraviolet light from its interior. A team of researchers from Drexel University, the University of Pennsylvania, the University of California at Berkeley, and Temple University recently published its discovery that it is possible to control UV light production via a chemical reaction that functions like flipping a light switch.

 

 http://phys.org/news/2015-12-molecular.html

 

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Science shocker: Light can vaporize water without heat, says MIT study

 

Apr 24, 2024

 

The photomolecular effect could explain a long-standing discrepancy in climate science – the observed higher absorption of sunlight by clouds than conventional models predict.

 

Light-triggered evaporation

 

This research, published in the journal PNAS, sheds light on a previously unknown mechanism – the photomolecular effect. The MIT team, led by Professor Gang Chen, demonstrated that light striking the water’s surface can directly liberate water molecules, causing them to evaporate into the air. This effect occurs independently of heat, upending our long-held belief that thermal energy is the sole driver of evaporation.

 

https://interestingengineering.com/energy/science-shocker-light-can-vaporize-water-without-heat-says-mit-study 

 

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Scientists Just Made Molecules Do the Impossible With Light

 

December 27, 2024

 

By combining photochemical reactions with molecular self-assembly, scientists have achieved the impossible: using light to create molecular fits that defy thermodynamic equilibrium.

 

This groundbreaking approach could revolutionize technology and medicine by leveraging sunlight to develop innovative materials, smart drugs, and dynamic systems mimicking the non-equilibrium processes in living organisms.

 

Harnessing Light for Molecular Manipulation

 

Using a creative combination of light-driven (photochemical) reactions and molecular self-assembly, a research team led by Prof. Alberto Credi at the University of Bologna has achieved a groundbreaking feat. They successfully inserted a thread-like molecule into the cavity of a ring-shaped molecule, forming a high-energy structure that would normally be impossible under thermodynamic equilibrium. In essence, light enables the creation of molecular configurations that nature cannot achieve on its own.

 

“We have shown that by administering light energy to an aqueous solution, a molecular self-assembly reaction can be prevented from reaching a thermodynamic minimum, resulting in a product distribution that does not correspond to that observed at equilibrium,” says Alberto Credi. “Such a behavior, which is at the root of many functions in living organisms, is poorly explored in artificial molecules because it is very difficult to plan and observe. The simplicity and versatility of our approach, together with the fact that visible light – i.e., sunlight – is a clean and sustainable energy source, allow us to foresee developments in various areas of technology and medicine.”

  

https://scitechdaily.com/scientists-just-made-molecules-do-the-impossible-with-light/

 

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Scientists Control Atoms With Light and It Could Change Chemistry and Physics Forever

December 27, 2024

 

Scientists have successfully manipulated quantum systems with extreme ultraviolet light pulses, achieving precise control of atomic structures and quantum states.

 

This method, demonstrated at Italy’s Elettra Synchrotron, could revolutionize chemical processes and pharmaceutical manufacturing by allowing light to direct chemical reactions.

 

https://scitechdaily.com/scientists-control-atoms-with-light-and-it-could-change-chemistry-and-physics-forever/

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Nanostructured device stops light in its tracks

 

April 29, 2021

 

MIT researchers develop compact on-chip device for detecting electric-field waveforms with attosecond time resolution. 

 

Understanding how light waves oscillate in time as they interact with materials is essential to understanding light-driven energy transfer in materials, such as solar cells or plants. Due to the fantastically high speeds at which light waves oscillate, however, scientists have yet to develop a compact device with enough time resolution to directly capture them.

 

Now, a team led by MIT researchers has demonstrated chip-scale devices that can directly trace the weak electric field of light waves as they change in time. Their device, which incorporates a microchip that uses short laser pulses and nanoscale antennas, is easy to use, requiring no special environment for operation, minimal laser parameters, and conventional laboratory electronics.

 

The team’s work, published earlier this month in Nature Photonics, may enable the development of new tools for optical measurements with applications in areas such as biology, medicine, food safety, gas sensing, and drug discovery.

 

“The potential applications of this technology are many,” says co-author Phillip Donnie Keathley, group leader and Research Laboratory of Electronics (RLE) research scientist. “For instance, using these optical sampling devices, researchers will be able to better understand optical absorption pathways in plants and photovoltaics, or to better identify molecular signatures in complex biological systems.”

 

https://news.mit.edu/2021/nanostructured-device-stops-light-its-tracks-0429

 

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Chip-Based Optical Tweezers Levitate Nanoparticles in a Vacuum

21 October 2021

 

WASHINGTON — Researchers have created tiny chip-based optical tweezers that can be used to optically levitate nanoparticles in a vacuum. Optical tweezers — which employ a tightly focused laser beam to hold living cells, nanoparticles and other objects — can be used for a variety of precision measurements and sensing applications. However, these optical traps are usually produced with bulky optical components. 

 

“By using an ultrathin metalens, we reduced the diameter of the focusing lens from about 25 mm to about 0.4 mm,” said research team leader Tongcang Li from Purdue University. “The chip-based design can be used to create an integrated and flexible optical system for studying near-surface forces by trapping an object less than 1 micrometer away from a surface. It might also be useful for trapping cold atoms in a vacuum to study quantum processes.”

 

In Optica, Optica Publishing Group’s journal for high-impact research, researchers at Purdue University and Pennsylvania State University report the first realization of on-chip optical levitation in a vacuum with an ultrathin metalens.  Accomplishing this feat in a vacuum helps improve the sensitivity of the system.

 

“Optically levitated particles can be used to create accelerometers and gyroscopes that could potentially be used in navigation,” said Li. “Scientists are also using optically levitated particles to search for dark matter and dark energy and to study gravity at short distances, which will deepen our understanding of nature.”

https://www.optica.org/about/newsroom/news_releases/2021/chip-based_optical_tweezers_levitate_nanoparticles/

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Researchers discover new limit of trapping light at the nanoscale

 

31 August 2021

 

Physicists from the University of Southampton and ETH Zürich have reached a new threshold of light-matter coupling at the nanoscale.

 

The international research, published this week in Nature Photonics, combined theoretical and experimental findings to establish a fundamental limitation of our ability to confine and exploit light.

 

The collaboration focussed on photonic nano-antennas fabricated in ever reducing sizes on the top of a two-dimensional electron gas. The setup is commonly used in laboratories all over the world to explore the effect of intense electromagnetic coupling, taking advantage of the antennas? ability to trap and focus light close to electrons.

 

Professor Simone De Liberato, Director of the Quantum Theory and Technology group at the University of Southampton, says: "The fabrication of photonic resonators able to focus light in extremely small volumes is proving a key technology which is presently enabling advances in fields as different as material science, optoelectronics, chemistry, quantum technologies, and many others.

 

"In particular, the focussed light can be made to interact extremely strongly with matter, making electromagnetism non-perturbative. Light can then be used to modify the properties of the materials it interacts with, thus becoming a powerful tool for material science. Light can be effectively woven into novel materials."

 

Scientists discovered that light could no longer be confined in the system below a critical dimension, of the order of 250nm in the sample under study, when the experiment started exciting propagating plasmons. This caused waves of electrons to move away from the resonator and spill the energy of the photon.

 

Experiments performed in the group of Professors Jéréme Faist and Giacomo Scalari at ETH Zürich had obtained results that could not be interpreted with state-of-the-art understanding of light-matter coupling. The physicists approached Southampton?s School of Physics and Astronomy, where researchers led theoretical analysis and built a novel theory able to quantitatively reproduce the results.

 

Professor De Liberato believes the newfound limits could yet be exceeded by future experiments, unlocking dramatic technological advances that hinge on ultra-confined electromagnetic fields.

 

"It has been said that proofs of impossibility are only proofs of a lack of imagination," he explains. "This is not the first time that a 'fundamental limit' on how tightly we can focus light has been discovered. The most famous is the Abbe diffraction limit, from 19th century German physicist Ernst Abbe, which says light can't be confined in a volume smaller than a cubic wavelength.

 

"Nanophotonics is a very active and successful field of research that is studying different ways to break out of Abbe limit. I think the next step will be to use some ingenuity and look for novel ways to confine light, bypassing both Abbe limit and the one we have just discovered."

 

https://www.phys.soton.ac.uk/news/6984

 

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Scientists Use Light To Trigger Magnetism in Nonmagnetic Material

May 1, 2022

 

Lasers Trigger Magnetism in Atomically Thin Quantum Materials

 

Researchers have discovered that light — in the form of a laser — can trigger a form of magnetism in a normally nonmagnetic material. This magnetism centers on the behavior of electrons. These subatomic particles have an electronic property called “spin,” which has a potential application in quantum computing. The researchers found that electrons within the material became oriented in the same direction when illuminated by photons from a laser.

https://scitechdaily.com/scientists-use-light-to-trigger-magnetism-in-nonmagnetic-material/

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Metasurfaces: Bilayer device can control many forms of polarized light

 

April 1, 2025

Researchers have created a bilayer metasurface made of two stacked layers of titanium dioxide nanostructures, opening new possibilities for structuring light.

https://www.sciencedaily.com/releases/2025/04/250401151633.htm

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“Photonic Sunflower” – Controlled by Light Alone, New Smart Materials Twist, Bend and Move

 

March 12, 2021

 

 

 

Photonic material in the shape of a flower can move in response to light, closely tracking the angle of maximum exposure.  

 

Researchers at Tufts University School of Engineering have created light-activated composite devices able to execute precise, visible movements and form complex three-dimensional shapes without the need for wires or other actuating materials or energy sources. The design combines programmable photonic crystals with an elastomeric composite that can be engineered at the macro and nano scale to respond to illumination.

 

The research provides new avenues for the development of smart light-driven systems such as high-efficiency, self-aligning solar cells that automatically follow the sun’s direction and angle of light, light-actuated microfluidic valves or soft robots that move with light on demand. A “photonic sunflower,” whose petals curl towards and away from illumination and which tracks the path and angle of the light, demonstrates the technology in a paper that appears today (March 12th, 2021) in Nature Communications.

 
https://scitechdaily.com/photonic-sunflower-controlled-by-light-alone-new-smart-materials-twist-bend-and-move/

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Controlling Light with a Material Three Atoms Thick

 

October 22, 2021

 

Most of us control light all the time without even thinking about it, usually in mundane ways: we don a pair of sunglasses and put on sunscreen, and close—or open—our window blinds.

 

But the control of light can also come in high-tech forms. The screen of the computer, tablet, or phone on which you are reading this is one example. Another is telecommunications, which controls light to create signals that carry data along fiber-optic cables.

 

Scientists also use high-tech methods to control light in the laboratory, and now, thanks to a new breakthrough that uses a specialized material only three atoms thick, they can control light more precisely than ever before.

 
https://www.caltech.edu/about/news/controlling-light-with-a-material-three-atoms-thick

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One-way light beam can be steered in different directions

 

January 11, 2016 

 

 Over the past few years, scientists have demonstrated the phenomenon of "one-way light," in which a light beam propagates in one direction only. The materials used to achieve this effect can be thought of as optical diodes, in analogy to the diodes used in electric circuits that allow an electric current to travel in one direction while prohibiting it from traveling in the opposite direction. One-way light could play an important role in integrated photonic circuits, which perform operations using beams of light instead of an electric current.

 

http://phys.org/news/2016-01-one-way.html

 

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Microdrones soar by recoiling light

 

21 April 2022

Nano-antennas generate optical recoil forces that can be used to independently control the direction and rotation of small objects.

https://www.nature.com/articles/s41565-022-01094-4

 
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Measuring how effectively light drives a molecular pump

27 June 2022

 

Information thermodynamics offers a route to measure how effectively a light-driven molecular machine converts energy from absorbed photons into pumped motion. 

https://www.nature.com/articles/s41565-022-01152-x

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 Light propagates through the surface of new photonic crystal without being scattered
 

September 18, 2015

 

 NIMS MANA researchers elucidated a new principle whereby electromagnetic waves including light propagate on the surface of a photonic crystal without being scattered.

 

 http://phys.org/news/2015-09-propagates-surface-photonic-crystal.html#nRlv

 

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Chiral plasmonic nanostructures push the limits of light manipulation on the nanoscale

April 10, 2025 

 

 

Scanning electron microscopy (SEM) image of an array formed by 45 nm colloidal Au nanoparticles self-assembled into chiral motifs, in this case triskelions, fabricated using a template-assisted self-assembly method.

https://phys.org/news/2025-04-chiral-plasmonic-nanostructures-limits-nanoscale.html

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Quantum Vacuum Breakthrough: Oxford Physicists Make Light Emerge From “Nothing”

 

June 20, 2025 

 

• Oxford scientists have simulated light interacting with “empty” space—a strange quantum effect that sounds like science fiction but is rooted in real physics.
• Incredibly, the simulation shows light being created from darkness, confirming predictions from quantum theory about the vacuum being filled with invisible, flickering particles.
• This breakthrough brings us one step closer to proving these wild effects in real-world labs, using ultra-powerful laser systems now coming online around the world.
• The research was published in Communications Physics, marking a major step in turning once-theoretical physics into testable reality.

 

https://scitechdaily.com/quantum-vacuum-breakthrough-oxford-physicists-make-light-emerge-from-nothing/ 

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Nano-architected Material Refracts Light Backward – an Important Step toward One Day Creating Photonic Circuits

2022-01-31

 

A newly created nano-architected material exhibits a property that
previously was just theoretically possible: it can refract light backward,
regardless of the angle at which the light strikes the material.

This property is known as negative refraction and it means that the refractive index—the
speed that light can travel through a given material—is negative across a portion of the
electromagnetic spectrum at all angles.

Refraction is a common property in materials; think of the way a straw in a glass of water
appears shifted to the side, or the way lenses in eyeglasses focus light. But negative
refraction does not just involve shifting light a few degrees to one side. Rather, the light is
sent in an angle completely opposite from the one at which it entered the material. This has
not been observed in nature but, beginning in the 1960s, was theorized to occur in so-called
artificially periodic materials—that is, materials constructed to have a specific structural
pattern. Only now have fabrication processes have caught up to theory to make negative
refraction a reality. 

 

"Negative refraction is crucial to the future of nanophotonics, which seeks to understand and
manipulate the behavior of light when it interacts with materials or solid structures at the
smallest possible scales," says Julia R. Greer, Caltech's Ruben F. and Donna Mettler Professor
of Materials Science, Mechanics and Medical Engineering...

https://statnano.com/index.php?ctrl=news&action=news_pdf&id=70343&lang=2

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Synthetic circuits can harvest light energy

November 13, 2017

 

Novel structures made with DNA scaffolds could be used to create solar-powered materials.

 

By organizing pigments on a DNA scaffold, an MIT-led team of researchers has designed a light-harvesting material that closely mimics the structure of naturally occurring photosynthetic structures.

 

The researchers showed that their synthetic material can absorb light and efficiently transfer its energy along precisely controlled pathways. This type of structure could be incorporated into materials such as glass or textiles, enabling them to harvest or otherwise control incoming energy from sunlight, says Mark Bathe, an associate professor of biological engineering at MIT.

 

“This is the first demonstration of a purely synthetic mimic of a natural light-harvesting circuit that consists of densely packed clusters of dyes that are precisely organized spatially at the nanometer scale, as found in bacterial systems,” Bathe says. One nanometer is one billionth of a meter, or 1/10,000 the thickness of a human hair.

 

https://chemistry.mit.edu/chemistry-news/synthetic-circuits-can-harvest-light-energy/

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New Nanoantenna Technology Designed to Harvest Light

November 23, 2019

 

University of Illinois Researchers Develop New Framework for Nanoantenna Light Absorption

 

Harnessing light’s energy into nanoscale volumes requires novel engineering approaches to overcome a fundamental barrier known as the “diffraction limit.”  However, University of Illinois researchers have breached this barrier by developing nanoantennas that pack the energy captured from light sources, such as LEDs, into particles with nanometer-scale diameters, making it possible to detect individual biomolecules, catalyze chemical reactions, and generate photons with desirable properties for quantum computing.

 

https://science-atlas.com/technology/new-nanoantenna-technology-designed-to-harvest-light/ 

 
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Nature’s Chaos That Powers Life: MIT Chemists Discover Why Photosynthetic Light-Harvesting Is So Efficient

 

July 5, 2023

 

https://scitechdaily.com/natures-chaos-that-powers-life-mit-chemists-discover-why-photosynthetic-light-harvesting-is-so-efficient/

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"Solid" light reveals new insights about quantum mechanics

 

September 18, 2014

 

 

 

Researchers at Princeton University have devised a method for giving light the properties of liquids and solids, with huge potential ramifications in the study of quantum mechanics and other areas of physics.

 

http://www.gizmag.com/solid-light-quantum-mechanics/33865/?li_source=LI&li_medium=default-widget 

 

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Physicists propose method for braiding light

 

August 22, 2016

 

http://phys.org/news/2016-08-physicists-method-braiding.html

 

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Ultrastrong coupling between light and matter

 

08 January 2019

 

Abstract

 

Ultrastrong coupling between light and matter has, in the past decade, transitioned from a theoretical idea to an experimental reality. It is a new regime of quantum light–matter interaction, which goes beyond weak and strong coupling to make the coupling strength comparable to the transition frequencies in the system. The achievement of weak and strong coupling has led to increased control of quantum systems and to applications such as lasers, quantum sensing, and quantum information processing. Here we review the theory of quantum systems with ultrastrong coupling, discussing entangled ground states with virtual excitations, new avenues for nonlinear optics, and connections to several important physical models. We also overview the multitude of experimental setups, including superconducting circuits, organic molecules, semiconductor polaritons, and optomechanical systems, that have now achieved ultrastrong coupling. We conclude by discussing the many potential applications that these achievements enable in physics and chemistry.

 
https://www.nature.com/articles/s42254-018-0006-2

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Groundbreaking experiment aims to create matter from light

 

May 18, 2014

 

Researchers at Imperial College London have devised a method of achieving light to matter transformation at power levels orders of magnitude lower than previously thought possible...

 

 http://www.gizmag.com/experiment-to-turn-light-into-matter/32107/?li_source=LI&li_medium=default-widget

 

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Photons collide in the void: Quantum simulation creates light out of nothing

 

June 8, 2025

 

Physicists have managed to simulate a strange quantum phenomenon where light appears to arise from empty space a concept that until now has only existed in theory. Using cutting-edge simulations, researchers modeled how powerful lasers interact with the so-called quantum vacuum, revealing how photons could bounce off each other and even generate new beams of light. These breakthroughs come just as new ultra-powerful laser facilities are preparing to test these mind-bending effects in reality, potentially opening a gateway to uncovering new physics and even dark matter particles. 

https://www.sciencedaily.com/releases/2025/06/250608072527.htm

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Light and matter merge in quantum coupling

 

 August 22, 2016

  Where light and matter intersect, the world illuminates. Where light and matter interact so strongly that they become one, they illuminate a world of new physics, according to Rice University scientists.

Rice physicists are closing in on a way to create a new condensed matter state in which all the electrons in a material act as one by manipulating them with light and a magnetic field. The effect made possible by a custom-built, finely tuned cavity for terahertz radiation shows one of the strongest light-matter coupling phenomena ever observed.

The work by Rice physicist Junichiro Kono and his colleagues is described in Nature Physics. It could help advance technologies like quantum computers and communications by revealing new phenomena to those who study cavity quantum electrodynamics and condensed matter physics, Kono said.

http://phys.org/news/2016-08-merge-quantum-coupling.html#jCp

 

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For faster battery charging, try a quantum battery?

 

August 3, 2015

  
Physicists have shown that a quantum battery—basically, a quantum system such as a qubit that stores energy in its quantum states—can theoretically be charged at a faster rate than conventional batteries. This "quantum speedup" arises from quantum entanglement among multiple qubits, which essentially provides a shortcut between the qubits' uncharged and charged states, allowing for faster charging.

 

http://phys.org/news/2015-08-faster-battery-quantum.html?utm_source=menu&utm_medium=link&utm_campaign=item-menu




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Stanford breakthrough heralds super-efficient light-based computers

 

May 28, 2015

 

 

Light can transmit more data while consuming far less power than electricity, and an engineering feat brings optical data transport closer to replacing wires. 

 

Infrared light enters this silicon structure from the left. The cut-out patterns, determined by an algorithm, route two different frequencies of this light into the pathways on the right. This is a greatly magnified image of a working device that is about the size of a speck of dust. 

http://www.opli.net/opli_magazine/eo/2015/stanford-breakthrough-heralds-super-efficient-light-based-computers-may-news/

 

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Wireless Biosensor Uses Light To Monitor Cellular Communication

 

December 23, 2024

 

MIT researchers developed wireless antennas that use light to detect cell electrical signals.

 

Monitoring electrical signals in biological systems helps scientists understand how cells communicate, which can aid in the diagnosis and treatment of conditions like arrhythmia and Alzheimer’s.

But devices that record electrical signals in cell cultures and other liquid environments often use wires to connect each electrode on the device to its respective amplifier. Because only so many wires can be connected to the device, this restricts the number of recording sites, limiting the information that can be collected from cells.

MIT researchers have now developed a biosensing technique that eliminates the need for wires. Instead, tiny, wireless antennas use light to detect minute electrical signals.

https://scitechdaily.com/mit-scientists-harness-light-to-wirelessly-monitor-cellular-electrical-signals/

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New MIT chip technology uses light to make computers faster and greener

July 30, 2025

 

Researchers at MIT have found a cheaper, faster, and more efficient way to connect computer chips that use light—called photonics—with traditional chips that use electricity.

 

This could be a big step toward building the next generation of computers and communication systems, where light and electricity work together to handle massive amounts of data more efficiently.

 

As our digital world grows, so does the need for faster and more energy-efficient technology. Every year, we use more devices—from phones and GPS units to smart gadgets—all of which connect to the cloud and generate data.

 

According to MIT Professor Lionel Kimerling, this data traffic is growing a thousand times every ten years. But we can’t just keep using more and more energy to keep up.

 

https://knowridge.com/2025/07/new-mit-chip-technology-uses-light-to-make-computers-faster-and-greener/

 

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Quantum computer that 'computes without running' sets efficiency record

August 31, 2015

http://phys.org/news/2015-08-quantum-efficiency.html

Due to quantum effects, it's possible to build a quantum computer that computes without running—or as the scientists explain, "the result of a computation may be learned without actually running the computer." So far, however, the efficiency of this process, which is called counterfactual computation (CFC), has had an upper limit of 50%, limiting its practical applications.


Now in a new paper, scientists have experimentally demonstrated a slightly different version called a "generalized CFC" that has an efficiency of 85% with the potential to reach 100%. This improvement opens the doors to realizing a much greater variety of applications, such as low-light medical X-rays and the imaging of delicate biological cells and proteins—in certain cases, using only a single photon.

 

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LANL: New Quantum Device Generates Single Photons, Encodes Information

August 26, 2023
 

https://losalamosreporter.com/2023/08/26/lanl-new-quantum-device-generates-single-photons-encodes-information/

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Breakthrough rectenna converts light into DC current

September 30, 2015

Rectifying antennas – "rectennas" – are used as parasitic power capture devices that absorb radio frequency (RF) energy and convert it into usable electrical power. Constructing such devices to absorb and rectify at optical wavelengths has proved impractical in the past, but the advent of carbon nanotubes and advances in microscopic manufacturing technology have allowed engineers at the Georgia Institute of Technology to create rectennas that capture and convert light to direct electrical current. The researchers believe that their creation may eventually help double the efficiency of solar energy harvesting.

http://www.gizmag.com/carbon-nanotube-rectenna-light-electricity-georgia-tech/39631/?li_source=LI&li_medium=default-widget



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Engineers demo first processor that uses light for ultrafast communications
 

December 23, 2015 

 

 

Engineers have successfully married electrons and photons within a single-chip microprocessor, a landmark development that opens the door to ultrafast, low-power data crunching.

http://phys.org/news/2015-12-demo-processor-ultrafast.html#jCp

 

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Experiment with electrons paves the way to new power standard

 

24 January 2022

https://innovationorigins.com/en/selected/experiment-with-electrons-paves-the-way-to-new-power-standard/

 

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Internet by light promises to leave Wi-Fi eating dust

 

February 23, 2016

 

Connecting your smartphone to the web with just a lamp—that is the promise of Li-Fi, featuring Internet access 100 times faster than Wi-Fi with revolutionary wireless technology.

http://phys.org/news/2016-02-internet-wi-fi.html#nRlv

 

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Are sound waves a better way to move data?

November 6, 2015

Researchers from the University of Leeds and Sheffield University have created a way to move data through magnetic nanowires by using surface acoustic waves as the motivating force. Being developed for use in so-called racetrack solid-state memory, the researchers claim that using sound waves for data transfer should markedly increase computer processing speeds while vastly reducing power consumption. Developed by IBM, racetrack memory (where data runs up and down a track of wires like race cars, hence the name) uses the transition between different magnetic moments (directions) in the domain walls separating each of the magnetic areas found in the nanowires that make up the memory. As each transition between these areas results in an angular displacement (a change of magnetic "direction") of 90 or 180 degrees, the racetrack memory allocates a one or zero to each of these changes to represent binary data along the length of the wire.

 http://www.gizmag.com/sound-waves-racetrack-data-memory/40231/?li_source=LI&li_medium=default-widget



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What element is attracted the most to a magnet?


Jan 31, 2019

https://www.youtube.com/watch?v=COWNJghBs3Y


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Making ferrofluid from scratch


Jul 5, 2019

https://www.youtube.com/watch?v=6L8yUY-doNc

 

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Material that could revolutionize memory storage is magnetic, but not as we know it

November 2, 2015

Using a type of magnetic insulator material that normally doesn’t conduct electricity, scientists working at Stanford University and the Department of Energy’s SLAC National Accelerator Laboratory have shown that electric currents can still be made to flow along the borders of the grains within the material. This latest research not only validates a long-held belief that magnetic insulators could be used to conduct electricity, but offers a more tantalizing possibility of creating highly-efficient magnetic memory devices.

http://www.gizmag.com/magnetic-insulator-memory-storage-slac/40166/?li_source=LI&li_medium=default-widget

 

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Magnetic substructure leads way to superfast and precise data storage
 

January 12, 2015 

 

 

With a surprising discovery, an international team of scientists from Radboud University, Switzerland and Japan demonstrates the feasibility of selective magnetization switching inside a microstructure by using laser light. Their findings open opportunities for very-high-density information storage media.


http://phys.org/news/2015-01-magnetic-substructure-superfast-precise-storage.html#nRlv

 


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Making a new generation of memristors for digital memory and computation

 

February 3, 2016

Memristors are a new class of electrical circuits—and they could end the silicon era and change electronics forever. Since HP first developed a working prototype with a titanium dioxide film in 2008, engineers have sought to perfect the model.

Now, researchers at Michigan Technological University have made an ideal memristor based on molybdenum disulfide nanosheets. Yun Hang Hu, the Charles and Carroll McArthur Professor of Materials Science and Engineering, led the research, which was published in Nano Letters this January.

Beyond Binary Code

Transistors based on silicon, which is the main component of computer chips, work using a flow of electrons. If the flow of electrons is interrupted in a transistor, all information is lost. However, memristors are electrical devices with memory; their resistance is dependent on the dynamic evolution of internal state variables. In other words, memristors can remember the amount of charge that was flowing through the material and retain the data even when the power is turned off.

"Memristors can be used to create super-fast memory chips with more data at less energy consumption" Hu says.

Additionally, a transistor is confined by binary codes—all the ones and zeros that run the internet, Candy Crush games, Fitbits and home computers. In contrast, memristors function in a similar way to a human brain using multiple levels, actually every number between zero and one. Memristors will lead to a revolution for computers and provide a chance to create human-like artificial intelligence.

http://phys.org/news/2016-02-memristors-digital-memory.html#nRlv


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AI 'lights up' nanoparticles, revealing hidden atomic dynamics

March 6, 2025

A team of scientists have developed a method to illuminate the dynamic behavior of nanoparticles, which are foundational components in the creation of pharmaceuticals, electronics, and industrial and energy-conversion materials. The advance, reported in the journal Science, combines artificial intelligence with electron microscopy to render visuals of how these tiny bits of matter respond to stimuli.

https://elnano.com/ai-lights-up-nanoparticles-revealing-hidden-atomic-dynamics/

 

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Precise molecular fingerprinting on the fly
 

December 22, 2015 

 

 Electro-optic modulators, which can switch light on and off within just picoseconds, are enabling ever faster telecommunication over optical glass fibres, so that large movies can be streamed more smoothly across oceans into our homes. The same tools have now been harnessed for high-speed and accurate molecular sensing, as reported by an international collaboration around Dr. Nathalie Picqué, Max Planck Institute of Quantum Optics and Ludwig-Maximilians-Universität Munich, in a letter published in Nature Photonics, 21 December 2015. The collaboration partners are with the Laboratoire Interdisciplinaire Carnot de Bourgogne (France) and the Institut des Sciences Moléculaires d'Orsay (France).

 http://phys.org/news/2015-12-precise-molecular-fingerprinting.html


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World's smallest beamsplitter paves way toward computing at the speed of light

May 18, 2015

 Silicon photonics is an emerging technology that incorporates electronic circuits using photons of laser light rather than electrons to transmit, receive, and manipulate information. As such, a silicon photonic CPU could potentially process information at the speed of light – millions of times faster than computers available today. In a step towards this goal, engineers working at the University of Utah have developed an ultra-compact photonic beam-splitter so small that millions of these devices could fit on a single silicon chip.


http://www.gizmag.com/computing-lightspeed-photonics-beamsplitter/37562/


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When an electron splits in two

 

May 12, 2015

 

As an elementary particle, the electron cannot be broken down into smaller particles, at least as far as is currently known. However, in a phenomenon called electron fractionalization, in certain materials an electron can be broken down into smaller "charge pulses," each of which carries a fraction of the electron's charge. Although electron fractionalization has many interesting implications, its origins are not well understood. -

 

- Gaining a better understanding of electron fractionalization could have a variety of implications for research in condensed matter physics, such as controlling single-electron currents in one-dimensional wires.

 

The experiment reveals that, when a single electron fractionalizes into two pulses, the final state cannot be described as a single-particle state, but rather as a collective state composed of several excitations. For this reason, the fractionalization process destroys the original electron particle. Electron destruction can be measured by the decoherence of the electron's wave packet.

http://phys.org/news/2015-05-electron.html#jCp

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Researchers first to create a single-molecule diode

 

May 25, 2015 

 

 

 Under the direction of Latha Venkataraman, associate professor of applied physics at Columbia Engineering, researchers have designed a new technique to create a single-molecule diode, and, in doing so, they have developed molecular diodes that perform 50 times better than all prior designs. Venkataraman's group is the first to develop a single-molecule diode that may have real-world technological applications for nanoscale devices. Their paper, "Single-Molecule Diodes with High On-Off Ratios through Environmental Control," is published May 25 in Nature Nanotechnology. "Our new approach created a single-molecule diode that has a high (>250) rectification and a high "on" current (~ 0.1 micro Amps)," says Venkataraman. "Constructing a device where the active elements are only a single molecule has long been a tantalizing dream in nanoscience. This goal, which has been the 'holy grail' of molecular electronics ever since its inception with Aviram and Ratner's 1974 seminal paper, represents the ultimate in functional miniaturization that can be achieved for an electronic device."



 http://phys.org/news/2015-05-single-molecule-diode.html?utm_source=menu&utm_medium=link&utm_campaign=item-menu

 

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Scientists Have Turned Light Into a Supersolid—Here's Why That's a Big Deal

Mar 07, 2025

Scientists have succeeded in making light behave like a "supersolid" for the first time—a breakthrough that could improve our understanding of this exotic phase of matter.

A supersolid has an ordered structure like a solid but can also flow without friction like a superfluid, and previously they have only been produced in so-called "Bose–Einstein condensates"—which are formed when a gas of atoms is cooled to near absolute zero.

"This is only the beginning of understanding supersolidity," said Italy-based physicists Antonio Gianfate of CNR Nanotec and Davide Nigro of the University of Pavia in a research summary.

https://www.newsweek.com/supersolid-light-physics-quantum-mechanics-2041338 

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Webinar: One-dimensional quantum wire: physics and applications at ultra low temperatures

  

A webinar discussing quantum devices which have potential for the development of a quantum memory, based on encoding a bit on a polarised line of electrons.



 http://connect.physicsworld.com/nanotechnology/one-dimensional-quantum-wire-physics-and-applications/2002285.article#webinar

 

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Electronic contacts with a single molecule

 23 October 2013


 http://connect.physicsworld.com/nanotechnology/electronic-contacts-with-a-single-molecule/2001245.article


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New Method to Control Nanoparticles with Light and Magnets

 

October 10, 2014

 

 

Elemental mapping of the location of iron atoms (blue) in the magnetic nanoparticles and cadmium (red) in the fluorescent quantum dots provide a clear visualization of the way the two kinds of particles naturally separate themselves into a core-and-shell structure. 

 

A team of researchers has developed particles that can glow with color-coded light and be manipulated with magnets, improving the likelihood of tracking the position of the nanoparticles as they move within the body or inside a cell. 

 

A long-sought goal of creating particles that can emit a colorful fluorescent glow in a biological environment, and that could be precisely manipulated into position within living cells, has been achieved by a team of researchers at MIT and several other institutions. The finding is reported this week in the journal Nature Communications.

https://scitechdaily.com/new-method-control-nanoparticles-light-magnets/

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Supercomputer study shows Lambda baryon a type of quark molecule

 

Apr 06, 2015 

 

http://phys.org/news/2015-04-supercomputer-lambda-baryon-quark-molecule.html

____________________________________

 

 If a flashlight was on and free floating in space would it accelerate?


 http://www.reddit.com/r/askscience/comments/2p6fku/if_a_flashlight_was_on_and_free_floating_in_space/

Q: Would the emission of photos push the flashlight at all?

 

Short answer: Yes. Photons carry momentum, which would cause the flashlight to experience a force against the direction it was shining.



____________________________________


In quantum physics, some scientists claim that if you were able to pinpoint physical particles in a beam of light or a lazer, then connect or stretch those particles back to the source where the light originated. That it could be possible to send physical particles from one location, to another location through a portal.  

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Scientists At NASA Announce That Space Portals Actually Do Exist

 

5th May 2015

 http://www.neonnettle.com/news/1432-scientists-at-nasa-announce-that-space-portals-actually-do-exist


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Experiment confirms quantum theory weirdness

May 27, 2015


 The bizarre nature of reality as laid out by quantum theory has survived another test, with scientists performing a famous experiment and proving that reality does not exist until it is measured.


 Physicists at The Australian National University (ANU) have conducted John Wheeler's delayed-choice thought experiment, which involves a moving object that is given the choice to act like a particle or a wave. Wheeler's experiment then asks - at which point does the object decide?

 Common sense says the object is either wave-like or particle-like, independent of how we measure it. But quantum physics predicts that whether you observe wave like behavior (interference) or particle behavior (no interference) depends only on how it is actually measured at the end of its journey. This is exactly what the ANU team found.


Read more at: http://phys.org/news/2015-05-quantum-theory-weirdness.html#jCp


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Best of Last Week – A way to measure variations in the speed of light, a slower universe and plucking hair


Apr 13, 2015



(Phys.org)—It was a big week for physics. First, a trio of researchers proposed a method to measure variations in the speed of light—in alternative theories of cosmology where it has been theorized that time and space can vary. Also, another team showed that the "quantum freezing phenomenon" is universal—this describes conditions in which quantum correlations can be "frozen" in a constant state and remain that way in the presence of noise. Meanwhile another team suggested that "unparticles" may provide a new path to superconductivity—the hypothetical form of matter, the researchers suggest, could play a key role in mediating superconductivity.

Read more at: http://phys.org/news/2015-04-week-variations-slower-universe-plucking.html#jCp

 
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Traveling without moving: Quantum communication scheme transfers quantum states without transmitting physical particles

Mar 10, 2015

Read more at: http://phys.org/news/2015-03-quantum-scheme-states-transmitting-physical.html#jCp


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Light-based memory chip is the first ever to store data permanently

September 22, 2015

The world's first entirely light-based memory chip to store data permanently has been developed by material scientists at Oxford University and University of Münster in collaboration with scientists at Karlsruhe and Exeter. The device, which makes use of materials used in CDs and DVDs, could help dramatically improve the speed of modern computing
Today's computers are held back by the relatively slow transmission of electronic data between the processor and the memory. "There's no point using faster processors if the limiting factor is the shuttling of information to-and-from the memory—the so-called von-Neumann bottleneck," explains Professor Harish Bhaskaran, the Oxford engineer who led the research along with Professor Wolfram Pernice from the University of Münster. "But we think using light can significantly speed this up."

Simply bridging the processor-memory gap with photons isn't efficient, though, because of the need to convert them back into electronic signals at each end. Instead, memory and processing capabilities would need be light-based too. Researchers have tried to create this kind of photonic memory before, but the results have always been volatile, requiring power in order to store data. For many applications—such as computer disk drives—it's essential to be able to store data indefinitely, with or without power.

http://phys.org/news/2015-09-light-based-memory-chip-permanently.html#jCp




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Unparticles may provide a new path to superconductivity

 

Apr 07, 2015

 

 (Phys.org)—Physicists have proposed that a hypothetical form of matter called "unparticles" may play a key role in mediating superconductivity—the ability of certain materials to conduct electricity with zero resistance.

Read more at: http://phys.org/news/2015-04-unparticles-path-superconductivity.html#jCp

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We can use energy from the sun, including materials that can bend and fluctuate, to create and store energy. This type of energy is mentioned in the chapter titled "Piezoelectric energy."

 

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Energy-Harvesting "Piezo-tree" to Produce Renewable Energy

 

December 29, 2009

 http://www.greenoptimistic.com/energy-harvesting-piezo-tree-to-produce-renewable-energy-20091229/#.VSYHGZO-2zk



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Chemistry student makes sun harvest breakthrough

May 06, 2015 

- The group is working with molecules known as the dihydroazulene-vinylheptafulvene system. Put very simply, this stores energy by changing shape, but every time the Brøndsted group managed to design improved molecules, the molecules lost some of their ability to hold their energy storage configuration, says professor Brøndsted."Regardless of what we did to prevent it, the molecules would change their shape back and release the stored energy after just an hour or two. Anders' achievement was that he managed to double the energy density in a molecule that can hold its shape for a hundred years. Our only problem now is how we get it to release the energy again. The molecule does not seem to want to change its shape back again," says Mogens Brøndsted...

http://phys.org/news/2015-05-chemistry-student-sun-harvest-breakthrough.html?utm_source=menu&utm_medium=link&utm_campaign=item-menu


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Magnetic Effect of Light Could Lead to New Solar Panels Technology

 

April 19, 2011



The great side about physics is that it discovers things where you would least expect them to be found. For example, just when you thought you knew everything about light, here comes an exciting new discovery that could become an alternative source of power, involving the magnetic properties of light!

http://www.greenoptimistic.com/magnetic-effect-light-solar-energy-20110419/


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 Chemists find new way to do light-driven reactions in solar energy quest

August 6, 2015

Chemists have found a new, more efficient method to perform light-driven reactions, opening up another possible pathway to harness sunlight for energy. The journal Science is publishing the new method, which is based on plasmon - a special motion of electrons involved in the optical properties of metals.

http://phys.org/news/2015-08-chemists-light-driven-reactions-solar-energy.html#jCp



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 Most precise test of Lorentz symmetry for the photon finds that the speed of light is indeed constant

September 15, 2015

http://phys.org/news/2015-09-precise-lorentz-symmetry-photon-constant.html#jCp

 

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Advancing light-to-electricity energy conversion: New method extends lifespan of plasmonic hot holes

Mar 18 2025

When light interacts with metallic nanostructures, it instantaneously generates plasmonic hot carriers, which serve as key intermediates for converting optical energy into high-value energy sources such as electricity and chemical energy. Among these, hot holes play a crucial role in enhancing photoelectrochemical reactions. However, they thermally dissipate within picoseconds (trillionths of a second), making practical applications challenging.

Now, a Korean research team has successfully developed a method for sustaining hot holes longer and amplifying their flow, accelerating the commercialization of next-generation, high-efficiency, light-to-energy conversion technologies.

The research team, led by Distinguished Professor Jeong Young Park from the Department of Chemistry at KAIST, in collaboration with Professor Moonsang Lee from the Department of Materials Science and Engineering at Inha University, has successfully amplified the flow of hot holes and mapped local current distribution in real time, thereby elucidating the mechanism of photocurrent enhancement. The work is published in Science Advances.

https://lifeboat.com/blog/2025/03/advancing-light-to-electricity-energy-conversion-new-method-extends-lifespan-of-plasmonic-hot-holes

 

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Integrated lightwave electronics

 

July 23, 2020

 

MIT researchers develop integrated lightwave electronic circuits to detect the phase of ultrafast optical fields.

 

https://news.mit.edu/2020/integrated-lightwave-electronics-0723



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Light-powered computer chip can train AI much faster than components powered by electricity

March 25, 2024

 

New chip design uses photons rather than electrons to perform calculations, and scientists hope to integrate the technology into future graphics cards to train AI. 


https://www.livescience.com/technology/electronics/light-powered-computer-chips-can-train-ai-much-faster-than-components-powered-by-electricity

 

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Light-powered enzymes create valuable chiral molecules from plant-based building blocks

 

June 24, 2025

https://phys.org/news/2025-06-powered-enzymes-valuable-chiral-molecules.html

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Chapter 10: Tesla Coils


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We need a clean source of energy. Many claim we already can generate  energy out of hydrogen, air, water, magnetism, including cold fusion and friction.
 
Many people think that the inventions of Nikola Tesla could harness an abundance of clean energy for the people of this planet.

 

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U.S. Army develops Tesla-style lightning bolt to destroy enemy vehicles

28 June 2012

 

 

http://www.dailymail.co.uk/sciencetech/article-2165966/U-S-Army-develops-Tesla-style-lightning-bolt-destroy-enemy-vehicles-adds-Sci-fi-fans-youre-welcome.html

 

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Tesla coil

 

A Tesla coil is an electrical resonant transformer circuit invented by Nikola Tesla around 1891. It is used to produce high-voltage, low-current, high frequency alternating-current electricity. Tesla experimented with a number of different configurations consisting of two, or sometimes three, coupled resonant electric circuits.
Tesla used these coils to conduct innovative experiments in electrical lighting, phosphorescence, X-ray generation, high frequency alternating current phenomena, electrotherapy, and the transmission of electrical energy without wires. Tesla coil circuits were used commercially in sparkgap radio transmitters for wireless telegraphy until the 1920s, and in medical equipment such as electrotherapy and violet ray devices. Today their main use is for entertainment and educational displays, although small coils are still used today as leak detectors for high vacuum systems.

 http://en.wikipedia.org/wiki/Tesla_coil

 

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Teleforce

 

 Teleforce is a charged particle beam projector that Nikola Tesla claimed to have conceived of after studying the Van de Graaff generator. Tesla described the weapon as being able to be used against ground-based infantry or for anti-aircraft purposes.

 

 http://en.wikipedia.org/wiki/Teleforce

 

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NIKOLA TESLA - THE MASTER OF LIGHTNING - Discovery History Science (documentary)

  

May 4, 2014

 

 https://www.youtube.com/watch?v=Mb5LMWpL3io

 

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Scalar Waves: Nicola Tesla's Forgotten Discovery Of A Source Of Clean, Cost Free Energy

 

Scalar wavelengths are finer than gamma rays or X rays and only one hundred millionth of a square centimeter in width. They belong to the subtle gravitational field and are also known as gravitic waves. Uniquely, they flow in multiple directions at right angles off electromagnetic waves, as an untapped energy source called 'potentials'. Potentials are particles which are unorganized in hyperspace - pure etheric energy not manifest in the physical world. In comparison, electromagnetic waves (measured by so many hertz or pulses per second, with which we are familiar with as radio other waves in the electro-magnetic spectrum) exist normally in the physical world, but can only be measured up to levels determined by the sensitivity of the equipment being used as to how many cycles per second they operate.

 http://www.greenteethmm.com/science-scalar-waves.shtml

 

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How the Physics of Electromagnetism can Generate Electricity

 

http://syzygyastro.hubpages.com/hub/How-the-Physics-of-Electromagnetism-can-Generate-Electricity

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Getting a charge from changes in humidity

 

 Jan 27, 2014 

New type of generator built with bacterial spores could one day provide a steady source of green electricity

BOSTON — A new type of electrical generator uses bacterial spores to harness the untapped power of evaporating water, according to research conducted at the Wyss Institute of Biologically Inspired Engineering at Harvard University. Its developers foresee electrical generators driven by changes in humidity from sun-warmed ponds and harbors.

The prototype generators work by harnessing the movement of a sheet of rubber coated on one side with spores. The sheet bends when it dries out, much as a pine cone opens as it dries or a freshly fallen leaf curls, and then straightens when humidity rises. Such bending back and forth means that spore-coated sheets or tiny planks can act as actuators that drive movement, and that movement can be harvested to generate electricity.

 http://wyss.harvard.edu/viewpressrelease/137/getting-a-charge-from-changes-in-humidity

 

 
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A new clean nuclear fusion reactor has been designed

 

January 14, 2013 

 

 http://phys.org/news/2013-01-nuclear-fusion-reactor.html#nRlv

 

A researcher at the Universidad politécnica de Madrid (UPM, Spain) has patented a nuclear fusion reactor by inertial confinement that, apart from be used to generate electric power in plants, can be applied to propel ships.

This invention is the result of a work carried out by the Professor José Luis González Díez from the Higher Technical School of Naval Engineering of the UPM, who has contributed to solve the problem of contamination risk associated with the generation of nuclear fission power. It is a design of a fusion nuclear reactor by laser ignition of 1000 MWe that uses as fuel hydrogen isotopes that can be extracted from water allowing us a significant saving in fuel.
The nuclear fission is generally considered as a dangerous energy due to its contaminant risks of radioactive waste resulting from the electricity generation process. The past events occurred in Japan after the tsunami of 2011 increased the risk perception of this type of energy generation what has provoked that research on alternative ways to obtain energy have gained more importance than ever.

For years, nuclear fusion was studied as an alternative to nuclear fission because of its remarkable advantages for security and financial issues. However, today, there is not working any fusion reactor to produce continuous electrical energy of high voltage.

 

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Electrostatic nuclear accelerator

 

 An electrostatic nuclear accelerator is one of the two main types of particle accelerators, where charged particles can be accelerated by subjection to a static high voltage potential. The static high voltage method is contrasted with the dynamic fields used in oscillating field particle accelerators. Owing to their simpler design, historically these accelerators were developed earlier. These machines are operated at lower energy than some larger oscillating field accelerators, and to the extent that the energy regime scales with the cost of these machines, in broad terms these machines are less expensive than higher energy machines, and as such they are much more common. Many universities world wide have electrostatic accelerators for research purposes.

 

 http://en.wikipedia.org/wiki/Electrostatic_nuclear_accelerator

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May 25, 2001

 

TESLA project goes public

 http://cerncourier.com/cws/article/cern/28450

At a major event held at the DESY laboratory in March (see News May 2000), the international TESLA collaboration, together with the members of various study groups, released the TESLA Technical Design Report. This five-volume opus presented the final facts and figures concerning a grand plan for the future: the "TeV-Energy Superconducting Linear Accelerator", a 33 km electron-positron linear collider with an integrated X-ray laser laboratory.
To be built near the DESY laboratory in Hamburg, the facility would not only provide particle collision energies of 500 GeV - which could be increased to 800 GeV - but also include powerful X-ray lasers that would open up new research opportunities in a variety of fields, ranging from condensed matter physics through chemistry and material science to structural biology.
It is widely acknowledged among particle physicists that a linear accelerator colliding electrons and positrons is the ideal machine to complement CERN's Large Hadron Collider, which is due to start operation in 2006. As well as the TESLA collaboration, plans for similar next-generation linear electron-positron colliders are being worked on by other teams.
SLAC in the US and KEK in Japan are jointly developing two similar designs - known respectively as the Next Linear Collider and the Japan Linear Collider - which could be ready for construction at around the same time as TESLA. CERN is also working on a next-generation collider, CLIC. However, the TESLA proposal is the first to be fully costed and made public. It is also the only project to include an X-ray laser laboratory and thus to address a large interdisciplinary research community.


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Chapter 11: CERN

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Doing experiments with the interaction of antimatter, including chemicals such as uranium, have many people and scientists concerned. As we know, smashing certain chemicals, such as uranium at very high speeds, could create a giant catastrophic explosion on the planet.


----------------------------

Gravitational interaction of antimatter

https://en.wikipedia.org/wiki/Gravitational_interaction_of_antimatter

The gravitational interaction of antimatter with matter or antimatter has not been conclusively observed by physicists. While the overwhelming consensus among physicists is that antimatter will attract both matter and antimatter at the same rate that matter attracts matter, there is a strong desire to confirm this experimentally.

Antimatter's rarity and tendency to annihilate when brought into contact with matter makes its study a technically demanding task. Most methods for the creation of antimatter (specifically antihydrogen) result in high-energy particles and atoms of high kinetic energy, which are unsuitable for gravity-related study. In recent years, first ALPHA [1][2] and then ATRAP [3] have trapped antihydrogen atoms at CERN; in 2013 ALPHA used such atoms to set the first free-fall loose bounds on the gravitational interaction of antimatter with matter, with a relative precision of the measurement of ±100%, not enough for a clear scientific statement about the sign of gravity acting on antimatter. Future experiments need to be performed with higher precision, either with beams of antihydrogen (AEGIS or GBAR) or with trapped antihydrogen (ALPHA).

 

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CERN researchers confirm existence of the Force

 

April, 2015

 Researchers at the Large Hadron Collider just recently started testing the accelerator for running at the higher energy of 13 TeV, and already they have found new insights into the fundamental structure of the universe. Though four fundamental forces – the strong force, the weak force, the electromagnetic force and gravity – have been well documented and confirmed in experiments over the years, CERN announced today the first unequivocal evidence for the Force. "Very impressive, this result is," said a diminutive green spokesperson for the laboratory.

 http://phys.org/news/2015-04-cern.html#jCp

 

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Meson f0(1710) could be so-called “glueball” particle made purely of nuclear force

 

Terms to describe the strange world of quantum physics have come to be quite common in our lexicon. Who, for instance, hasn't at least heard of a quark, or a gluon or even Schrodinger's cat? Now there's a new name to remember: "Glueball." A long sought-after exotic particle, and recently claimed to have been detected by researchers at TU Wien, the glueball's strangest characteristic is that it is composed entirely of gluons. In other words, it is a particle created from pure force.

First mooted as a particle in 1972 when physicists Murray Gell-Mann and Harald Fritsch wondered about possible bound states of recently-discovered gluons, scientists have sought the particle in the intervening decades. Originally dubbed "gluonium," but now called glueballs, these strange particles of pure force are exceptionally unstable and can only be indirectly detected by monitoring their decay as they disassemble into lesser particles.

More recently, physics Professor Anton Rebhan and his PhD student Frederic Brünner from TU Wien have theorized that a strong nuclear decay resonance, called f0(1710), observed in the data from a number of particle accelerator experiments is strong evidence for the elusive glueball particle...

http://www.gizmag.com/meson-f01710-glueball-particle/39866/?li_source=LI&li_medium=default-widget

 


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Stephen Hawking Says 'God Particle' Could Wipe Out the Universe

 

 September 08, 2014

 

(Simulated data from the Large Hadron Collider particle detector shows the Higgs boson produced after two protons collide. )

  

 Stephen Hawking bet Gordon Kane $100 that physicists would not discover the Higgs boson. After losing that bet when physicists detected the particle in 2012, Hawking lamented the discovery, saying it made physics less interesting. Now, in the preface to a new collection of essays and lectures called "Starmus," the famous theoretical physicist is warning that the particle could one day be responsible for the destruction of the known universe.

 http://www.livescience.com/47737-stephen-hawking-higgs-boson-universe-doomsday.html

 

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CERN Document Server - Micro energy harvesting

 2015

https://cds.cern.ch/record/2019306

 

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CERN Document Server - Piezoelectric energy harvesting

 2015

 http://cds.cern.ch/record/1613190?ln=en

 

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CAST explores the dark side of the universe

September 21, 2015

Over the next 10 days, CERN's Axion Solar Telescope (CAST) will receive the Sun's rays. The Sun's course is visible from the window in the CAST experimental hall just twice a year, in March and September. The scientists will take advantage of these few days to improve the alignment of the detector with respect to the position of the Sun to within a thousandth of a radian.

Read more at: http://phys.org/news/2015-09-explores-dark-side-universe.html#jCp



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Big Chill Sets in as RHIC Physics Heats Up

 

Run 14 promises highest collision rates enabling exploration of detailed properties of early-universe matter

 

Monday, February 03, 2014

UPTON, NY—If you think it's been cold outside this winter, that's nothing compared to the deep freeze setting in at the Relativistic Heavy Ion Collider (RHIC), the early-universe-recreating "atom smasher" at the U.S. Department of Energy's Brookhaven National Laboratory. Brookhaven's accelerator physicists have begun pumping liquid helium into RHIC's 1,740 superconducting magnets to chill them to near absolute zero (-273 degrees Celsius—the coldest anything can get) in preparation for the collider's next physics run.

Once that extreme subzero temperature is reached, enabling the magnets to operate with zero energy loss, the physicists will begin injecting beams of gold ions and steering them into head-on collisions at nearly the speed of light. Those collisions create temperatures at the opposite extreme of the temperature scale—4 trillion degrees Celsius, or 250,000 times hotter than the center of the sun—to produce RHIC's signature "perfect" liquid quark-gluon plasma, a stand in for what the universe was like an instant after the Big Bang. During this experimental run, the 14th at this nuclear physics scientific user facility, scientists will conduct detailed studies of the primordial plasma's properties and fill in some missing data points to plot its transition to the matter we see in the universe today

https://www.bnl.gov/newsroom/news.php?a=111606


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The puzzle of the origin of elements in the universe

 

December 17, 2015

 

 

 A rare nuclear reaction that occurs in red giants has been observed for the first time at the Gran Sasso National Laboratory in Italy. This result was achieved by the LUNA experiment, the world's only accelerator facility running deep underground.

The LUNA experiment at the INFN Gran Sasso National Laboratory in Italy has observed a rare nuclear reaction that occurs in giant red stars, a type of star in which our sun will also evolve. This is the first direct observation of sodium production in these stars, one of the nuclear reactions that is fundamental for the formation of the elements that make up the universe. The study has been published in Physical Review Letters.

LUNA (Laboratory for Underground Nuclear Astrophysics) is a compact linear accelerator. It is the only one in the world installed in an underground facility, shielded against cosmic rays. The experiment aims to study the nuclear reactions that take place inside stars where, like in an intriguing and amazing cosmic kitchen, the elements that make up matter are formed and then driven out by gigantic explosions and scattered as cosmic dust.


 http://phys.org/news/2015-12-puzzle-elements-universe.html

 

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RHIC particle smashups find that shape matters

 

December 7, 2015

 Peering into the seething soup of primordial matter created in particle collisions at the Relativistic Heavy Ion Collider (RHIC)-an "atom smasher" dedicated to nuclear physics research at the U.S. Department of Energy's Brookhaven National Laboratory-scientists have come to a new understanding of how particles are produced in these collisions. This understanding represents a paradigm shift consistent with the presence of a saturated state of gluons, super-dense fields of the glue-like particles that bind the building blocks of ordinary matter.

 http://phys.org/news/2015-12-rhic-particle-smashups.html

 

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Physicists search for signs of supersymmetry

 

December 17, 2015

The first results from direct searches for new physics were announced today from CERN's energy-upgraded Large Hadron Collider (LHC). Among these results was a search for signs of a new theory called supersymmetry in which members of the University of Bristol particle physics group have played a leading role.


The LHC is the world's highest energy particle accelerator. After an almost two year shutdown and several months' re-commissioning, the LHC delivered physics data to its experiments from June to November this year at the unprecedented energy of 13 TeV, almost double the collision energy of its first run. The energy of the colliding protons is such that new particles much heavier than the proton can be created including the famous Higgs boson, and possibly even heavier and more exotic particles hypothesised in new physics theories. One such theory is called supersymmetry, which predicts an exotic partner for each currently known particle type.

http://phys.org/news/2015-12-physicists-supersymmetry.html

 

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Four new elements confirmed

 

 January 4, 2016

http://www.gizmag.com/new-periodic-table-elements-confirmed/41139/

Chemistry textbooks are in need of a rewrite with the addition of four new elements to the Periodic Table. The International Union of Pure and Applied Chemistry (IUPAC) has confirmed the existence of four new elements with the atomic numbers 113, 115, 117, and 118, which were discovered by laboratories in Japan, the United States, and Russia. This bumper group of new elements completes the 7th row of the Periodic Table and clears the way for the discoverers to start thinking up names for them.

Until now, elements 113, 115, 117, and 118 have only been known from their gaps in the table and the temporary names ununtrium (Uut), ununpentium (Uup), ununseptium (Uus), and ununoctium (Uuo). Now, thanks to RIKEN in Japan; the Joint Institute for Nuclear Research in Dubna, Russia; Lawrence Livermore National Laboratory (LLNL), California; and Oak Ridge National Laboratory, (ORNL), Tennessee, these elements that do not exist in nature have been confirmed to have been created for the first time.

The fourth IUPAC and the International Union of Pure and Applied Physics (IUPAP) Joint Working Party (JWP) reviewed the findings of the discoverers and, based on a criteria set out in 1991, have confirmed them. Elements 115 and 117 were found by the Joint Institute for Nuclear Research, LLNL, and ORNL. Element 118 was found by the Joint Institute and LLNL, and 113 was found by RIKEN.

The periodic table in its modern form was invented by Russian chemistry professor Dmitri Mendeleev in 1869 and lists elements according to their atomic numbers based on the number of protons in their nuclei. Its odd shape, which is familiar to anyone trying to stay awake in chemistry class, is due to the discovery that by arranging the elements to group them by their chemical properties and electron configurations, it becomes a graphic representation of objective reality.
In other words, chemists could not only use the table to describe known elements, but also predict the existence and properties of unknown elements that were yet to be discovered. This makes the IUPAC announcement particularly important because it means that an entire row or period of the table has now been filled in thanks, in part, to this predictability.

Though many of the new elements were discovered as far back as 2004, the tricky bit has been proving that they exist. In the 19th century, any competent chemist could determine if a substance was a pure element, but the new elements reside in a part of the table where the atoms are super heavy and so unstable that they exist for less than a thousandth of a second.

Element 113, for example, was created by using a linear accelerator to bombard a thin layer of bismuth with zinc ions travelling at about ten percent of the speed of light in hope that, in rare instances, the bismuth and zinc atoms would fuse to form a element. The resulting super-heavy atom of 113 would then decay and turn into other unstable radioactive isotopes, which would decay nearly as fast.

The result was that the scientists who created the new element had to spend years tracing back the event through a labyrinth of isotopic breakdowns to prove that they descended from the new element. Then, the JWP of the IUPAC had to review the literature to make sure no mistakes were made.
Now that the elements are confirmed, the discoverers can officially apply permanent names and symbols to them. The proposed names and two-letter symbols will be checked by the Inorganic Chemistry Division of IUPAC and then be subjected to a public review for five months to make sure they conform to the standards of consistency, translatability into other languages, and historic use. Typically, names have been derived from mythology, minerals, geography, or the name of a scientist.
One other interesting point about the new elements is that it opens the way to the search for an "island of stability." That is, a region beyond the current Periodic Table where new superheavy elements will become stable and exist long enough to allow for conventional chemistry experiments.

 

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The perfect liquid -- now even more perfect

 

January 17, 2012

 Ultra hot quark-gluon-plasma, generated by heavy-ion collisions in particle accelerators, is supposed to be the "most perfect fluid" in the world. Previous theories imposed a limit on how "liquid" fluids can be. Recent results at the Vienna University of Technology suggest that this limit can be broken -- making the world's "most perfect fluid" even more perfect.

How liquid can a fluid be? This is a question particle physicists at the Vienna University of Technology have been working on. The "most perfect liquid" is nothing like water, but the extremely hot quark-gluon-plasma which is produced in heavy-ion collisions at the Large Hadron Collider at CERN. New theoretical results at Vienna UT show that this quark-gluon plasma could be even less viscous than was deemed possible by previous theories. The results were published in Physical Review Letters and highlighted as an "editors' selection".

Highly viscous liquids (such as honey) are thick and have strong internal friction, quantum liquids, such as super fluid helium can exhibit extremely low viscosity. In 2004, theorists claimed that quantum theory provided a lower bound for viscosity of fluids. Applying methods from string theory, the lowest possible ratio of viscosity to the entropy density was predicted to be ħ/4π (with the Planck-constant ħ). Even super fluid helium is far above this threshold. In 2005, measurements showed that quark-gluon-plasma exhibits a viscosity just barely above this limit. However, this record for low viscosity can still be broken, claims Dominik Steineder from the Institute for Theoretical Physics at Vienna UT. He obtained this remarkable result working as a PhD-student with Professor Anton Rebhan.


 http://phys.org/news/2012-01-liquid-.html#nRlv

 

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Linear particle accelerator

 

https://en.wikipedia.org/wiki/Linear_particle_accelerator

A linear particle accelerator (often shortened to linac) is a type of particle accelerator that greatly increases the kinetic energy of charged subatomic particles or ions by subjecting the charged particles to a series of oscillating electric potentials along a linear beamline; this method of particle acceleration was invented by Leó Szilárd. It was patented in 1928 by Rolf Widerøe, who also built the first operational device at the RWTH Aachen University in 1928, influenced by a publication of Gustav Ising.



Linacs have many applications: they generate X-rays and high energy electrons for medicinal purposes in radiation therapy, serve as particle injectors for higher-energy accelerators, and are used directly to achieve the highest kinetic energy for light particles (electrons and positrons) for particle physics.
The design of a linac depends on the type of particle that is being accelerated: electrons, protons or ions. Linacs range in size from a cathode ray tube (which is a type of linac) to the 3.2-kilometre-long (2.0 mi) linac at the SLAC National Accelerator Laboratory in Menlo Park, California.

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China to build a particle collider​ twice the size of the Large Hadron Collider

 

November 27, 2015

China is planning to enter the Europe- and US-dominated world of experimental physics with (wait for it …) a bang. It has formally announced that it will begin the first phase of construction of an enormous particle accelerator around 2020, which will be twice the size and seven times more powerful than CERN's Large Hadron Collider (LHC).

 http://www.gizmag.com/china-worlds-biggest-particle-collider/40526/?li_source=LI&li_medium=default-widget

 

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Antimatter Propulsion Engine Redesigned Using CERN's Particle Physics Simulation Toolkit

Latest simulation shows that the magnetic nozzles required for antimatter propulsion could be vastly more efficient than previously thought–and built with today’s technologies

 http://www.technologyreview.com/view/427923/antimatter-propulsion-engine-redesigned-using-cerns-particle-physics-simulation-toolkit/


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For more information on nuclear experiments with plasma accelerator technology, view the chapter titled "Plasma technology."


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Chapter 12: Antimatter



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Antimatter

In particle physics, antimatter is material composed of antiparticles, which have the same mass as particles of ordinary matter but opposite charges, as well as other particle properties such as lepton and baryon numbers and quantum spin. Collisions between particles and antiparticles lead to the annihilation of both, giving rise to variable proportions of intense photons (gamma rays), neutrinos, and less massive particle–antiparticle pairs. The mass of any produced neutrinos is negligible, while they contain energy that generally continues to be unavailable after the release of particle–antiparticle annihilation. The total consequence of annihilation is a release of energy available for work, proportional to the total matter and antimatter mass, in accord with the mass–energy equivalence equation, E = mc²

 http://en.wikipedia.org/wiki/Antimatter


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Air Force pursuing antimatter weapons / Program was touted publicly, then came official gag order


October 4, 2004


http://www.sfgate.com/science/article/Air-Force-pursuing-antimatter-weapons-Program-2689674.php

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Antimatter weapon

http://en.wikipedia.org/wiki/Antimatter_weapon


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The antimatter factory: inside the project that could power fusion and annihilation lasers

 August 28, 2013


 http://www.theverge.com/2013/8/28/4659834/unlocking-the-positron-fusion-annihilation-laser


 Physicists have been chasing antimatter technology for more than 80 years now — driven by the promise of oppositely oriented particles that explode in a burst of energy whenever they make contact with their more common counterpart. If we could tame antimatter, those explosions could be used to power a new generation of technology, from molecular scanners to rocket engines to the so-called "annihilation laser," a tightly concentrated energy beam fueled by annihilating positrons. But while scientists have seen recent breakthroughs in creating the particles, they still have trouble capturing and containing them.


 That progress has left us closer to workable antimatter than ever before, and parallel projects are already working on novel devices to cool and trap the particles, along with new magnetic arrays to keep them stable. With the right funding, experts estimate we could see the dawn of the positron age in as few as five years. Positron Dynamics is one key player in the new wave of technology, working on an innovative method for cooling down and capturing positrons, the antimatter equivalent of the common electron. Whenever a positron and an electron meet, they annihilate each other, which presents a serious challenge for anyone working with them. It’s particularly difficult because electrons are literally everywhere, floating in clouds around essentially every atom in the universe. Right now, the best solution for cooling the positrons is running them through a block of frozen neon (called a "moderator"), which offers a minimum of stray electrons. But the system only catches roughly one in 100 positrons, and in the 30 years it’s been in use, no one’s been able to improve on it.


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After 85-year search, massless particle with promise for next-generation electronics found

July 16, 2015

An international team led by Princeton University scientists has discovered Weyl fermions, an elusive massless particle theorized 85 years ago. The particle could give rise to faster and more efficient electronics because of its unusual ability to behave as matter and antimatter inside a crystal, according to new research.

 The researchers report in the journal Science July 16 the first observation of Weyl fermions, which, if applied to next-generation electronics, could allow for a nearly free and efficient flow of electricity in electronics, and thus greater power, especially for computers, the researchers suggest.

Proposed by the mathematician and physicist Hermann Weyl in 1929, Weyl fermions have been long sought by scientists because they have been regarded as possible building blocks of other subatomic particles, and are even more basic than the ubiquitous, negative-charge carrying electron (when electrons are moving inside a crystal). Their basic nature means that Weyl fermions could provide a much more stable and efficient transport of particles than electrons, which are the principle particle behind modern electronics.

 http://phys.org/news/2015-07-year-massless-particle-next-generation-electronics.html#jCp

 

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Antiproton Decelerator

 

http://en.wikipedia.org/wiki/Antiproton_Decelerator#ATRAP

 The Antiproton Decelerator (AD) is a storage ring at the CERN laboratory in Geneva. It was built as a successor to the Low Energy Antiproton Ring (LEAR) and started operation in the year 2000. The decelerated antiprotons are ejected to one of several connected experiments.

ATRAP

The ATRAP collaboration at CERN developed out of TRAP, a collaboration whose members pioneered cold antiprotons, cold positrons, and first made the ingredients of cold antihydrogen to interact. ATRAP members also pioneered accurate hydrogen spectroscopy and first observed hot antihydrogen atoms.

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'Anti-atomic fingerprint': Physicists manipulate anti-hydrogen atoms for the first time (Update)

Mar 07, 2012

 

 

http://phys.org/news/2012-03-anti-atomic-fingerprint-physicists-anti-hydrogen-atoms.html#jCp

 

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Space Station's Giant Antimatter Magnet Finds Abundance Of Mysterious Particles


 April 3, 2013

The Alpha Magnetic Spectrometer's first results could be evidence of dark matter.



 http://www.popsci.com/technology/article/2013-04/antimatter-magnet-flying-space-station-finds-new-clues-pointing-dark-matter

 

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Warp Drive, When? Status of Antimatter

http://www.nasa.gov/centers/glenn/technology/warp/antistat.html



Antimatter is real stuff, not just science fiction. Antimatter is firmly in the realm of science with some aspects even entering the technology realm. There is also a lot of speculation about what one might do with antimatter.


What is Antimatter?


Antimatter is matter with its electrical charge reversed. Anti-electrons, called "positrons," are like an electron but with a positive charge. Antiprotons are like protons with a negative charge. Positron, antiprotons and other antiparticles can be routinely created at particle accelerator labs, such as CERN in Europe, and can even be trapped and stored for days or weeks at a time. And just last year, they made antihydrogen for the first time. It didn’t last long, but they did it. Also, Antimatter is NOT antigravity. Although it has not been experimentally confirmed, existing theory predicts that antimatter behaves the same to gravity as does normal matter.


Technology is now being explored to make antimatter carrying cases, to consider using antimatter for medical purposes, and to consider how to make antimatter rockets.


The catch?


Right now it would cost about One-Hundred-Billion dollars to create one milligram of antimatter. One milligram is way beyond what is needed for research purposes, but that amount would be needed for large scale applications. To be commercially viable, this price would have to drop by about a factor of Ten-Thousand.


And what about using antimatter for power generation? - not promising.

It costs far more energy to create antimatter than the energy one could get back from an antimatter reaction. Right now standard nuclear reactors, which take advantage of the decay of radioactive substances, are far more promising as power generating technology than antimatter. Something to keep in mind, too, is that antimatter reactions - where antimatter and normal matter collide and release energy, require the same safety precautions as needed with nuclear reactions.

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Left-handed cosmic magnetic field could explain missing antimatter

May 14, 2015


http://phys.org/news/2015-05-left-handed-cosmic-magnetic-field-antimatter.html?utm_source=menu&utm_medium=link&utm_campaign=item-menu


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Chapter 13: Plasma energy



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Plasma breakthrough: Scientists unlock magnetic secrets for stable nuclear fusion

 

Aug 09, 2025

 

Turbulence that starts at the particle level can directly change the large-scale equilibrium of a plasma system.

 

Researchers from South Korea have provided experimental proof of ‘multi-scale coupling’ in plasma. The study demonstrates how microscopic events can cause large-scale changes in this state of matter.

 

A challenge in plasma physics has been to understand multi-scale coupling, a process where particle-level turbulence scales up to affect the entire plasma system.

 

“Cross-scale coupling from magnetohydrodynamics (MHD) to non-MHD scales is important in interpreting observations of explosive events in nature,” said the researchers in a new study.

 

https://interestingengineering.com/energy/plasmas-secrets-unlocked-for-fusion-reactor

 

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 New methods to make longer streams of plasma with greater longevity could lead to laser-powered lightning rods

September 24, 2015

( A picture of a femtosecond laser. The laser beam itself is invisible (800nm), but due to the formation of a plasma channel, the beam emits (visible) white light. )

Benjamin Franklin invented the lightning rod 250 years ago to protect people and buildings from lightning strikes. Someday, those metal poles may be replaced with lasers.


A team of researchers from The Hebrew University of Jerusalem, Israel, have demonstrated new techniques that bring lasers as lighting rods closer to reality.

When a powerful laser beam shoots through the air, it ionizes the molecules, leaving a thin trail of hot, ionized particles in its wake. Because this stream of plasma conducts electricity, it could be used to channel away a potentially damaging lightning bolt.

The researchers found ways to make the length of such a plasma channel reach more than 10 times longer—a necessary advance for using the channel to redirect a lightning strike.


 http://phys.org/news/2015-09-methods-longer-streams-plasma-greater.html#jCp



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Researchers build real-time tunable plasmon laser

4/24/2015

Traditionally, light can only ever be focused down to a point half the size of its frequency—aka the diffraction limit. Scientists have found a way around that limit, however, by building what are known as plasmon lasers, which are lasers that couple their beam with plasmons (oscillating surface electrons) on the surface of metals—gold for example, arranged in an array. But that approach has had its limitations as well, because it has had to rely on a solid bit of material called the gain—such lasers could not be tuned very easily, and not in real-time at all. In this new effort, the researchers report that they have found a way to use a liquid material as the gain, and because of that, are able to tune their laser in real time.

http://phys.org/news/2015-04-real-time-tunable-plasmon-laser.html#jCp


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Michio Kaku - Can you build a real Lightsaber ?

 

Mar 5, 2014

Dr. Michio Kaku attempts to build a real Lightsaber from the Star Wars universe using modern technology

https://www.youtube.com/watch?v=1lr5OUjFDkg


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The Science of Lightsabers

4 May 2022

 

No Earthly material can withstand plasma at these temperatures, and it must be held away from the walls of the reactor by extraordinarily powerful magnetic fields.

The resulting ‘magnetic bottle’ used to confine the plasma in ITER, and many other fusion reactors is called a tokamak, a doughnut-shaped vacuum chamber surrounded by magnetic coils.

Magnetic fields are the key to containing the plasma in a lightsaber too, speculates Felici, though he adds that a plasma capable of cutting through steel would not have to be anything like as hot as that required for nuclear fusion, merely a few thousand degrees...

https://blog.sciencemuseum.org.uk/the-science-of-lightsabers/

 

 

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4000° PLASMA PROTO-LIGHTSABER BUILD (RETRACTABLE BLADE!)

Oct 8, 2020

https://www.youtube.com/watch?v=xC6J4T_hUKg&t=33s

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World's First Lightsaber! - Guinness World Records

Dec 3, 2020

https://www.youtube.com/watch?v=AymYhmayWz4

 

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How I made a REAL LIGHTSABER - Guinness World Records

Jan 21, 2022 

https://www.youtube.com/watch?v=RSSAhmmiZjM

 

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Making a Real Lightsaber Using Rydberg Atoms and Photonic Molecules

Apr 4, 2018

https://www.youtube.com/watch?v=-yjjm49WeE8

 

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Entanglement of Two Atoms Using Rydberg Blockade

2012

https://pages.physics.wisc.edu/~tgwalker/105.Rydberg.pdf

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Observation of Rydberg blockade between two atoms

11 January 2009

https://www.nature.com/articles/nphys1178

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Electronically programmable photonic molecule

14 December 2018

https://www.nature.com/articles/s41566-018-0317-y

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Confinement of ignition and yield on the National Ignition Facility

2015

https://www.academia.edu/18874810/Confinement_of_ignition_and_yield_on_the_National_Ignition_Facility

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The National Ignition Facility: A New Era in High Energy Density Science

June 12, 2009

https://www.osti.gov/servlets/purl/966900

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X marks the spot: Researchers confirm novel method for controlling plasma rotation

 

June 23rd, 2015

 http://phys.org/news/2015-06-method-plasma-rotation.html?utm_source=menu&utm_medium=link&utm_campaign=item-menu

 Rotation is key to the performance of salad spinners, toy tops, and centrifuges, but recent research suggests a way to harness rotation for the future of mankind's energy supply. In papers published in Physics of Plasmas in May and Physical Review Letters this month, Timothy Stoltzfus-Dueck, a physicist at the U.S. Department of Energy's (DOE) Princeton Plasma Physics Laboratory (PPPL), demonstrated a novel method that scientists can use to manipulate the intrinsic - or self-generated - rotation of hot, charged plasma gas within fusion facilities called tokamaks.


 Such a method could prove important for future facilities like ITER, the huge international tokamak under construction in France that will demonstrate the feasibility of fusion as a source of energy for generating electricity. ITER's massive size will make it difficult for the facility to provide sufficient rotation through external means.


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Extending life of plasma channels could allow lasers to be used as lightning rods

 

 September 25, 2015

 

 

 http://www.gizmag.com/plasma-channels-laser-lightning-rods/39588/

 

Today's simple metal lightning rods may be on their way to obsolescence. That's because scientists at The Hebrew University of Jerusalem are developing a high-tech alternative that could potentially reach higher and be more effective – laser lightning rods.

When a high-power laser is shot into the sky, it ionizes airborne molecules in the process. As a result, even once the laser itself is shut off, a trail of ionized particles known as a plasma channel is left in its place. Plasma channels conduct electricity, not unlike a good ol' steel rod.

Led by scientist Jenya Papeer, the Jerusalem team successfully created plasma channels measuring 100 microns in diameter, by firing a laser in pulses lasting just 100 femtoseconds each. Unfortunately, however, after three nanoseconds the plasma cooled off and the channels ceased to exist.

In order to boost those trails' longevity by a factor of 10, the researchers added a second laser that is fired in 10-nanosecond bursts along the path of the first one. Its wider beam envelopes the plasma created by the first beam, keeping it hot and conductive. By boosting the power of that second laser, or even by adding additional beams, it is hoped that the lifespan and the length of the plasma channels could be lengthened further.

Speaking of which, though, the first plasma channels to be produced were only a meter (3.3 ft) long. The researchers addressed this limitation by creating an array of lenses that change the way in which the laser is focused. As a result, it now creates a series of three one-meter-long channels linked end-to-end, effectively forming one 3-meter plasma channel.

That said, by further adjusting the focus and using a powerful enough laser, it should be possible to produce any number of linked plasma channels, creating a lightning rod of any desired length.

A paper on the research will be presented on Oct. 22nd at the Frontiers in Optics conference, in San Jose, California.

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The Air Force Exploration of Pulse-Train Plasmoid Guns

 

23 July 2012 

http://www.topsecretwriters.com/2012/07/the-air-force-exploration-of-pulse-train-plasmoid-guns/

In 1956, Winston Bostick discovered an entity consisting of plasma and magnetic field, which he named the Plasmoid(1).
Plasmoids have a series of cosmic implications and is used to explain various phenomenon, such as the magnetic plasma structures found in comet tails, solar wind, and solar atmosphere.
However, barely four years after the discovery of the Plasmoid, the U.S. government conducted research into the possibility of using Plasmoids as a weapon. TheBlackVault.com acquired a Defense Technical Information Center report through an FOIA request on the matter.

 
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Kilotesla Magnetic Field due to a Capacitor-Coil Target Driven by High Power Laser

Published 30 January 2013

 Laboratory generation of strong magnetic fields opens new frontiers in plasma and beam physics, astro- and solar-physics, materials science, and atomic and molecular physics. Although kilotesla magnetic fields have already been produced by magnetic flux compression using an imploding metal tube or plasma shell, accessibility at multiple points and better controlled shapes of the field are desirable. Here we have generated kilotesla magnetic fields using a capacitor-coil target, in which two nickel disks are connected by a U-turn coil. A magnetic flux density of 1.5 kT was measured using the Faraday effect 650 μm away from the coil, when the capacitor was driven by two beams from the GEKKO-XII laser (at 1 kJ (total), 1.3 ns, 0.53 or 1 μm, and 5 × 10¹⁶ W/cm²).

 http://www.nature.com/srep/2013/130130/srep01170/full/srep01170.html

 

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Boeing Has Patented a Plasma 'Force Field' to Protect Against Shock Waves

30 March 2015

https://www.sciencealert.com/boeing-has-patented-a-plasma-force-field-to-protect-against-shock-waves

 

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Students prove real-life Star Wars deflector shield is possible

May 3, 2014

Star Wars is science fiction, but deflector shields like the ones in the films might be possible with today's technology. There are still a few kinks to work out, but a group of physics students have figured out the basics.

https://www.extremetech.com/extreme/181773-physics-students-figure-out-how-to-make-star-wars-deflector-shields-in-real-life

 
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The Genius Behind The First Force Field

Apr 7, 2024

https://www.youtube.com/watch?v=ApYGMzPgzuo

 

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Scientists announce breakthrough in hypersonic heat shield

January 24, 2024

https://techxplore.com/news/2024-01-scientists-breakthrough-hypersonic-shield.html

 

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Squid-inspired soft material is a switchable shield for light, heat, microwaves

June 28, 2023

https://scienceblog.com/538480/squid-inspired-soft-material-is-a-switchable-shield-for-light-heat-microwaves/

 

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Laser-focused look at spinning electrons shatters world record for precision

February 26, 2024 

 

 

Jefferson Lab's Compton polarimeter laser system, used to measure the parallel spin of electrons, is aligned during the Calcium Radius Experiment at Jefferson Lab.

https://phys.org/news/2024-02-laser-focused-electrons-shatters-world.html

 

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Turning Sound Into a Laser

Aug 20, 2018

https://www.youtube.com/watch?v=aBdVfUnS-pM

 

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The experiment that revealed the atomic world: Brownian Motion

Feb 29, 2024

https://www.youtube.com/watch?v=ZNzoTGv_XiQ

 

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Future opportunities in solar system plasma science through ESA’s exploration programme

14 March 2024

https://www.nature.com/articles/s41526-024-00373-9


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Interstellar Travel: Magnetic Fusion Plasma Engines Could Carry Us Across the Solar System and Beyond

October 22, 2023

https://scitechdaily.com/interstellar-travel-magnetic-fusion-plasma-engines-could-carry-us-across-the-solar-system-and-beyond/

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Wild new NASA plasma tech reduces drag during hypersonic flight

December 8, 2023

NASA's Technology Transfer Program is licensing its rights to a radical new form of propulsion that uses electromagnets to control the flow of plasma over aircraft and spacecraft flying at hypersonic speeds.

https://www.space.com/nasa-hypersonic-magnetohydrodynamic-control

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Firing the Lorentz Plasma Cannon

Mar 12, 2025

https://www.youtube.com/watch?v=lix-vr_AF38

 

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Incredible display of a glowing plasma toroid!

2024 Jul 24

https://www.youtube.com/shorts/trGsFRV8HLM

 

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Plasma toroid by Alexander Glazkov

2024 Feb 24

https://www.youtube.com/shorts/65v0MGhyPCk

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Seeding magnetic fields for laser-driven flux compression in high-energy-density plasmas.

 

2009 Apr


 A compact, self-contained magnetic-seed-field generator (5 to 16 T) is the enabling technology for a novel laser-driven flux-compression scheme in laser-driven targets. A magnetized target is directly irradiated by a kilojoule or megajoule laser to compress the preseeded magnetic field to thousands of teslas. A fast (300 ns), 80 kA current pulse delivered by a portable pulsed-power system is discharged into a low-mass coil that surrounds the laser target. A >15 T target field has been demonstrated using a <100 J capacitor bank, a laser-triggered switch, and a low-impedance (<1 Omega) strip line. The device has been integrated into a series of magnetic-flux-compression experiments on the 60 beam, 30 kJ OMEGA laser [T. R. Boehly et al., Opt. Commun. 133, 495 (1997)]. The initial application is a novel magneto-inertial fusion approach [O. V. Gotchev et al., J. Fusion Energy 27, 25 (2008)] to inertial confinement fusion (ICF), where the amplified magnetic field can inhibit thermal conduction losses from the hot spot of a compressed target. This can lead to the ignition of massive shells imploded with low velocity-a way of reaching higher gains than is possible with conventional ICF.


 http://www.ncbi.nlm.nih.gov/pubmed/19405657

 

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Amplifying Magnetic Fields in High Energy Density Plasmas

 

Ultra high intensity magnetic fields open new opportunities in high energy density plasma science.

 

 October 2012

 (A double coil is assembled on the transmission line of the magnetic field generator (MIFEDS) by Mr. PY Chang, PhD student at the University of Rochester. The MIFEDS device discharges 50 kA of current through the coil generating a ~10 Tesla magnetic field used to magnetize laser-driven targets.)
 

http://science.energy.gov/fes/highlights/2012/fes-2012-10-c/



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Skunk Works Reveals Compact Fusion Reactor Details

  

Oct 15, 2014

 

http://aviationweek.com/technology/skunk-works-reveals-compact-fusion-reactor-details

Lockheed Martin aims to develop compact reactor prototype in five years, production unit in 10

 Hidden away in the secret depths of the Skunk Works, a Lockheed Martin research team has been working quietly on a nuclear energy concept they believe has the potential to meet, if not eventually decrease, the world’s insatiable demand for power.

Dubbed the compact fusion reactor (CFR), the device is conceptually safer, cleaner and more powerful than much larger, current nuclear systems that rely on fission, the process of splitting atoms to release energy. Crucially, by being “compact,” Lockheed believes its scalable concept will also be small and practical enough for applications ranging from interplanetary spacecraft and commercial ships to city power stations. It may even revive the concept of large, nuclear-powered aircraft that virtually never require refueling—ideas of which were largely abandoned more than 50 years ago because of the dangers and complexities involved with nuclear fission reactors. -


-To understand the breakthroughs of the Lockheed concept, it is useful to know how fusion works and how methods for controlling the reaction have a fundamental impact on both the amount of energy produced and the scale of the reactor. Fusion fuel, made up of hydrogen isotopes deuterium and tritium, starts as a gas injected into an evacuated containment vessel. Energy is added, usually by radio-frequency heating, and the gas breaks into ions and electrons, forming plasma.

The super hot plasma is controlled by strong magnetic fields that prevent it from touching the sides of the vessel and, if the confinement is sufficiently constrained, the ions overcome their mutual repulsion, collide and fuse. The process creates helium-4, freeing neutrons that carry the released energy kinetically through the confining magnetic fields. These neutrons heat the reactor wall which, through conventional heat exchangers, can then be used to drive turbine generators.

Until now, the majority of fusion reactor systems have used a plasma control device called a tokamak, invented in the 1950s by physicists in the Soviet Union. The tokamak uses a magnetic field to hold the plasma in the shape of a torus, or ring, and maintains the reaction by inducing a current inside the plasma itself with a second set of electromagnets. The challenge with this approach is that the resulting energy generated is almost the same as the amount required to maintain the self-sustaining fusion reaction.

 An advanced fusion reactor version, the International Thermonuclear Experimental Reactor (ITER), being built in Cadarache, France, is expected to generate 500 MW. However, plasma is not due to be generated until the late 2020s, and derivatives are not likely to be producing significant power until at least the 2040s.

The problem with tokamaks is that “they can only hold so much plasma, and we call that the beta limit,” McGuire says. Measured as the ratio of plasma pressure to the magnetic pressure, the beta limit of the average tokamak is low, or about “5% or so of the confining pressure,” he says. Comparing the torus to a bicycle tire, McGuire adds, “if they put too much in, eventually their confining tire will fail and burst—so to operate safely, they don’t go too close to that.” Aside from this inefficiency, the physics of the tokamak dictate huge dimensions and massive cost. The ITER, for example, will cost an estimated $50 billion and when complete will measure around 100 ft. high and weigh 23,000 tons.


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Scientists in Germany switch on nuclear fusion experiment (Update)

 

February 3, 2016 

 

http://phys.org/news/2016-02-scientists-germany-nuclear-fusion.html

Scientists in Germany flipped the switch Wednesday on an experiment they hope will advance the quest for nuclear fusion, considered a clean and safe form of nuclear power.

Following nine years of construction and testing, researchers at the Max Planck Institute for Plasma Physics in Greifswald injected a tiny amount of hydrogen into a doughnut-shaped device—then zapped it with the equivalent of 6,000 microwave ovens.

The resulting super-hot gas, known as plasma, lasted just a fraction of a second before cooling down again, long enough for scientists to confidently declare the start of their experiment a success.

"Everything went well today," said Robert Wolf, a senior scientist involved with the project. "With a system as complex as this you have to make sure everything works perfectly and there's always a risk."

Among the difficulties is how to cool the complex arrangement of magnets required to keep the plasma floating inside the device, Wolf said. Scientists looked closely at the hiccups experienced during the start-up of the Large Hadron Collider in Switzerland more than five years ago to avoid similar mistakes, he said.

The experiment in Greifswald is part of a world-wide effort to harness nuclear fusion, a process in which atoms join at extremely high temperatures and release large amounts of energy that's similar to what occurs inside the sun.

Advocates acknowledge that the technology is probably many decades away, but argue that—once achieved—it could replace fossil fuels and conventional nuclear fission reactors.

Construction has already begun in southern France on ITER, a huge international research reactor that uses a strong electric current to trap plasma inside a doughnut-shaped device long enough for fusion to take place. The device, known as a tokamak, was conceived by Soviet physicists in the 1950s and is considered fairly easy to build, but extremely difficult to operate.

The team in Greifswald, a port city on Germany's Baltic coast, is focused on a rival technology invented by the American physicist Lyman Spitzer in 1950. Called a stellarator, the device has the same doughnut shape as a tokamak but uses a complicated system of magnetic coils instead of a current to achieve the same result.

 
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New facility to accelerate materials solutions for fusion energy

June 9, 2025

MIT Plasma Science and Fusion Center to establish the Schmidt Laboratory for Materials in Nuclear Technologies. 

Fusion energy has the potential to enable the energy transition from fossil fuels, enhance domestic energy security, and power artificial intelligence. Private companies have already invested more than $8 billion to develop commercial fusion and seize the opportunities it offers. An urgent challenge, however, is the discovery and evaluation of cost-effective materials that can withstand extreme conditions for extended periods, including 150-million-degree plasmas and intense particle bombardment.

To meet this challenge, MIT’s Plasma Science and Fusion Center (PSFC) has launched the Schmidt Laboratory for Materials in Nuclear Technologies, or LMNT (pronounced “element”). Backed by a philanthropic consortium led by Eric and Wendy Schmidt, LMNT is designed to speed up the discovery and selection of materials for a variety of fusion power plant components. 

https://news.mit.edu/2025/new-facility-accelerate-materials-solutions-fusion-energy-0609

 

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New Fusion Technology Promises Cleaner, Cheaper Energy Future

April 27, 2025

In the persistent quest to harness the power of the stars, a new spark of hope has emerged from a laboratory in California. A team of fusion researchers at TAE Technologies, Inc., working alongside physicists from the University of California, has unveiled a bold new approach to fusion energy—one that could radically alter the trajectory of humanity’s energy future. Their groundbreaking work, detailed in the journal Nature Communications, boasts astonishing claims: a reactor capable of producing 100 times more power than conventional designs, operating at half the cost.

For decades, fusion energy has been the holy grail of clean power—an elusive dream that, if realized, could solve the world’s growing energy needs without the environmental baggage of fossil fuels. Yet, despite immense efforts and monumental investments, fusion has remained a dream perpetually “thirty years away.” Could this new technology finally bring that dream within reach?
The Eternal Challenge of Fusion

Fusion, at its core, is simple to understand yet fiendishly difficult to achieve. The process powers the sun, merging hydrogen atoms under immense heat and pressure to release massive amounts of energy. Recreating such conditions on Earth, however, has been a monumental scientific and engineering challenge.

Traditional fusion efforts have largely centered around massive devices like tokamaks—donut-shaped reactors that corral ultra-hot plasma using powerful magnetic fields. These machines, like the famous ITER project in France, are engineering marvels, but they are also staggeringly expensive, energy-hungry, and complex.

Even when functioning as designed, tokamaks consume enormous amounts of electricity just to sustain the magnetic fields that contain the plasma. This immense input has made achieving “net energy”—producing more energy than is consumed—a seemingly Sisyphean task.

https://www.sciencenewstoday.org/new-fusion-technology-promises-cleaner-cheaper-energy-future

 

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Researchers stunned by results of energy experiment using ultrahot plasma: 'We were totally shocked'

June 14, 2025 

A team of U.S. scientists has made a surprising discovery that could help bring fusion energy, a long-hoped-for clean energy source, closer to reality.

In a recent experiment at the University of Rochester, researchers were stunned to find that heat in an ultrahot plasma didn't flow between materials the way they thought it would. At a scorching 180,000 degrees, heat seemed to get stuck between tungsten metal and a plastic coating, leaving that material surprisingly cool, as reported by Interesting Engineering.

"When we looked at the data, we were totally shocked because the heat was not flowing between these materials," said physicist Thomas White, who led the project alongside his former student, Cameron Allen.

https://www.yahoo.com/news/researchers-stunned-results-energy-experiment-111548267.html

 

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Swedish firm aims for 100x plasma confinement boost in new fusion reactor

Dec 14, 2024

The success of fusion power plants hinges on the quality of energy confinement.

A Sweden-based firm has launched a plasma confinement project to achieve commercially viable fusion energy.

The TauEB project by Novatron Fusion Group aims to revolutionize plasma confinement and energy containment in fusion reactors.

Novatron’s project will introduce a first-of-its-kind integration of three physical confinement techniques, which will include Magnetic Confinement, Ambipolar Plugging, and Ponderomotive Confinement.

https://interestingengineering.com/energy/sweden-new-plasma-confinement-project


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Engineers make key breakthrough in quest for limitless energy device: 'We are more than thrilled'

August 11, 2025

Scientists and researchers worldwide are looking for technological breakthroughs that improve clean energy efficiency. One exciting area that continues to draw a lot of focus is the field of fusion energy.

According to the Department of Energy, fusion energy is produced when two nuclei produce a new nucleus. This releases a lot of energy. In fact, it is the process that powers the sun.

To replicate that here on Earth, scientists are trying to figure out how to heat plasma up to a hundred million degrees Celsius so electrons in atomic nuclei can be freed.

A company called General Atomics has announced it completed a shipment of materials to the United Kingdom Atomic Energy Authority to be used in its Mega Ampere Spherical Tokamak Upgrade machine, which is a next-generation fusion experiment.

This involves a new method for heating plasma called Electron Bernstein Wave heating. This process uses electromagnetic waves to boost and direct charged particles inside plasma.

Figuring out fusion technology would be a massive game-changer, as it would mean nearly unlimited amounts of clean energy. This would lower energy costs for everyone and lead to a cleaner, cooler future, as the process does not require the burning of dirty fuels such as coal, oil, and gas.

This is extremely important, as NASA observed that extreme heat events have doubled over the past 40 years.

https://www.yahoo.com/news/articles/engineers-key-breakthrough-quest-limitless-211500770.html 

 

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China takes bold step forward in global race for limitless energy device: 'We have fully mastered the core technologies'

August 4, 2025

China is rapidly closing in on an achievement that could transform the way we power homes, cities, and industries forever.

The country has entered the final assembly phase of a next-generation fusion reactor called the Burning Plasma Experiment Superconducting Tokamak, which is expected to be operational by 2027, per Popular Mechanics.

If it's successful, BEST would mark a major milestone in the race toward achieving fusion energy, a process that mimics the same physics that power the sun.

https://www.yahoo.com/news/articles/china-takes-bold-step-forward-114531311.html 

 

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Fusion Breakthrough: 6 Minutes of Plasma Sets New Reactor Record

07 May 2024

https://www.sciencealert.com/fusion-breakthrough-6-minutes-of-plasma-sets-new-reactor-record


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San Diego Based Company Showcasing Terahertz Wands and "Med Bed" Plasma Technology to the Public

CARLSBAD, CALIFORNIA, USA, October 20, 2022 /EINPresswire.com/ -- Med beds and "med bed" type technology has started to catch the public eye as a science fiction type of technology that apparently exists but yet very few if any are familiar with. These so-called "med beds" offer a wide range of benefits using a variety of technologies to assist with a myriad of health and wellness-related issues.

A San Diego-based company is now providing many of these new technologies to med spas, wellness centers, and the general public. These devices and technology are using frequencies and energy to assist cells and the body in recovery and rejuvenation. Some of the new products and technologies being brought out to the public include terahertz wands, plasma wave generators, and anti-aging bed covers.

Anti-aging bed covers may be one of the more simple yet powerful technology products being offered with earthing, grounding, and FAR infrared. These bed covers assist the body with removing EMF radiation, providing electrons, and neutralizing free radicals along with improved circulation and increased energy with ATP production. The anti-aging bed covers work by just laying down on the cover and the effects with better sleep and recovery are some of the most reported benefits people are experiencing.

Another very fast and popular technology includes terahertz wands which are frequency-based devices that look and work much like a hair dryer but also provide terahertz, quantum scaler, and quartz crystal frequencies and technology. This frequency coming from the wand assists the body with cellular function, detoxification, cellular regeneration, and circulation. The technologies assist the body with all types of health and wellness issues including stiffness, soreness, arthritis, joint pain, kidney functions, gums and mouth, and all types of skin-related issues including wrinkles, Psoriasis, acne, rashes, and more.

"The terahertz wands are quickly becoming a top seller and are assisting people with Osteoperosis, tumors, activating dormant stem cells, hair growth, and more. These small devices are not just beneficial for the body but are also used to "charge water", where the energy from the wand is pointed into the water and the structure of the water is altered to enhance hydration.

When it comes to more powerful med bed-type technologies plasma-based technology is one of the most popular. Plasma is created when gas is charged with enough energy to convert it from gas to plasma. Plasma is what the sun is made of along with lightning and many people including Nikola Tesla have worked with plasma energy for over one hundred years ago. Plasma energy can also be turned into specific frequencies to address very specific cells and health conditions. Many other pioneers including Royal Rife spent years finding the frequencies that cells would resonate at and how plasma could affect the removal of bad cells and promote the health of good cells. The San Diego-based company has a wide variety of plasma-based technology products including "plasma energy spheres" which create a plasma energy field that people can sit into to absorb the plasma energy. Products like the plasma energy spheres are actually creating a live and intelligent energy field that goes back into more science fiction with fact-based physics.

"As more of these plasma and med bed type technologies make their way public GMG Medical will keep finding them and showcasing them as options for improved health and wellness", said GMG Medical CEO Gloria Flores. "We are finding a wide level of interest with the terahertz wands and other plasma technology products which people are using for Alzheimer's, Parkinson's, Lyme disease, and many other ailments". she said. "These products are ideal for assisting with many health issues but also maintaining good health, which is just as important".

https://www.appliedtechnologynews.com/article/596585795-san-diego-based-company-showcasing-terahertz-wands-and-med-bed-plasma-technology-to-the-public


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PyroGenesis Signs Additional Contract with Constellium to Advance Aluminum Furnace Electrification Using Plasma Torch Technology

Aug 5, 2025

Marks next phase of industrial-scale deployment for aluminum sector energy transition. 

https://www.thestar.com/globenewswire/pyrogenesis-signs-additional-contract-with-constellium-to-advance-aluminum-furnace-electrification-using-plasma-torch-technology/article_2c1c9be5-d527-5beb-bdb4-968eab2723d8.html


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This Explosive Plasma Discovery by a US Lab Is About to Redefine Nuclear Energy and Microchip Performance Forever

May 26, 2025

In a groundbreaking development poised to revolutionize both energy and electronics, scientists at the U.S. Department of Energy’s Princeton Plasma Physics Laboratory have unveiled a new simulation method that enhances fusion research and chip manufacturing by providing unprecedented insights into the complex behaviors of plasma systems.

https://www.sustainability-times.com/research/this-explosive-plasma-discovery-by-a-us-lab-is-about-to-redefine-nuclear-energy-and-microchip-performance-forever/

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GPS Moonshots: Creating a star on earth

 

December 22, 2014
 

http://www.cnn.com/videos/bestoftv/2014/12/22/exp-gps-moonshots-iter-sot.cnn




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ITER

 ITER (International Thermonuclear Experimental Reactor and Latin for "the way") is an international nuclear fusion research and engineering megaproject, which is currently building the world's largest experimental tokamak nuclear fusion reactor adjacent to the Cadarache facility in the south of France. The ITER project aims to make the long-awaited transition from experimental studies of plasma physics to full-scale electricity-producing fusion power plants.

http://en.wikipedia.org/wiki/ITER


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Hydrogen-Boron vs. Deuterium-Tritium

 

Nuclear fusion has the potential to generate power without the radioactive waste of nuclear fission, but that depends on which atoms you decide to fuse.  Conventional fusion approaches work with deuterium and tritium (DT), while focus fusion works with hydrogen and boron eleven (pB¹¹).


http://focusfusion.org/index.php/site/article/deuterium_tritium_vs_hydrogen_boron/

 

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We can even harness energy from different chemicals and gases, these chemicals can be made for self-sustaining sources of renewable energy. Scientists still question the footprint that may be left, when using of combination of different chemicals for a source of clean energy.


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HOW IT WORKS: Fusion Power

https://www.youtube.com/watch?v=LJZvFlo0iNs


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Small-scale nuclear fusion may be a new energy source

September 25, 2015

Fusion energy may soon be used in small-scale power stations. This means producing environmentally friendly heating and electricity at a low cost from fuel found in water. Both heating generators and generators for electricity could be developed within a few years, according to new research.


 Nuclear fusion is a process whereby atomic nuclei melt together and release energy. Because of the low binding energy of the tiny atomic nuclei, energy can be released by combining two small nuclei with a heavier one. A collaboration between researchers at the University of Gothenburg and the University of Iceland has been to study a new type of nuclear fusion process. This produces almost no neutrons but instead fast, heavy electrons (muons), since it is based on nuclear reactions in ultra-dense heavy hydrogen (deuterium).

 http://www.sciencedaily.com/releases/2015/09/150925085550.htm

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Nuclear fusion, the ultimate clean energy

 

20th March, 2015

 http://theforeigner.no/pages/columns/nuclear-fusion-the-ultimate-clean-energy/

 
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Magnetic fields and lasers elicit graphene secret

Nov 24, 2014

Scientists at the Helmholtz-Zentrum Dresden-Rossendorf (HZDR) have studied the dynamics of electrons from the "wonder material" graphene in a magnetic field for the first time. This led to the discovery of a seemingly paradoxical phenomenon in the material. Its understanding could make a new type of laser possible in the future. Together with researchers from Berlin, France, the Czech Republic and the United States, the scientists precisely described their observations in a model and have now published their findings in the scientific journal Nature Physics.

Read more at: http://phys.org/news/2014-11-magnetic-fields-lasers-elicit-graphene.html#jCp

http://phys.org/news/2014-11-magnetic-fields-lasers-elicit-graphene.html

Graphene is considered a "wonder material": its breaking strength is higher than steel and it conducts electricity and heat more effectively than copper. As a two-dimensional structure consisting of only a single layer of carbon atoms, it is also flexible, nearly transparent and approximately one million times thinner than a sheet of paper. Furthermore, shortly after its discovery ten years ago, scientists recognized that the energy states of graphene in a magnetic field - known as Landau levels - behave differently than those of semiconductors. "Many fascinating effects have been discovered with graphene in magnetic fields, but the dynamics of electrons have never been studied in such a system until now," explains physicist Dr. Stephan Winnerl from HZDR.

The HZDR researchers exposed the graphene to a four-Tesla magnetic field - forty times stronger than a horseshoe magnet. As a result, the electrons in graphene occupy only certain energy states. The negatively charged particles were virtually forced on tracks. These energy levels were then examined with free-electron laser light pulses at the HZDR. "The laser pulse excites the electrons into a certain Landau level. A temporally delayed pulse then probes how the system evolves," explains Martin Mittendorff, doctoral candidate at the HZDR and first author of the paper.

Electron redistribution surprises scientists

The result of the experiments has astonished the researchers. This particular energy level, into which new electrons were pumped using the laser, gradually emptied. Winnerl illustrates this paradoxical effect using an everyday example: "Imagine a librarian sorting books on a bookshelf with three shelves. She places one book at a time from the lower shelf onto the middle shelf. Her son is simultaneously 'helping' by taking two books from the middle shelf, placing one of them on the top shelf, the other on the bottom. The son is very eager and now the number of books on the middle shelf decreases even though this is precisely the shelf his mother wishes to fill."

Because there were neither experiments nor theories regarding such dynamics before, the Dresden physicists initially had difficulty interpreting the signals correctly. After a number of attempts, however, they found an explanation: collisions between electrons cause this unusual rearrangement. "This effect has long been known as Auger scattering, but no one expected it would be so strong and would cause an energy level to become depleted," explains Winnerl.

This new discovery could be used in the future for developing a laser that can produce light with arbitrarily adjustable wavelengths in the infrared and terahertz ranges. "Such a Landau-level laser was long considered impossible, but now with graphene this semiconductor physicists' dream could become a reality," says Winnerl enthusiastically.

 

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Magnetized target fusion

 

Magnetized target fusion (MTF) is a relatively new approach to producing fusion power that combines features of magnetic confinement fusion (MCF) and inertial confinement fusion (ICF) approaches. Like the magnetic approach, the fusion fuel is confined at lower density by magnetic fields while it is heated into a plasma. Like the inertial approach, fusion is initiated by rapidly squeezing the target to greatly increase fuel density and temperature. Although the resulting density is far lower than in traditional ICF, it is thought that the combination of longer confinement times and better heat retention will let MTF yield the same efficiencies, yet be far easier to build. The term magneto-inertial fusion (MIF) is similar, but encompasses a wider variety of arrangements. The two terms are often applied interchangeably to experiments.

http://en.wikipedia.org/wiki/Magnetized_target_fusion


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Levitated dipole

A levitated dipole is a nuclear fusion experiment using a solid superconducting torus which is magnetically levitated inside the reactor chamber. It is believed that such an apparatus could contain plasma more efficiently than other fusion reactor designs. The superconductor forms an axisymmetric magnetic field of a nature similar to Earth's or Jupiter's magnetospheres. The machine was run in a collaboration between MIT and Columbia University.

The Levitated Dipole Experiment was funded by the US Department of Energy's Office of Fusion Energy, but funding for the LDX was ended in November 2011 to concentrate resources on Tokamak designs

 http://en.wikipedia.org/wiki/Levitated_dipole


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With lazers, magnetism, vacuums and sustainable energy, it is possible to make many new inventions.




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Plasma propulsion engine

 A plasma propulsion engine is a type of electric propulsion that generates thrust from a quasi-neutral plasma. This is in contrast to ion thruster engines, which generates thrust through extracting an ion current from plasma source, which is then accelerated to high velocities using grids/anodes.

 https://en.wikipedia.org/wiki/Plasma_propulsion_engine

 

--------------------




For more information on magnets for harvesting energy, view the chapter titled "Magnetic energy."

 


 ------------------------------------------------

Plasma research shows promise for future compact accelerators

 

December 22, 2015 

 

 A transformative breakthrough in controlling ion beams allows small-scale laser-plasma accelerators to deliver unprecedented power densities. That development offers benefits in a wide range of applications, including nuclear fusion experiments, cancer treatments, and security scans to detect smuggled nuclear materials.

"In our research, plasma uses the energy stored in its electromagnetic fields to self-organize itself in such a way to reduce the energy-spread of the laser-plasma ion accelerator," said Sasikumar Palaniyappan of Los Alamos National Laboratory's Plasma Physics group. "In the past, most of the attempts to solve this problem required active plasma control, which is difficult."


Laser-plasma accelerators shoot a high-energy laser into a cloud of plasma, releasing a beam of ions, or electrically charged particles, in a fraction of the distance required by conventional accelerators. The laser generates electromagnetic fields in the plasma.

 Using a computer simulation called Vector-Particle-In-Cell (VPIC), the Laboratory's team of physicists and computational scientists developed a scheme that enlists the electromagnetic fields so the beam essentially contains itself, reducing the energy spread, making the beam more efficient, and concentrating more energy on its target.

http://phys.org/news/2015-12-plasma-future-compact.html


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Researchers identify zebra-like stripes of plasma in a patch of space

 

July 14, 2015

 

 Since the early 1970s, orbiting satellites have picked up on noise-like plasma waves very close to the Earth's magnetic field equator. This "equatorial noise," as it was then named, seemed to be an unruly mess of electric and magnetic fields oscillating at different frequencies in the form of plasma waves.

Now a team from MIT, the University of California at Los Angeles, the University of Sheffield, and elsewhere has detected a remarkably orderly pattern amid the noise.
 

http://phys.org/news/2015-07-zebra-like-stripes-plasma-patch-space.html


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In plasmonics, 'optical losses' could bring practical gain

 

January 26, 2016

 What researchers had thought of as a barrier to developing advanced technologies based on the emerging field of plasmonics is now seen as a potential pathway to practical applications in areas from cancer therapy to nanomanufacturing.

Plasmonic materials contain features, patterns or elements that enable unprecedented control of light by harnessing clouds of electrons called surface plasmons. It could allow the miniaturization of optical technologies, bringing advances such as nano-resolution imaging and computer chips that process and transmit data using light instead of electrons, representing a potential leap in performance.

However, the development of advanced optical technologies using plasmonics has been hampered because components under development cause too much light to be lost and converted into heat. But now researchers are finding that this "loss-induced plasmonic heating" could be key to development of various advanced technologies, said Vladimir M. Shalaev, co-director of the new Purdue Quantum Center, scientific director of nanophotonics at the Birck Nanotechnology Center in the university's Discovery Park and a distinguished professor of electrical and computer engineering.

 http://phys.org/news/2016-01-plasmonics-optical-losses-gain.html

 

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Making Quantum ‘Waves’ in Ultrathin Materials – Plasmons Could Power a New Class of Technologies

 

May 15, 2020

 

Study co-led by Berkeley Lab reveals how wavelike plasmons could power up a new class of sensing and photochemical technologies at the nanoscale.

 

Wavelike, collective oscillations of electrons known as “plasmons” are very important for determining the optical and electronic properties of metals.

 

 In atomically thin 2D materials, plasmons have an energy that is more useful for applications, including sensors and communication devices, than plasmons found in bulk metals. But determining how long plasmons live and whether their energy and other properties can be controlled at the nanoscale (billionths of a meter) has eluded many.

https://scitechdaily.com/making-quantum-waves-in-ultrathin-materials-plasmons-could-power-a-new-class-of-technologies/

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Plasma Gasification: Revolutionizing Waste Management

August 12, 2024

Plasma (“the fourth state of matter”) is an extremely high-temperature, highly ionized gas that is able to carry an electric current. Natural plasma includes lightning and gas at the surface of the sun, while man-made plasma is formed using a plasma torch to pass an electric current through a gas like oxygen. The reaction dissociates the gas into electrons and ions and increases its temperature to nearly as hot as the sun’s surface. This plasma can then be used for plasma gasification, a process that breaks waste down into basic chemicals. 

Plasma gasification can turn “any kind of trash” into chemical products and clean fuels. Industry leader InEnTec was founded in 1995 to focus on governments and companies with large amounts of toxic waste. Their patented Plasma Enhanced Melter (PEM) system is deployed in 13 facilities worldwide. “Back in the early ’90s, global warming was more of an academic pursuit,” InEnTech co-founder, president, and CEO Jeffrey E. Surma told MIT News in 2021. With climate change a leading global challenge, his co-founder, Daniel R. Cohn, believes it is time for InEnTech to expand its impact. 

“About 130 million tons of waste per year go into landfills in the U.S., and that produces at least 130 million tons of CO2-equivalent emissions,” Cohn argues. Most of these emissions are methane, a greenhouse gas that is 28 times more potent than carbon dioxide (CO2) and a global concern. The Global Methane Initiative (GMI) is an international public-private partnership focused on advancing methane mitigation in oil and gas, biogas, and coal mines. By utilizing plasma gasification and reducing or even eliminating landfills and other waste, the GMI could make significant advancements.

https://www.aii.org/plasma-gasification-revolutionizing-waste-management/

 

____________________________________

 

NEWS: High field magnets

https://www.psfc.mit.edu/news/topic/high-field-magnets

 

____________________________________

 


NEWS: Magnetic fusion energy

https://www.psfc.mit.edu/news/topic/magnetic-fusion-energy

 
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Researchers create stable superconductor enhanced by magnetism

April 4, 2024

An international team including researchers from the University of Würzburg has succeeded in creating a special state of superconductivity. This discovery could advance the development of quantum computers. The results are published in Nature Physics...

https://phys.org/news/2024-04-stable-superconductor-magnetism.html

 

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Plasma for Fusion: How magnets are paving the way for clean energy

January 25, 2022

https://sitn.hms.harvard.edu/flash/2022/plasma-for-fusion-how-magnets-are-paving-the-way-for-clean-energy/

 

____________________________________

 


Magnetically confined plasmas articles from across Nature Portfolio

Magnetically confined plasmas are those plasmas that are trapped using magnetic fields. Magnetic fields can prevent high-temperature plasma coming into contact with solid materials that it could damage or destroy. Magnetically confined plasmas offer one possible route to sustained nuclear fusion.

https://www.nature.com/subjects/magnetically-confined-plasmas

 
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New superconducting magnet breaks magnetic field strength records, paving the way for fusion energy

September 8, 2021

https://phys.org/news/2021-09-superconducting-magnet-magnetic-field-strength.html

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Tests show high-temperature superconducting magnets are ready for fusion

Date: March 4, 2024

Source: Massachusetts Institute of Technology

Summary: A comprehensive study of high-temperature superconducting magnets confirms they meet requirements for an economic, compact fusion power plant.

https://www.sciencedaily.com/releases/2024/03/240304135732.htm


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New method for creating transparent magnetic materials using laser heating

Dec 14, 2023

https://phys.org/news/2023-12-method-transparent-magnetic-materials-laser.html

In a significant advancement in optical technology, researchers from Tohoku University and Toyohashi University of Technology have developed a new method for creating transparent magnetic materials using laser heating. This breakthrough, recently published in the journal Optical Materials, presents a novel approach to integrating magneto-optical materials with optical devices, a long-standing challenge in the field.

"The key to this achievement lies in creating Cerium-substituted Yttrium Iron Garnet (Ce:YIG), a transparent magnetic material, employing a specialized laser heating technique," says Taichi Goto, associate professor at Tohoku University's Electrical Communication Research Institute (RIEC) and co-author of the study. "This method addresses the key challenge of integrating magneto-optical materials with optical circuits without damaging them—a problem that has hindered advancements in miniaturizing optical communication devices."

Magneto-optical isolators are vital for ensuring stable optical communication. They act like traffic directors for light signals, allowing them to move in one direction but not the other. Integrating these isolators into silicon-based photonic circuits is challenging due to the high-temperature processes typically involved.

As a result of this conundrum, Goto and his colleagues focused their attention on laser annealing—a technique that selectively heats specific areas of a material by laser. This allows for precise control, influencing only the targeted regions without affecting surrounding areas.

Previous studies had used this to selectively heat bismuth-substituted yttrium iron garnet (Bi: YIG) films deposited on a dielectric mirror. This allows the Bi:YIG to crystalize without affecting the dielectric mirror.

However, when working with Ce:YIG, an ideal material for optical devices due to its magnetic and optical properties, problems arise because exposure to the air results in unwanted chemical reactions.

To avoid this, the researchers engineered a new device that heats materials in a vacuum, i.e., without air, using a laser. This allowed for precise heating of small areas (about 60 micrometers) without altering the surrounding material.

"The transparent magnetic material created through this method is expected to significantly enhance the development of compact magneto-optical isolators, crucial for stable optical communication," says Goto. "Additionally, it opens avenues for creating powerful miniaturized lasers, high-resolution displays, and small optical devices."

 
____________________________________

Strong magnetic fields change how friction works in plasma

August 16, 2021

Rather than just slowing down a charged particle moving through a plasma, friction can also push from the side in a strong magnetic field.

https://news.engin.umich.edu/2021/08/strong-magnetic-fields-change-how-friction-works-in-plasma/

____________________________________

 


Electron scale magnetic reconnections in laser produced plasmas

29 June 2023

https://link.springer.com/article/10.1007/s41614-023-00125-4


____________________________________


Push and pull magnetic reconnection driven by intense laser interaction with double-coil capacitor target

24 February 2023

https://iopscience.iop.org/article/10.1088/1361-6587/acbb24

____________________________________



Innovative new magnet could facilitate development of fusion and medical devices

March 4, 2022

https://phys.org/news/2022-03-magnet-fusion-medical-devices.html


____________________________________


New Magnetic Device Makes Microelectronic Chips More Sustainable

Mar 19, 2024

An invention will allow chips to fit more data in a smaller space and operate with better energy efficiency

https://www.mccormick.northwestern.edu/news/articles/2024/03/new-magnetic-device-makes-microelectronic-chips-more-sustainable/


____________________________________


Laser-produced plasmas articles within Nature Physics

https://www.nature.com/subjects/laser-produced-plasmas/nphys

____________________________________


Laser produced electromagnetic pulses: generation, detection and mitigation

09 June 2020

https://www.cambridge.org/core/journals/high-power-laser-science-and-engineering/article/laser-produced-electromagnetic-pulses-generation-detection-and-mitigation/746D683F7B7CA0C05D0756EE1C62102F

____________________________________


Research team presents a new type of particle accelerator

May 20, 2021

https://phys.org/news/2021-05-team-particle.html

____________________________________


Laser–plasma-accelerators—A novel, versatile tool for space radiation studies

2011

https://www.sciencedirect.com/science/article/abs/pii/S0168900211001768

____________________________________


Demonstration of a compact plasma accelerator powered by laser-accelerated electron beams

17 May 2021

https://www.nature.com/articles/s41467-021-23000-7

____________________________________

 

A trio of paths toward the discovery machine of the future

03/19/24

Proton-proton collider

Muon collider

Plasma-wakefield collider

https://www.symmetrymagazine.org/article/a-trio-of-paths-toward-the-discovery-machine-of-the-future?language_content_entity=und

 
____________________________________

 

Laser-plasma technology: the future of particle acceleration

14 Jan 2021

https://www.thalesgroup.com/en/worldwide-market-specific-solutions-lasers/science-applications/news/laser-plasma-technology-future

____________________________________



Plasmas could be used to make the world's most powerful laser

22 August 2022

Because plasma can shape very intense light without being damaged, it could be used to make components for lasers thousands of times more powerful than the strongest ones that exist

https://www.newscientist.com/article/2334804-plasmas-could-be-used-to-make-the-worlds-most-powerful-laser/


____________________________________


Generation of intense magnetic wakes by relativistic laser pulses in plasma

30 January 2023

https://www.nature.com/articles/s41598-023-28753-3


____________________________________


Manipulation of polarizations for broadband terahertz waves emitted from laser plasma filaments

27 August 2018

Abstract

Polarization control of broadband terahertz waves is essential for applications in many areas, such as materials science, medical and biological diagnostics, near-field communications and public securities. Conventional methods for polarization control are limited to narrow bandwidth and often with low efficiency. Here, based on theoretical and experimental studies, we demonstrate that the two-colour laser scheme in gas plasma can provide effective control of elliptically polarized terahertz waves, including their ellipticity, azimuthal angle and chirality. This is achieved with a circularly polarized laser at the fundamental frequency and its linearly polarized second harmonic, a controlled phase difference between these two laser components, as well as a suitable length of the laser plasma filament. Flexible control of ellipticity and azimuthal angle is demonstrated with our theoretical model and systematic experiments. This offers a unique and flexible technique on the polarization control of broadband terahertz radiation suitable for a wide range of applications.

https://www.nature.com/articles/s41566-018-0238-9

____________________________________


Scientists produce densest artificial ionospheric plasma clouds using HAARP

Date: February 25, 2013

Source: Naval Research Laboratory

Summary: Glow discharges in the upper atmosphere were generated to explore ionospheric phenomena and its impact on communications and space weather.

https://www.sciencedaily.com/releases/2013/02/130225112504.htm


____________________________________


NEWS: High field magnets

https://www.psfc.mit.edu/news/topic/high-field-magnets

____________________________________


NEWS: Magnetic fusion energy

https://www.psfc.mit.edu/news/topic/magnetic-fusion-energy

____________________________________


Researchers create stable superconductor enhanced by magnetism

April 4, 2024

An international team including researchers from the University of Würzburg has succeeded in creating a special state of superconductivity. This discovery could advance the development of quantum computers. The results are published in Nature Physics...

https://phys.org/news/2024-04-stable-superconductor-magnetism.html

____________________________________


Magnetic pumping pushes plasma particles to high energies

November 5, 2018

https://phys.org/news/2018-11-magnetic-plasma-particles-high-energies.html

____________________________________


Effect of permanent magnets on plasma confinement and ion beam properties in a double layer helicon plasma source

26 June 2019

https://www.cambridge.org/core/journals/journal-of-plasma-physics/article/effect-of-permanent-magnets-on-plasma-confinement-and-ion-beam-properties-in-a-double-layer-helicon-plasma-source/5C277CBE933FB32404A2156EC526EF9D

____________________________________


Science Made Simple: What Is Plasma Confinement?

August 10, 2021

 

Image of the inside of a magnetic confinement experiment during plasma discharge. In a tokamak, plasma particles are confined and shaped by magnetic field lines that combine to act like an invisible bottle. Pictured, the spherical tokamak MAST at the Culham Centre for Fusion Energy (UK), where over 30,000 man-made ”stars” have been created.

What Is Plasma Confinement?

Plasma confinement refers to the containment of a plasma by various forces at the extreme conditions necessary for thermonuclear fusion reactions. These conditions exist naturally in stars, where they are sustained by the force of gravity. In the laboratory, researchers use strong magnetic fields to confine plasma. This magnetic confinement strategy may allow them to confine fusion grade plasmas over the long term. Another confinement strategy relies on the inertia of imploding matter. This inertial confinement strategy has been demonstrated on Earth in hydrogen bomb detonations and specialized facilities. Inertial confinement is an active research area. Laboratories use high power lasers or electrical discharges, to compress hydrogen fuel to very high densities for billionths of a second.

Plasma Confinement Facts

    Magnetically confined plasmas have achieved temperatures 10 times hotter than the core of our sun.
    ITER will be the first burning plasma in the world. It aims to generate 500 megawatts of fusion power–10 times more power than will be injected. NIF is the most energetic laser in the world with 2 megajoules of light energy (the energy consumed by 20,000 100-watt light bulbs in one second) delivered in 16 nanoseconds.

https://scitechdaily.com/science-made-simple-what-is-plasma-confinement/

____________________________________


Magnetic confinement fusion

Magnetic confinement fusion (MCF) is an approach to generate thermonuclear fusion power that uses magnetic fields to confine fusion fuel in the form of a plasma. Magnetic confinement is one of two major branches of controlled fusion research, along with inertial confinement fusion.

https://en.wikipedia.org/wiki/Magnetic_confinement_fusion

____________________________________


Liquid lithium on the walls of a fusion device helps the plasma within maintain a hot edge

January 23, 2024

https://phys.org/news/2024-01-liquid-lithium-walls-fusion-device.html

____________________________________


Laboratory investigation of particle acceleration and magnetic field compression in collisionless colliding fast plasma flows

20 June 2019

https://www.nature.com/articles/s42005-019-0160-6


____________________________________


World's strongest fusion magnet brings new power to nuclear pursuit

September 08, 2021

https://newatlas.com/energy/worlds-strongest-fusion-magnet-power-nuclear-pursuit/

____________________________________


Newly discovered quantum magnet unleashes electronics potential

July 12, 2023

Three MIT scientists and their collaborators publish groundbreaking paper in Nature Communications detailing their discovery of a paradigm-shifting magnet.

https://www.psfc.mit.edu/news/2023/newly-discovered-quantum-magnet-unleashes-electronics-potential

____________________________________


Superconductors for fusion: a roadmap

13 September 2021

https://iopscience.iop.org/article/10.1088/1361-6668/ac0992

____________________________________


Physics of magnetized dusty plasmas

28 November 2021

https://link.springer.com/article/10.1007/s41614-021-00060-2

____________________________________


Behavior of compressed plasmas in magnetic fields

26 November 2020

https://link.springer.com/article/10.1007/s41614-020-00048-4

____________________________________

 

Is this the Force device researchers are looking for?

6 Sep 2023

    Military scientists are experimenting with a prototype that uses magnetic plasma rings to manipulate distant objects in space

    The new approach could be used for satellite recovery, delivery missions and deflecting space debris

In the science fiction universe of Hollywood’s Star Wars, the Jedi are able to use the Force to move objects around without physical contact, a manoeuvre referred to as “Force push” or “Force pull”.

The ability allows the Jedi to levitate themselves or others, and to manipulate objects in more complex ways, such as constructing structures or repairing machinery...

https://www.scmp.com/news/china/science/article/3233110/force-device-chinese-researchers-are-looking

____________________________________


Electromagnetic Waves in Plasmas

https://ocw.mit.edu/courses/22-611j-introduction-to-plasma-physics-i-fall-2003/75c75c5df51f8fba1b2a903fde937ddc_chap5.pdf

____________________________________


Superior Ionic Plasma Thruster Inspired By Nature

Apr 27, 2024

https://www.youtube.com/watch?v=WC92SStn7vY

____________________________________


Powerful Magnetic Accelerator, the Brick Breaker | Magnetic Games

Sep 30, 2023

https://www.youtube.com/watch?v=7rn5Y4keMJU

____________________________________


The Plasma Magnet for Sailing the Solar Wind

February 06 2005

https://pubs.aip.org/aip/acp/article-abstract/746/1/1171/605806/The-Plasma-Magnet-for-Sailing-the-Solar-Wind?redirectedFrom=fulltext

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Conductive Metal–Organic Frameworks with Tunable Dielectric Properties for Boosting Electromagnetic Wave Absorption

June 23, 2023

https://pubs.acs.org/doi/10.1021/acsnano.3c02170

____________________________________


Researchers measure and control interactions between magnetic ripples using lasers

February 7, 2024

Fundamental step toward ultrafast magnetism-based computers comes from multi-institution team involving UCLA

https://newsroom.ucla.edu/releases/magnetic-ripple-interaction-step-toward-ultrafast-computers

____________________________________


Plasma magnet

A plasma magnet is a proposed spacecraft propulsion device that uses a dipole magnetic field to capture energy from the solar wind. The field acts as a sail, using the captured energy to propel the spacecraft analogously to how the wind propels a sailing vessel. It could accelerate a vessel moving away from the sun and decelerate it when approaching a distant star at the end of an interstellar journey. Thrust vectoring and steering could be achieved by manipulating the dipole tilt for any type of magnetic sail.

https://en.wikipedia.org/wiki/Plasma_magnet

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Magnetic Fusion Plasma Engines Could Carry us Across the Solar System and Into Interstellar Space

https://www.universetoday.com/163348/magnetic-fusion-plasma-engines-could-carry-us-across-the-solar-system-and-into-interstellar-space/

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Magnetohydrodynamic drive

A magnetohydrodynamic drive or MHD accelerator is a method for propelling vehicles using only electric and magnetic fields with no moving parts, accelerating an electrically conductive propellant (liquid or gas) with magnetohydrodynamics. The fluid is directed to the rear and as a reaction, the vehicle accelerates forward.

https://en.wikipedia.org/wiki/Magnetohydrodynamic_drive


____________________________________


Magnets at the LIMITS of Scientific Knowledge

Jan 26, 2024

https://www.youtube.com/watch?v=WPfcpHVlYZA

____________________________________


Designing a Futuristic Magnetic Turbine (MHD drive)

Nov 30, 2023

https://www.youtube.com/watch?v=WgAIPOSc4TA

 
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Researchers make a quantum computing leap with a magnetic twist

June 28, 2023

https://phys.washington.edu/news/2023/06/28/researchers-make-quantum-computing-leap-magnetic-twist

 

____________________________________


Making Anti-gravity tubes - Copper & Silver! - Lenz's law - Metal casting Experiment

Dec 22, 2023

 

https://www.youtube.com/watch?v=VIV3NqSDjAg


____________________________________


Defying Gravity - HUGE Neodymium Magnet vs Copper Tube Experiment - The Power of Lenz's Law!

Feb 4, 2024

 

https://www.youtube.com/watch?v=TRihrPnLt78

 
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Chapter 14: fusion



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____________________________________

 

 

 

 


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Cold fusion reactor verified by third-party researchers, seems to have 1 million times the energy density of gasoline

 October 9, 2014

 Andrea Rossi’s E-Cat — the device that purports to use cold fusion to generate massive amounts of cheap, green energy — has been verified by third-party researchers, according to a new 54-page report. The researchers observed a small E-Cat over 32 days, where it produced net energy of 1.5 megawatt-hours, or “far more than can be obtained from any known chemical sources in the small reactor volume.” The researchers were also allowed to analyze the fuel before and after the 32-day run, noting that the isotopes in the spent fuel could only have been obtained by “nuclear reactions” — a conclusion that boggles the researchers: “… It is of course very hard to comprehend how these fusion processes can take place in the fuel compound at low energies.”

 http://www.extremetech.com/extreme/191754-cold-fusion-reactor-verified-by-third-party-researchers-seems-to-have-1-million-times-the-energy-density-of-gasoline

 

____________________________________

Focus Fusion: The Fastest Route to Cheap, Clean Energy

https://www.youtube.com/watch?v=yhKB-VxJWpg

8:00 -  Goldman Sachs funding


____________________________________ 

Nuclear Fission vs. Nuclear Fusion

http://chemwiki.ucdavis.edu/Physical_Chemistry/Nuclear_Chemistry/Fission_and_Fusion/Nuclear_Fission_vs_Nuclear_Fusion


____________________________________ 

 

MIT Physicists Create Ultracold Molecules of ²³Na⁴⁰K

 

June 10, 2015

(MIT researchers have successfully cooled a gas of sodium potassium (NaK) molecules to a temperature of 500 nanokelvin. In this artist’s illustration, the NaK molecule is represented with frozen spheres of ice merged together: the smaller sphere on the left represents a sodium atom, and the larger sphere on the right is a potassium atom.)

 http://scitechdaily.com/mit-physicists-create-ultracold-molecules-of-23na40k/

A team of physicists from MIT has successfully cooled molecules in a gas of sodium potassium (NaK) to a temperature of 500 nanokelvins, creating ultracold molecules.
The air around us is a chaotic superhighway of molecules whizzing through space and constantly colliding with each other at speeds of hundreds of miles per hour. Such erratic molecular behavior is normal at ambient temperatures.
But scientists have long suspected that if temperatures were to plunge to near absolute zero, molecules would come to a screeching halt, ceasing their individual chaotic motion and behaving as one collective body. This more orderly molecular behavior would begin to form very strange, exotic states of matter — states that have never been observed in the physical world.
Now experimental physicists at MIT have successfully cooled molecules in a gas of sodium potassium (NaK) to a temperature of 500 nanokelvins — just a hair above absolute zero, and over a million times colder than interstellar space. The researchers found that the ultracold molecules were relatively long-lived and stable, resisting reactive collisions with other molecules. The molecules also exhibited very strong dipole moments — strong imbalances in electric charge within molecules that mediate magnet-like forces between molecules over large distances.


____________________________________

 

Cold Atom Laboratory Chills Atoms to New Lows

 

September 26, 2014

 

 

 (Artist's concept of an atom chip for use by NASA's Cold Atom Laboratory (CAL) aboard the International Space Station. CAL will use lasers to cool atoms to ultracold temperatures.Image Credit: NASA)

 

http://www.jpl.nasa.gov/news/news.php?feature=4312

 

Cold Atom Laboratory researchers used lasers to optically cool rubidium atoms to temperatures almost a million times colder than that of the depths of space. The atoms were then magnetically trapped, and radio waves were used to cool the atoms 100 times lower. The radiofrequency radiation acts like a knife, slicing away the hottest atoms from the trap so that only the coldest remain.

The research is at the point where this process can reliably create a Bose-Einstein condensate in just seconds.

"This was a tremendous accomplishment for the CAL team. It confirms the fidelity of the instrument system design and provides us a facility to perform science and hardware verifications before we get to the space station," said CAL Project Manager Anita Sengupta of JPL.

While so far, the Cold Atom Laboratory researchers have created Bose-Einstein condensates with rubidium atoms, eventually they will also add in potassium. The behavior of two condensates mixing together will be fascinating for physicists to observe, especially in space.

Besides merely creating Bose-Einstein condensates, CAL provides a suite of tools to manipulate and probe these quantum gases in a variety of ways. It has a unique role as a facility for the atomic, molecular and optical physics community to study cold atomic physics in microgravity, said David Aveline of JPL, CAL ground testbed lead.

 

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Molecules in the Spotlight

 

August 8, 2025

 

Molecules in the Spotlight: Snapshots Reveal the Eternal Dance of Particles

 

Frankfurt physicists observe coupled quantum zero-point motion of a molecule’s atoms

 

Researchers at Goethe University Frankfurt have, for the first time, directly visualized the so-called quantum zero-point motion in a larger molecule. This motion is exhibited by particles even at absolute zero temperature. In a collaborative experiment with the Max Planck Institute for Nuclear Physics, the University of Hamburg, the European XFEL, and other partners, they managed to make this “eternal dance” of the atoms visible. The discovery was made possible by the COLTRIMS reaction microscope developed in Frankfurt, which is capable of reconstructing molecular structures. The findings have now been published in the journal Science.

 

Most of us find it difficult to grasp the quantum world: According to Heisenberg’s uncertainty principle, it’s like observing a dance without being able to see simultaneously exactly where someone is dancing and how fast they’re moving – you always must choose to focus on one. And yet, this quantum dance is far from chaotic; the dancers follow a strict choreography. In molecules, this strange behavior has another consequence: Even if a molecule should be completely frozen at absolute zero, it never truly comes to rest. The atoms it is made of perform a constant, never-ending quiet dance driven by so-called zero-point energy.

 

https://nanodigest.in/molecules-in-the-spotlight/ 

 

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Wendelstein 7-X sets new performance records in fusion research

June 3, 2025

International efforts included a diagnostic and control system from the Princeton Plasma Physics Laboratory

A new fusion

record was set thanks to researchers in Germany and the U.S. The international effort moves the world one step closer to a commercial fusion power plant, which will need to run continuously at temperatures hotter than the sun. 

The record-breaking machine, known as the Wendelstein 7-X (W7-X), is a stellarator. This twisty fusion system confines plasma
using external magnets so the nuclei of atoms fuse together and release energy. W7-X is operated by the Max Planck Institute for Plasma Physics (IPP) in Germany and has systems designed and built by the U.S. Department of Energy’s (DOE) Princeton Plasma Physics Laboratory (PPPL) and Oak Ridge National Laboratory

(ORNL) with support from the Fusion Energy Sciences program in the DOE’s Office of Science.

“This world record marks the highest performing sustained fusion experiment that ran longer than 30 seconds, with record performance lasting for a full 43 seconds,” said Novimir Pablant, the division head for stellarator experiments at PPPL. Pablant said if they can reach this record for 30 seconds, there’s every reason to believe these plasma conditions could be sustained for weeks, months or even years because 30 seconds is long enough for the scientists to see the relevant physics at work. “This experiment ran long enough that nothing is changing any longer in terms of the plasma or experiment conditions.” However, there are technical challenges still to extending this discharge to, say, 30 minutes or more, related to the reliability of technology.

https://www.pppl.gov/news/2025/wendelstein-7-x-sets-new-performance-records-fusion-research

 

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Fusion Energy Breakthrough: 1938 Physics Revived | US Experiment

 

 

June 30, 2025

 

Los Alamos, NM – In a stunning turn of events, a team of U.S. physicists has successfully replicated a long-lost 1938 experiment centered around triton-deuterium fusion. This revival not only validates decades-old findings but also injects fresh momentum into the global race for sustainable, unlimited energy. What implications does this event have for further research?

https://www.archyde.com/fusion-energy-breakthrough-1938-physics-revived-us-experiment/

____________________________________

 

 

A New 5D Model Cracks the Mystery of Mercury’s Bizarre Nuclear Fission

 

June 20, 2025

 

https://www.sciencenewstoday.org/a-new-5d-model-cracks-the-mystery-of-mercurys-bizarre-nuclear-fission 

 

____________________________________

 

Plasma breakthrough: Scientists unlock magnetic secrets for stable nuclear fusion

 

Aug 09, 2025

 

Turbulence that starts at the particle level can directly change the large-scale equilibrium of a plasma system.

 

Researchers from South Korea have provided experimental proof of ‘multi-scale coupling’ in plasma. The study demonstrates how microscopic events can cause large-scale changes in this state of matter.

 

A challenge in plasma physics has been to understand multi-scale coupling, a process where particle-level turbulence scales up to affect the entire plasma system.

 

“Cross-scale coupling from magnetohydrodynamics (MHD) to non-MHD scales is important in interpreting observations of explosive events in nature,” said the researchers in a new study.

 

https://interestingengineering.com/energy/plasmas-secrets-unlocked-for-fusion-reactor

 

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Chapter 15: Batteries & energy storage

____________________________________
____________________________________

 

 

 

 


____________________________________ 




The following chapter will detail some of the new technology that has been introduced in battery technology, including energy storage.

 

____________________________________

 

Wood nanobattery could be green option for large-scale energy storage

July 6, 2013

 



(A closeup of the wood fibers used by the researchers in their sodium-ion battery (Image: University of Maryland)

 Li-ion batteries may be ok for your smartphone, but when it comes to large-scale energy storage, the priorities suddenly shift from compactness and cycling performance (at which Li-ion batteries excel) to low cost and environmental feasibility (in which Li-ion batteries still have much room for improvement). A new "wood battery" could allow the emerging sodium-ion battery technology to fit the bill as a long-lasting, efficient and environmentally friendly battery for large-scale energy storage.

http://www.gizmag.com/wood-battery-energy-storage/28032/


____________________________________




Researchers uncover how magnesium boosts solid-state battery safety and longevity

June 5, 2025

https://www.lifetechnology.com/blogs/life-technology-technology-news/researchers-uncover-how-magnesium-boosts-solid-state-battery-safety-and-longevity

 

____________________________________

 

Trees are source for high-capacity, soft batteries

 

Jun 01, 2015 

 

 

( A closeup of the soft battery, created with wood pulp nanocellulose.)

http://phys.org/news/2015-06-trees-source-high-capacity-soft-batteries.html?utm_source=menu&utm_medium=link&utm_campaign=item-menu

A method for making elastic high-capacity batteries from wood pulp was unveiled by researchers in Sweden and the US. Using nanocellulose broken down from tree fibres, a team from KTH Royal Institute of Technology and Stanford University produced an elastic, foam-like battery material that can withstand shock and stress.

"It is possible to make incredible materials from trees and cellulose," says Max Hamedi, who is a researcher at KTH and Harvard University. One benefit of the new wood-based aerogel material is that it can be used for three-dimensional structures.

"There are limits to how thin a battery can be, but that becomes less relevant in 3D, " Hamedi says. "We are no longer restricted to two dimensions. We can build in three dimensions, enabling us to fit more electronics in a smaller space."



____________________________________

 

Biodegradable computer chips made almost entirely from wood

May 28, 2015

 http://www.gizmag.com/biodegradable-wooden-computer-chips/37755/


____________________________________

 

 

You'll never be-leaf what makes up this battery

 

January 28, 2016

 Scientists at the University of Maryland have a new recipe for batteries: Bake a leaf, and add sodium. They used a carbonized oak leaf, pumped full of sodium, as a demonstration battery's negative terminal, or anode, according to a paper published yesterday in the journal ACS Applied Materials Interfaces.

 

http://phys.org/news/2016-01-youll-be-leaf-battery.html

 

____________________________________

Making batteries with portabella mushrooms

 

 2015

 

Porous structure of portabella mushrooms is key to making efficient batteries that could power cell phones, electric vehicles

 Can portabella mushrooms stop cell phone batteries from degrading over time? Researchers think so. They have created a new type of lithium-ion battery anode using portabella mushrooms, which are inexpensive, environmentally friendly and easy to produce.

 http://www.sciencedaily.com/releases/2015/09/150929142522.htm

 

____________________________________ 

MIT’s photonic crystals lead towards nuclear batteries everywhere

 

February 3, 2012

Researchers at MIT have developed photonic crystals that, in as little as two years, could enable the use of hydrocarbon reactors in portable electronic devices, and nuclear power sources everywhere else.
Photonic crystals are optical nanostructures that are tuned to specific wavelengths of light. If you understand how semiconductors affect the motion of electrons (i.e. the bandgap only allows electrons with a certain energy level to pass through), photonic crystals are the optical equivalent. In this case, MIT has created infrared-absorbing photonic crystals using metals such as tungsten and titanium. Because of their metallic roots, these photonic crystals can operate at temperatures up to 1200C (2192F).


http://www.extremetech.com/extreme/116853-mits-photonic-crystals-lead-towards-a-nuclear-reactor-in-every-gadget

 

____________________________________

 

Tin nanocrystals for the battery of the future

Published: 08.04.13

(Monodisperse tin nanodroplets in an electron microscopic image.)

More powerful batteries could help electric cars achieve a considerably larger range and thus a breakthrough on the market. A new nanomaterial for lithium ion batteries developed in the labs of chemists at ETH Zurich and Empa could come into play here.

 

http://www.ethlife.ethz.ch/archive_articles/130408_li_ionen_fb/index_EN

 

____________________________________

New "Spin Battery" Storing Energy into Nano-Magnets

 

 2009

 

http://www.greenoptimistic.com/2009/03/12/spin-battery-magnetic-energy-storage/#.UmNYqRDNkmw

____________________________________

Graphene Charges Atmosphere with Battery Running on Thin Air

 

December 20, 2014

 http://www.greenoptimistic.com/graphene-charges-atmosphere-battery-running-thin-air-20141220/#.VSFkGeG-2zk


____________________________________

‘Power Paper’ – Story Of A Paper That Can Store Electricity

  

December 12, 2015


 Power Paper, created by the researchers of Sweden’s Linköping University, is showing an outstanding ability in storing energy, which can later be used to recharge devices.

 http://www.greenoptimistic.com/power-paper-store-electricity/


____________________________________

 

From allergens to anodes: Pollen derived battery electrodes

 

February 5, 2016

 

Pollens, the bane of allergy sufferers, could represent a boon for battery makers: Recent research has suggested their potential use as anodes in lithium-ion batteries.

"Our findings have demonstrated that renewable pollens could produce carbon architectures for anode applications in energy storage devices," said Vilas Pol, an associate professor in the School of Chemical Engineering and the School of Materials Engineering at Purdue University.

Batteries have two electrodes, called an anode and a cathode. The anodes in most of today's lithium-ion batteries are made of graphite. Lithium ions are contained in a liquid called an electrolyte, and these ions are stored in the anode during recharging.

The researchers tested bee pollen- and cattail pollen-derived carbons as anodes.

"Both are abundantly available," said Pol, who worked with doctoral student Jialiang Tang. "The bottom line here is we want to learn something from nature that could be useful in creating better batteries with renewable feedstock."

Research findings are detailed in a paper that appeared on Feb. 5 in Nature's Scientific Reports.

Whereas bee pollen is a mixture of different pollen types collected by honey bees, the cattail pollens all have the same shape.

"I started looking into pollens when my mom told me she had developed pollen allergy symptoms about two years ago," Tang said. "I was fascinated by the beauty and diversity of pollen microstructures. But the idea of using them as battery anodes did not really kick in until I started working on battery research and learned more about carbonization of biomass."

The researchers processed the pollen under high temperatures in a chamber containing argon gas using a procedure called pyrolysis, yielding pure carbon in the original shape of the pollen particles. They were further processed, or "activated," by heating at lower temperature - about 300 degrees Celsius - in the presence of oxygen, forming pores in the carbon structures to increase their energy-storage capacity.

http://phys.org/news/2016-02-allergens-anodes-pollen-derived-battery.html?utm_source=menu&utm_medium=link&utm_campaign=item-menu

 

____________________________________

 

New alloy claimed to have higher strength-to-weight ratio than any other metal

 

December 11, 2014

When it comes to metal that's being used in the automotive or aerospace industries, the higher its strength-to-weight ratio, the better. With that in mind, researchers from North Carolina State University and Qatar University have developed a new alloy that reportedly has a low density similar to that of aluminum, but that's stronger than titanium.
The material is a type of high-entropy alloy, meaning that it's made up of at least five metals in more or less equal amounts. In this case, those metals are lithium, magnesium, titanium, aluminum and scandium.

"It has a combination of high strength and low density that is, as far as we can tell, unmatched by any other metallic material," said NCSU's Dr. Carl Koch, senior author of a paper on the research. "The strength-to-weight ratio is comparable to some ceramics, but we think it’s tougher – less brittle – than ceramics."

He additionally informed us that while carbon fiber very likely has a higher strength-to-weight ratio than the alloy, it also wouldn't be as tough – in other words, the alloy would be more likely to bend under an amount of stress that would cause the carbon to fracture.
More work still has to be done in the testing of the alloy, along with establishing a practical production method. Koch and his colleagues are also looking into replacing or eliminating the scandium that makes up 20 percent of the material, as it's very expensive.

 http://www.gizmag.com/high-entropy-alloy-strength-to-weight/35170/

 

____________________________________ 

Graphene-Boron Compound Could Revolutionize Lithium-Ion Battery Capacity

 

 May 28, 2013

http://www.greenoptimistic.com/graphene-boron-compound-could-revolutionize-lithium-ion-battery-capacity-20130528/#.VSFr-eG-2zk

Researchers have touted graphene as a game-changing material that could boost the power and energy capacity of a lithium-ion battery.

Graphene, a film of carbon atoms just one atom thick, is an excellent conductor of electricity. In a battery, the massive surface area of such carbon sheets could be a boon to increasing the power capacity of a lithium-ion battery. The only problem is lithium ions won’t bond with graphene, which makes it practically useless in a battery.
While pure graphene didn’t seem to be a good option, researchers turned to imperfect graphene, that is, carbon mixed with other elements. Testing with boron, researchers at Rice University found the material to be about twice that of the standard graphite currently used in lithium-ion batteries. The new material is also more stable and doesn’t expand and contract as much as graphite alone.




____________________________________ 

CALMAC Stores Surplus Wind Energy in Ice Banks

November 25, 2009


 http://www.greenoptimistic.com/calmac-stores-surplus-wind-energy-in-ice-banks-20091125/#.VSF_W-G-2zk




____________________________________

Utah-Based Company Digging Underground Compressed Air Batteries

 

February 9, 2010


http://www.greenoptimistic.com/utah-underground-energy-storage-20100209/#.VSHcl-G-2zk




____________________________________ 

An All-Liquid Battery For Storing Solar And Wind Energy

  

September 22, 2014

(This room-temperature liquid battery was made with mercury, salt water, and steel foam. High temperature liquid batteries could one day efficiently store solar and wind energy.)

 http://www.popsci.com/article/science/all-liquid-battery-storing-solar-and-wind-energy


____________________________________ 

Liquified Air Could Be Cheaper Energy Storage Than Batteries

May 20, 2013

 The idea is a couple of hundred years old, but liquified air technology was just too inefficient to store energy.

http://www.greenoptimistic.com/liquified-air-could-be-cheaper-energy-storage-than-batteries-20130520/

 

____________________________________

Scientists convert harmful algal blooms into high-performance battery electrodes

 

October 9, 2015

Last August, the seasonal harmful algal blooms (HABs) in Lake Erie grew so extreme that they poisoned the water system in Toledo, Ohio, leaving nearly half a million residents without drinking water. But a few researchers at the time collected some of the toxic HABs, and have now shown that, by heating them at temperatures of 700-1000 °C in argon gas, the HABs can be converted into a material called "hard carbon" that can be used as high-capacity, low-cost electrodes for sodium-ion (Na-ion) batteries.


http://techxplore.com/news/2015-10-scientists-algal-blooms-high-performance-battery.html

____________________________________

Semiliquid battery competitive with both Li-ion batteries and supercapacitors

 

May 22, 2015

 

 http://phys.org/news/2015-05-semiliquid-battery-competitive-li-ion-batteries.html?utm_source=menu&utm_medium=link&utm_campaign=item-menu

 

(Phys.org)—A new semiliquid battery developed by researchers at The University of Texas at Austin has exhibited encouraging early results, encompassing many of the features desired in a state-of-the-art energy-storage device. In particular, the new battery has a working voltage similar to that of a lithium-ion battery, a power density comparable to that of a supercapacitor, and it can maintain its good performance even when being charged and discharged at very high rates.


The researchers, led by Assistant Professor Guihua Yu, along with Yu Ding and Yu Zhao, at UT Austin, have published their paper on the new membrane-free, semiliquid battery in a recent issue of Nano Letters. The researchers explain that the battery is considered "semiliquid" because it uses a liquid ferrocene electrolyte, a liquid cathode, and a solid lithium anode.

 

____________________________________

Flexible and Safe Aluminum-Graphite Battery Charges in One Minute

 

April 8, 2015

 http://www.greenoptimistic.com/aluminum-graphite-battery/#.VSX0dZO-2zk


____________________________________

"Origami battery" made from paper and dirty water for just a few cents

June 13, 2015

 A foldable, inexpensive paper battery that can generate a small amount of electricity brings a new sense of power to origami, the Japanese art of paper folding. An engineer at Binghamton University in New York has developed a battery that creates power through the process of microbial respiration in a drop of dirty water on paper.


 http://www.gizmag.com/origami-battery-bacteria/37970/

 
 
____________________________________




Nano-mechanical study offers new assessment of silicon for next-gen batteries

September 24, 2015

A detailed nano-mechanical study of mechanical degradation processes in silicon structures containing varying levels of lithium ions offers good news for researchers attempting to develop reliable next-generation rechargeable batteries using silicon-based electrodes.

http://phys.org/news/2015-09-nano-mechanical-silicon-next-gen-batteries.html#jCp



____________________________________

 

Clay sheets stack to form proton conductors

 

July 13, 2015 

 

 

 

(This is a scanning electron microscopy image of stacked clay sheets. When two-dimensional sheets of the clay, called vermiculite, are exfoliated in water, they carry negative charges, attracting positively charged protons. After the sheets dry, they self-assemble into paper-like films. The near 1-nanometer spacing between the layers serves as the nanochannels that can concentrate protons for conduction. Credit: Jiaxing Huang )

 
http://phys.org/news/2015-07-clay-sheets-stack-proton-conductors.html?utm_source=menu&utm_medium=link&utm_campaign=item-menu

 
____________________________________

 

 

Stronger together: Interlocked electrodes push silicon battery lifespan beyond limits

28-May-2025

In practical terms, this means electric vehicles can travel farther and smartphones can operate longer using the same-sized battery

https://www.chemeurope.com/en/news/1186362/stronger-together-interlocked-electrodes-push-silicon-battery-lifespan-beyond-limits.html

 

____________________________________

 

New Dry Electrode Tech Doubles Battery Performance For Renewable Energy Storage

 

June 23, 2025

https://impactful.ninja/new-dry-electrode-tech-doubles-battery-performance-for-renewable-energy-storage/

 

____________________________________

 

 

Williams demonstrates sodium-ion-powered proof-of-concept e-bike

May 15, 2015

http://www.gizmag.com/williams-demonstrates-sodium-ion-powered-proof-of-concept-e-bike/37537/

 

____________________________________

 

Silicon anode structure generates new potential for lithium-ion batteries

 

 5-Feb-2021 

 

Scientists reveal a new nanostructure that could revolutionize technology in batteries and beyond.

https://scitechdaily.com/silicon-anode-nanostructure-generates-new-potential-for-lithium-ion-batteries/

____________________________________ 

 

 

Enhancing Sodium-Ion Batteries with New Electrolyte Formulation

 

Mar 17, 2025 

 

https://sodiumbatteryhub.com/2025/03/17/enhancing-sodium-ion-batteries-with-new-electrolyte-formulation/

 

____________________________________

 

Dry-Powder Breakthrough Boosts Stability and Sustainability of Sodium-Ion Batteries

 

August 5, 2025

 

https://aps.unc.edu/home-page-news-item/dry-powder-breakthrough-boosts-stability-and-sustainability-of-sodium-ion-batteries/

 

____________________________________

 

 Chemists discover key reaction mechanism behind the highly touted sodium-oxygen battery

May 27, 2015

http://phys.org/news/2015-05-chemists-key-reaction-mechanism-highly.html#jCp

 

____________________________________

Candle soot could reduce lithium ion battery production costs

 

October 15, 2015

 A new study suggests that the carbon-based waste material given off by burning candles could be suitable for use in larger, more powerful lithium ion batteries such as those used in electric cars. Two researchers from the Indian Institute of Technology found that as an anode material, candle soot compares favorably to existing commercial options because of its low cost of production and fractal-like nanoparticle structure.

 http://www.gizmag.com/candle-soot-lithium-ion-battery/39881/?li_source=LI&li_medium=default-widget

 

____________________________________

High-voltage lithium-ion battery realized with superconcentrated electrolyte

 

July 26, 2016


https://techxplore.com/news/2016-07-high-voltage-lithium-ion-battery-superconcentrated-electrolyte.html
 

 

____________________________________

New lithium-oxygen battery greatly improves energy efficiency, longevity

 

July 25, 2016

 

 http://phys.org/news/2016-07-lithium-oxygen-battery-greatly-energy-efficiency.html

 

____________________________________ 

 

Advances in lithium-ion battery recycling: Strategies, pathways, and technologies

2025

https://www.sciencedirect.com/science/article/pii/S2772571524000317

 

 ____________________________________

 

New Cathode Design Significantly Improves Performance of Next-Generation Battery

December 26, 2020

 

https://scitechdaily.com/new-cathode-design-significantly-improves-performance-of-next-generation-battery/ 


____________________________________

 

Chinese ‘switch’ extends lithium battery life by 20,000 cycles with new design

 

Aug 01, 2024 

 

Innovation unlocks commercialization potential of solid-state lithium batteries to overcome energy storage hurdles. 

 

Researchers at the Qingdao Institute of Bioenergy and Bioprocess Technology (QIBEBT) in China have innovated a modification to the cathode for all-solid-state lithium batteries (ASLB), significantly improving their energy density and life cycle. 

 

According to an organizational press release, the research paves the way for the next generation of high-performance batteries. 

 

In our attempts to move away from fossil fuels and electrify modes of transport, batteries are an important component. Although batteries have been around for centuries, it is only with lithium-ion batteries that we have managed the highest energy densities so far. 

 

https://interestingengineering.com/energy/solid-state-lithium-batteries-cathode-china

 

____________________________________

 

Improving Lithium-Ion Battery Performance, Cell Lifetime for Renewable Energy Applications

 

November 28, 2020

https://scitechdaily.com/improving-lithium-ion-battery-performance-cell-lifetime-for-renewable-energy-applications/

____________________________________ 

 

 

Improved Advanced Energy Storage Using New Nano-Engineering Strategy

July 20, 2020

 

New types of cathodes, suitable for advanced energy storage, can be developed using beyond-lithium ion batteries.

 

The rapid development of renewable energy resources has triggered tremendous demands in large-scale, cost-efficient, and high-energy-density stationary energy storage systems.

 

Lithium-ion batteries (LIBs) have many advantages but there are much more abundant metallic elements available such as sodium, potassium, zinc, and aluminum.

 

These elements have similar chemistries to lithium and have recently been extensively investigated, including sodium-ion batteries (SIBs), potassium-ion batteries (PIBs), zinc-ion batteries (ZIBs), and aluminum-ion batteries (AIBs). Despite promising aspects relating to redox potential and energy density, the development of these beyond-LIBs has been impeded by the lack of suitable electrode materials.

 

New research led by Professor Guoxiu Wang from the University of Technology Sydney, and published in Nature Communications, describes a strategy using interface strain engineering in a 2D graphene nanomaterial to produce a new type of cathode. Strain engineering is the process of tuning a material’s properties by altering its mechanical or structural attributes.

 

https://scitechdaily.com/improved-advanced-energy-storage-using-new-nano-engineering-strategy/

 

____________________________________

 

New Technique Reveals 3D Nanoscale Chemical Reactions Inside Batteries

  

December 11, 2021

 

Researchers in the College of Illinois at Chicago and Lawrence Berkeley National Laboratory allow us a brand new technique that allows them to target the location of chemical reactions happening inside lithium-ion batteries in 3d in the nanoscale level. Their answers are printed within the journal Nature Communications... 

 
https://science-atlas.com/chemistry/new-technique-reveals-3d-nanoscale-chemical-reactions-inside-batteries/

____________________________________ 

 

 

 

From beam to battery: Single-step laser printing supercharges high-performance lithium-sulfur batteries

April 23, 2025

A research team has developed an innovative single-step laser printing technique to accelerate the manufacturing of lithium-sulfur batteries. Integrating the commonly time-consuming active materials synthesis and cathode preparation in a nanosecond-scale laser-induced conversion process, this technique is set to revolutionize the future industrial production of printable electrochemical energy storage devices. 

Lithium-sulfur batteries are expected to supersede existing lithium-ion batteries due to sulfur cathodes' high theoretical energy density. To ensure the rapid conversion of sulfur species, these cathodes are typically composed of active materials, host materials (or catalysts), and conductive materials. However, the fabrication of host materials and preparation of sulfur cathodes often involve complicated, multistep, and labor-intensive processes that require varying temperatures and conditions, raising concerns about efficiency and cost in industrial production.

To overcome these challenges, Prof. Li's team developed a novel single-step laser printing technique for the rapid manufacturing of integrated sulfur cathodes. During this high-throughput laser-pulse irradiation process, the precursor donor is activated, producing jetting particles that include in-situ synthesized halloysite-based hybrid nanotubes (host material), sulfur species (active material), and glucose-derived porous carbon (conductive component). The mixture is printed onto a carbon fabric acceptor, forming an integrated sulfur cathode. Notably, the laser-printed sulfur cathodes demonstrate outstanding performance in both coin and pouch lithium-sulfur cells.

"Traditional manufacturing processes of a cathode/anode in ion battery usually contain the synthesis of active materials (sometimes combined with host material/ catalyst), the preparation of mixture slurry, and the assembly of cathode/anode. Prof. Li explained, "These steps are usually carried out separately under different temperatures and conditions because the materials behave differently. As a result, the whole process can take tens of hours or even several days."

Prof. Li said, "Our newly developed laser-induced conversion technology offers a way to combine these processes into a single step at nanosecond speeds. The printing speed can achieve about 2 cm2/minute using only a single beam laser. A 75 × 45 mm2 sulfur cathode can be printed within 20 minutes and supply power for a small screen for several hours when assembled into a lithium-sulfur pouch cell."

https://www.sciencedaily.com/releases/2025/04/250423112140.htm

____________________________________ 

 

 

Sulfur-based polymers open door to a new class of battery

 

April 19, 2013

 http://www.gizmag.com/sulfur-polymer-batteries/27117/?li_source=LI&li_medium=default-widget

 Whether sulfur is a by-product or a waste product of oil refinement and coal combustion depends on how you slice it. Certainly, much of that sulfur can be put to use producing sulfuric acid, fertilizer and other chemicals, but some is left to accumulate on stockpiles which are expensive to maintain (due to the need to neutralize acidic run-off). Researchers at the University of Arizona think more of that sulfur could one day be put to use thanks to a new chemical process that uses sulfur to make polymers. The new material could lead to a new generation of lighter, more efficient lithium-sulfur batteries, the researchers claim.

 

____________________________________

 

 

CaO makes the graphene hierarchy for high-power lithium-sulfur batteries

 

January 26, 2016

 Structural hierarchy is the cornerstone of the biological world, as well as the most important lesson that we have learned from nature to develop ingenious hierarchical porous materials for various applications in energy conversion and storage. Recently, a research group from China, led by Prof. Qiang Zhang in Tsinghua University, has developed a novel kind of hierarchical porous graphene (HPG) via a versatile chemical vapor deposition (CVD) on CaO templates for high-power lithium-sulfur (Li-S) batteries. This work is published in the journal Advanced Functional Materials.

 

http://phys.org/news/2016-01-cao-graphene-hierarchy-high-power-lithium-sulfur.html

 
____________________________________

 

 

New LithiumSulfur Battery Promises 5 Times More Capacity

October 23, 2023

https://www.electronicsforu.com/news/new-lithiumsulfur-battery-promises-5-times-more-capacity

____________________________________ 

 

 

Rapid lithium extraction eliminates use of acid and high heat, scientists report 

 30-Apr-2025 

https://www.eurekalert.org/news-releases/1082372

____________________________________

 

Metal fatigue in anodes identified as key cause of solid-state lithium battery degradation

May 2, 2025

https://batteriesnews.com/metal-fatigue-in-anodes-identified-as-key-cause-of-solid-state-lithium-battery-degradation/

 

____________________________________

 

Carbon Nanotubes Store Triple the Energy of Lithium Batteries

December 20, 2024

 

 

 

Carbon Nanotubes Store Triple the Energy of Lithium Batteries

 

https://batteriesnews.com/carbon-nanotubes-store-triple-the-energy-of-lithium-batteries/

____________________________________

 

New fuel cell could enable electric aviation

  

May 27, 2025

 

 Engineers developed a fuel cell that offers more than three times as much energy per pound compared to lithium-ion batteries. Powered by a reaction between sodium metal and air, the device could be lightweight enough to enable the electrification of airplanes, trucks, or ships.

https://www.sciencedaily.com/releases/2025/05/250527124115.htm

____________________________________ 

 

How can we optimize solid-state batteries? Try asking AI

May 4 2025

https://lifeboat.com/blog/2025/05/how-can-we-optimize-solid-state-batteries-try-asking-ai

____________________________________


Operando setup enables visualization of battery aging processes during charging cycles

April 29, 2025

https://techxplore.com/news/2025-04-operando-setup-enables-visualization-battery.html

____________________________________

 

Redox flow battery achieves energy efficiency of 87.9% and longer cycling life with new catalytic electrode

April 2, 2025

A team of materials scientists, chemical engineers, and environmental scientists affiliated with a host of institutions in China has developed a redox flow battery (RFB) with 87.9% energy efficiency, which can also last for 850 cycles. In their project, published in the journal Nature Communications, the group developed a new kind of catalytic electrode to improve the efficiency of the battery.

https://techxplore.com/news/2025-04-redox-battery-energy-efficiency-longer.html

____________________________________

 

Charging electric vehicles 5x faster in subfreezing temps

April 4, 2025

https://news.engin.umich.edu/2025/04/charging-electric-vehicles-5x-faster-in-subfreezing-temps/

____________________________________

 

Electric vehicles could travel farther on a single charge thanks to new discovery 

March 4, 2025

https://news.fiu.edu/2025/electric-vehicles-could-travel-farther-on-a-single-charge-thanks-to-new-discovery 

 

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Two new families of PFAS-free solvents for next-generation batteries

March 28, 2025

https://batteriesnews.com/two-new-families-of-pfas-free-solvents-for-next-generation-batteries/

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Taking the 'forever' out of 'forever chemicals': Scientists work out how to destroy the PFAS in batteries

February 7, 2025

Lithium-ion batteries are part of everyday life. They power small rechargeable devices such as mobile phones and laptops. They enable electric vehicles. And larger versions store excess renewable energy for later use, supporting the clean energy transition.

Australia produces more than 3,000 metric tons of lithium-ion battery waste a year. Managing this waste is a technical, economic and social challenge. Opportunities exist for recycling and creating a circular economy for batteries. But they come with risk.

That's because lithium-ion batteries contain manufactured chemicals such as PFAS, or per- and polyfluoroalkyl substances. The chemicals carry the lithium—along with electricity—through the battery. If released into the environment, they can linger for decades and likely longer. This is why they've been dubbed "forever chemicals".

Recently, scientists identified a new type of PFAS known as bis-FASIs (short for bis-perfluoroalkyl sulfonimides) in lithium-ion batteries and in the environment. Bis-FASIs have since been detected in soils and waters worldwide. They are toxic—just one drop in an Olympic-size swimming pool can harm the nervous system of animals. Scientists don't know much about possible effects on humans yet.

Bis-FASIs in lithium-ion batteries present a major obstacle to recycling or disposing of batteries safely. Fortunately, we may have come up with a way to fix this.

https://techxplore.com/news/2025-02-chemicals-scientists-destroy-pfas-batteries.html

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 New battery made of molten metals may offer low-cost, long-lasting storage for the grid

January 13, 2016

 As their first combination, Sadoway and Bradwell chose magnesium for the top electrode, antimony for the bottom electrode, and a salt mixture containing magnesium chloride for the electrolyte. They then built prototypes of their cell—and they worked. The three liquid components self-segregated, and the battery performed as they had predicted. Spurred by their success, in 2010 they, along with Luis Ortiz SB '96, PhD '00, also a former member of Sadoway's research group, founded a company—called initially the Liquid Metal Battery Corporation and later Ambri—to continue developing and scaling up the novel technology.

http://phys.org/news/2016-01-battery-molten-metals-low-cost-long-lasting.html

 

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AI Just Found the Future of Batteries, And It’s Not Lithium

 

August 5, 2025

 

These discoveries could enable cheaper, safer, and more powerful energy storage by using elements like magnesium and zinc. 

 

 https://scitechdaily.com/ai-just-found-the-future-of-batteries-and-its-not-lithium/

 

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An anode-free zinc battery that could someday store renewable energy

 

January 21, 2021

https://sciencebulletin.org/an-anode-free-zinc-battery-that-could-someday-store-renewable-energy/


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A reversible Zn-metal battery

  

10 May 2021

Thanks to a stable fluorinated interphase formed on top of a Zn metal anode, a Zn metal battery shows 99.9% Coulombic efficiency and record-high Zn utilization.

https://www.nature.com/articles/s41565-021-00908-1

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Fluorinated interphase enables reversible aqueous zinc battery chemistries

 

10 May 2021

 

Abstract

 

Metallic zinc is an ideal anode due to its high theoretical capacity (820 mAh g⁻¹), low redox potential (−0.762 V versus the standard hydrogen electrode), high abundance and low toxicity. When used in aqueous electrolyte, it also brings intrinsic safety, but suffers from severe irreversibility. This is best exemplified by low coulombic efficiency, dendrite growth and water consumption. This is thought to be due to severe hydrogen evolution during zinc plating and stripping, hitherto making the in-situ formation of a solid–electrolyte interphase (SEI) impossible. Here, we report an aqueous zinc battery in which a dilute and acidic aqueous electrolyte with an alkylammonium salt additive assists the formation of a robust, Zn²⁺-conducting and waterproof SEI. The presence of this SEI enables excellent performance: dendrite-free zinc plating/stripping at 99.9% coulombic efficiency in a Ti||Zn asymmetric cell for 1,000 cycles; steady charge–discharge in a Zn||Zn symmetric cell for 6,000 cycles (6,000 h); and high energy densities (136 Wh kg⁻¹ in a Zn||VOPO₄ full battery with 88.7% retention for >6,000 cycles, 325 Wh kg⁻¹ in a Zn||O₂ full battery for >300 cycles and 218 Wh kg⁻¹ in a Zn||MnO₂ full battery with 88.5% retention for 1,000 cycles) using limited zinc. The SEI-forming electrolyte also allows the reversible operation of an anode-free pouch cell of Ti||Zn_xVOPO₄ at 100% depth of discharge for 100 cycles, thus establishing aqueous zinc batteries as viable cell systems for practical applications.

 
https://www.nature.com/articles/s41565-021-00905-4

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High-Energy Batteries Coming to Market

 Oct, 2009

Rechargeable zinc-air batteries can store three times the energy of a lithium-ion battery.

http://www.technologyreview.com/news/416020/high-energy-batteries-coming-to-market/

 
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Zinc–air battery

http://en.wikipedia.org/wiki/Zinc%E2%80%93air_battery


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New Battery Boasts 7 Times More Energy Density

 July 30th, 2014

http://cleantechnica.com/2014/07/30/new-battery-boasts-7-times-energy-density/

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Ein-Eli's New Battery Could Power a Laptop for Hundreds of Hours

 December 1, 2009

 An Israeli research team conducted by Prof. Yair Ein-Eli at the Technion – Israel Institute of Science, has recently developed a new battery that is able to produce thousands of hours of charge from an abundant and non-polluting fuel source.


This new portable battery could replace the batteries used in hearing aids, due to its reduced dimensions (measuring about less than a third of an inch). According to the researchers, in the near future it can replace laptop batteries as we known them, allowing them to run for hundreds of hours on a single charge. The small devices could benefit of this technology within a couple of years. “This would take about 10 years more and be revolutionary,” said Ein-Eli.

The current prototypes of the battery have a silicon power source that reverts back to their original form as sand. “In the paper, we showed that at 600 hours it had used only 10 percent of the energy. So we are talking about 6,000 hours,” says the professor.

http://www.greenoptimistic.com/ein-elis-new-battery-could-power-a-laptop-for-hundreds-of-hours-20091201/#.VSF4ceG-2zk


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Commercially-available NanoTritium battery can power microelectronics for 20+ years

August 15, 2012

When installing micro-electronic devices in locations that are expensive or hard to reach, or just downright dangerous, you don't want to have to keep returning to swap out a battery cell. City Labs has announced the commercial launch of its NanoTritium betavoltaic power source, a thumb-sized battery that draws on the energy released from its radioactive element to provide continuous nanoWatt power for over 20 years.

http://www.gizmag.com/city-labs-nanotritium-betavoltaic-battery/23720/?li_source=LI&li_medium=default-widget

 

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Quantum Materials Cut Closer Than Ever Before for Faster, More Energy-Efficient Electronics

April 25, 2021

 

“Quantum materials cut closer than ever”. Posts about “Quantum materials cut closer than ever” written by richardmitnick.

 

DTU and Graphene Flagship (EU) researchers have taken the art of patterning nanomaterials to the next level. Precise patterning of 2D materials is a route to computation and storage using 2D materials, which can deliver better performance and much lower power consumption than today’s technology.

 

The electron beam lithography system in DTU Nanolab can write details down to 10 nanometers. Computer calculations can predict exactly the shape and size of patterns in the graphene to create new types of electronics. They can exploit the charge of the electron and quantum properties such as spin or valley degrees of freedom, leading to high-speed calculations with far less power consumption. These calculations, however, ask for higher resolution than even the best lithography systems can deliver: atomic resolution. 

 
https://science-atlas.com/technology/quantum-materials-cut-closer-than-ever-before-for-faster-more-energy/

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Researchers Infuse Bacteria with Silver to Improve Power Efficiency in Fuel Cells

Sep 16, 2021

 

 A  UCLA-led team of engineers and chemists has taken a major step forward in the development of microbial fuel cells — a technology that utilizes natural bacteria to extract electrons from organic matter in wastewater to generate electrical currents. A study detailing the breakthrough was recently published in Science. 

 

“Living energy-recovery systems utilizing bacteria found in wastewater offer a one-two punch for environmental sustainability efforts,” said co-corresponding author Yu Huang, a professor and chair of the Materials Science and Engineering Department at the UCLA Samueli School of Engineering. “The natural populations of bacteria can help decontaminate groundwater by breaking down harmful chemical compounds. Now, our research also shows a practical way to harness renewable energy from this process.”

 

The team focused on the bacteria genus Shewanella, which have been widely studied for their energy-generation capabilities. They can grow and thrive in all types of environments — including soil, wastewater and seawater — regardless of oxygen levels. 

 

Shewanella species naturally break down organic waste matter into smaller molecules, with electrons being a byproduct of the metabolic process. When the bacteria grow as films on electrodes, some of the electrons can be captured, forming a microbial fuel cell that produces electricity.

https://samueli.ucla.edu/researchers-infuse-bacteria-with-silver-to-improve-power-efficiency-in-fuel-cells/

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Unplanned Discovery: An Excellent Material for Batteries along with other Energy Conversion Devices

 

January 31, 2022

 

Unplanned Discovery: A Super Material for Batteries and Other Energy Conversion Devices. Unplanned discoveries may lead to fundamental discoveries in batteries, fuel cells, and equipment that converts heat into electricity in the future.

 

“Our analysis showed that before this transformation, silver ions were fixed in a confined space within the two-dimensional space of our material,” Kanatzidis said. “But after this transition, they moved. ” Although people know a lot about how ions move in three-dimensional space, little is known about how they move in two-dimensional space.

 

When Mercouri Kanatzidis, a professor at Northwestern University in a joint position at the U.S. Department of Energy (DOE) Argonne National Laboratory, was looking for a new superconductor with unconventional behavior, he made an unexpected discovery. It is a material that is only four atoms thick and only allows the movement of charged particles to be studied in two dimensions. These studies can promote the invention of new materials for various energy conversion devices.

 

https://science-atlas.com/technology/unplanned-discovery-an-excellent-material-for-batteries-along-with/

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Researchers Discover a New Family of 2D Semiconductors for Energy-Efficient Electronic Devices

 

Oct 17, 2021 

 

Due to the increasing demand for high computational power in compact smart devices, circuits are shrinking while becoming more powerful. Therefore, the need for high device densities arises.

 

However, making circuit elements smaller is a challenge with various trade-offs. As the trend of miniaturization continues, engineers are trying to overcome the limitations of silicon-based technology.

 

As devices such as transistors are miniaturized or scaled-down beyond a certain size, quantum tunneling effects become prominent, which leads to highly uncontrollable device behaviors. As the transistors become too small, some electrons can tunnel past the barriers even if they don't have enough energy to cross. Due to these effects, ultrasmall computer chips do not behave in a controllable way.

 

To continue scaling further, sophisticated device technologies, such as FinFET and Gallium Arsenide FETs, can be employed. In addition, 2D semiconductors are considered as a potential candidate for future computing electronics. These materials, being atomically thin semiconductor layers, can efficiently handle electrical switching operations.

 

However, for implementing 2D transistors, a 2D semiconductor needs to electrically connect by two pieces of metals that form source and drain. The contacts between metals and semiconductors form an interfacial potential barrier, known as the Schottky barrier, which can severely affect the charge injection efficiency. As a result, a stronger voltage is needed to force the flow of electricity through the Schottky barrier, wasting energy and generating heat. 

 

A research team from the Singapore University of Technology and Design (SUTD) is working on ohmic contacts with no Schottky barrier. They discovered a new family of 2D semiconductors, namely MoSi2N4 and WSi2N4 that form ohmic contacts with metals titanium, scandium, and nickels. Their work is described in the npj 2D Materials and Applications journal.

https://eepower.com/news/researchers-discover-a-new-family-of-2d-semiconductors-for-energy-efficient-electronic-devices/#

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New X-Ray microscopy technique reveals nanoscale secrets of rechargeable batteries

 

August 4, 2016

http://phys.org/news/2016-08-team-reveals-nanoscale-secrets-rechargeable.html

 
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Researchers Watch Solid-State Batteries Charge and Discharge Using X-ray Tomography

 

January 28, 2021

 

Real-time 3D imaging shows voids at solid-state battery interfaces cause failure, offering clues for improving their lifespan and performance.

 

Using X-ray tomography, a research team has observed the internal evolution of the materials inside solid-state lithium batteries as they were charged and discharged. Detailed three-dimensional information from the research could help improve the reliability and performance of the batteries, which use solid materials to replace the flammable liquid electrolytes in existing lithium-ion batteries.

 

https://scitechdaily.com/researchers-watch-solid-state-batteries-charge-and-discharge-using-x-ray-tomography/ 

 

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Scientists analyze a single atom with X-rays for the first time

 

June 7, 2023

 

New X-ray capability could find wide application in environmental and medical research, as well as the development of batteries and microelectronic devices

https://www.anl.gov/article/scientists-analyze-a-single-atom-with-xrays-for-the-first-time

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New design points a path to the 'ultimate' battery

 

October 29, 2015 

 

 Scientists have developed a working laboratory demonstrator of a lithium-oxygen battery which has very high energy density, is more than 90% efficient, and, to date, can be recharged more than 2000 times, showing how several of the problems holding back the development of these devices could be solved.

http://phys.org/news/2015-10-path-ultimate-battery.html

 

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Silicon Nanowire Battery Has Three Times More Capacity, Charges Faster

 http://www.greenoptimistic.com/silicon-nanowire-battery-capacity-20130216/#.VSFr9OG-2zk


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Newly Discovered TiO2-Coated Nanotubes Could Build Better Li-Ion Battery Electrodes

 

February 2, 2010

http://www.greenoptimistic.com/titanium-dioxide-coated-nanotube-electrode-20100202/#.VSFcYuG-2zk

 

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Breakthrough nano-spring technology boosts battery durability and energy density

 

March 15, 2025

Scientists improved battery durability and energy density with a nano-spring coating.

https://www.sciencedaily.com/releases/2025/03/250313130813.htm

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Lithium-ion batteries inspired by snail shells could prove longer-lasting

February 11, 2015


In an ongoing effort to improve the performance of lithium-ion batteries, scientists have looked to the techniques that snails use to control the growth of their shells. This biological inspiration, combined with a peptide found to bind very effectively with materials used to make cathodes, has potential for making lighter and longer-lasting batteries.


http://www.gizmag.com/lithium-ion-batteries-snail-shells/36045/



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Batteries Mimic Multilayer Geometry of Mammal Bones for Structural Stability

 

December 9, 2020

 

 

 

Mimicking mammal bone structure improves sodium-ion battery cathodes’ stability and performance.

 

By copying the multilayer geometry of mammal bones, cathodes for sodium-ion batteries can be made more structurally stable, while maintaining high capacities and fast charge rates.

 

Sodium-ion batteries are poised to replace lithium-ion batteries for large-scale electrical energy storage. They offer several advantages over lithium-ion batteries, particularly due to the widespread abundance of sodium.

 

However, it is difficult to develop sodium cathodes, materials through which electrons can enter a battery. Many candidate materials are unstable or cannot withstand high voltages.

 

To find a solution, researchers from Sungkyunkwan University, the University of Texas at Austin, and Brookhaven National Laboratory turned to nature. They describe their mammal bone-inspired sodium cathode in the journal Applied Physics Reviews, from AIP Publishing.

 

“We believe that nature provides a very promising solution to resolve technical problems,” said Ho Seok Park, one of the authors. “Accordingly, we tried to find the ideal architecture that can resolve these kinetic and stability limitations.”

 

Mammal bone structures consist of an inner porous, spongy bone that allows the storage and transport of bone marrow, surrounded by a hard, compact bone, which offers mechanical and structural integrity under severe stress.

 

https://scitechdaily.com/batteries-mimic-multilayer-geometry-of-mammal-bones-for-structural-stability/ 

 

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An Affordable, Sustainable New Battery Technology

 

June 26, 2025

 

Traditional Li-ion batteries rely on graphite as an anode material. However, the same graphite structure fails when it comes to sodium or potassium. But, by rethinking the shape of the carbon at the microscopic level, researchers found a workaround.

 

https://www.techbriefs.com/component/content/article/53372-an-affordable-sustainable-new-battery-technology

 

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This battery self-destructs: Biodegradable power inspired by 'Mission: Impossible'

 

 June 7, 2025

 

New paper shows the potential of using probiotics -- live microorganisms that offer health benefits when ingested but are otherwise harmless

 

 Scientists at Binghamton University are bringing a sci-fi fantasy to life by developing tiny batteries that vanish after use inspired by Mission: Impossible. Led by Professor Seokheun Choi, the team is tackling one of the trickiest parts of biodegradable electronics: the power source. Instead of using toxic materials, they re exploring probiotics friendly bacteria often found in yogurt to generate electricity. With engineered paper-based batteries that dissolve in acidic environments, this breakthrough could revolutionize safe, disposable tech for medical and environmental use.

https://www.sciencedaily.com/releases/2025/06/250607231828.htm

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The Quantum Battery That Flipped Entanglement: A Stunning Reversal of the Rules

  

July 9, 2025

 

Scientists have discovered a way to make quantum entanglement reversible, something long thought to be impossible, by using a conceptual device called an entanglement battery.

 

Much like a regular battery stores energy, this theoretical tool can store and release entanglement, allowing quantum states to be transformed and reversed without loss. This breakthrough reveals a new “second law” for quantum mechanics, echoing the principles of thermodynamics and opening the door to more efficient quantum technologies and a unified framework for manipulating quantum resources.

 

https://scitechdaily.com/the-quantum-battery-that-flipped-entanglement-a-stunning-reversal-of-the-rules/

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Newly Discovered Property of Graphene to Boost Fuel Cells Efficiency

  

November 28, 2014


 The founder of graphene discovered one more incredible property of the material that can give the ever-so-needed to boost fuel cells and hydrogen-based technologies. The strongest, thinnest, and initially known as impermeable material, in fact allows hydrogen protons to pass through.

No wonder graphene is labelled as the “miracle material”. Every property or use of it that is discovered, opens up a great deal of new and super exciting opportunities and applications. Of course, there is no one, who better understands graphene than its discoverer- the Nobel prize winner Andre Geim of University of Manchester, and therefore it is no surprise that exactly his team has found yet another super exciting property of the thin super-strong material.

In the study published this week in the journal Nature, the team describes how at high temperatures, above 250 degrees Celsius, graphene allows hydrogen protons to pass through. In addition, this process of proton transport can be enhanced by adding an extra layer of catalytic metal nanoparticles, such as platinum. This great discovery has a potential in improving the performance of fuel cells. Here, it could act as a proton-conducting membrane, which could potentially eliminate the pressing problem of fuel leaks, associated with reduction of cell efficiency. This property also opens up new horizons for development of exciting hydrogen-based technologies.

 http://www.greenoptimistic.com/newly-discovered-property-graphene-boost-fuel-cells-efficiency-20141128/#.VSFr4OG-2zk




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New electrolyte promises to rid lithium batteries of short-circuiting dendrites

  

March 2, 2015

(Scanning electron microscope images that show how normal electrolyte promotes dendrite growth (a, left), while PNNL’s new electrolyte produces smooth nodules that don’t short-circuit cells (b, right).

 Dendrites – thin conductive filaments that form inside lithium batteries – reduce the life of these cells and are often responsible for them catching fire. Scientists working at the Pacific Northwest National Laboratory (PNNL) of the US Department of Energy claim to have produced a new electrolyte for lithium batteries that not only completely eliminates dendrites, but also promises to increase battery efficiency and vastly improve current carrying capacity.

 http://www.gizmag.com/dendrite-electrolyte-lithium-batteries/36274/

 

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Scientists cook up a green recipe for recycling lithium-ion batteries using vegetable oil

24 February 2025

https://techxplore.com/news/2025-02-scientists-cook-green-recipe-recycling.html


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 Erupting electrodes: How recharging leaves behind microscopic debris inside batteries (w/ Video)

Apr 10, 2015

 http://phys.org/news/2015-04-erupting-electrodes-recharging-microscopic-debris.html#jCp

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Using batteries to produce hydrogen peroxide from air for industrial applications

12-Mar-2025

Hydrogen peroxide (H2O2) is widely used as a bleach, disinfectant, and oxidising agent, among other things. However, industrial production of H2O2 is expensive and uses a lot of energy owing to the rare and precious metal catalysts used in its production. Researchers at the Indian Institute of Science (IISc) have developed an alternative, onsite production strategy for H2O2 that can also degrade industrial pollutants like toxic dyes.

https://www.chemeurope.com/en/news/1185767/using-batteries-to-produce-hydrogen-peroxide-from-air-for-industrial-applications.html 

 

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Lithium extraction: the end of polluting methods?

February 05, 2025

Lithium, essential for electric vehicle batteries, is currently extracted using costly and polluting methods. A team of researchers proposes an electrochemical alternative, cleaner and more efficient, which could reduce costs by 35% and CO₂ emissions by 75%.

https://www.techno-science.net/en/news/lithium-extraction-the-end-of-polluting-methods-N26456.html


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Iron-Air Batteries Promise Higher Energy Density Than Lithium-Ion Batteries

 

November 16, 2017

 

https://scitechdaily.com/iron-air-batteries-promise-higher-energy-density-than-lithium-ion-batteries/

 

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Will Iron Forge the Future of Metal-Air Batteries in Grid Scale Energy Storage?

 

17 March 2025

 

Graphical Abstract

 

This Perspective paper highlights different aspects of iron-air batteries, as an appealing sustainable alternative energy storage technology for grid-scale applications. The utilization of iron as an anode is attractive, since it is abundant and safe to handle, recyclable and affordable, has multielectron reversible redox activity, holds historically rich experience in terms of production and processing. 

 

https://chemistry-europe.onlinelibrary.wiley.com/doi/10.1002/cssc.202402412 

 

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Researchers develop safer electrolytes and use novel technique to assess them

 

Apr 03, 2015 

Most of us have seen dramatic photographs of laptops and even cars that have burst into flames due to failures in lithium-ion batteries. On a much larger scale, battery fires grounded Boeing's 787 Dreamliner jets for several months in 2013 while the company implemented new features to reduce the risk of overheating and combustion.

 

http://phys.org/news/2015-04-safer-electrolytes-technique.html#nRlv

 

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Newly Invented Energy-Storing Organic Membrane Better and Cheaper Than Batteries and Capacitors

 

October 27, 2011


An organic membrane may be the world’s next best battery and may revolutionize energy storage as we know it – it can bear far more energy than capacitors can, and can charge quicker than ever. Not to mention that it’s also dead-cheap.


http://www.greenoptimistic.com/xie-energy-storing-organic-membrane-20111027/

 

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Advanced stability and energy storage capacity in hierarchically engineered Bi_0.5Na_0.5TiO₃-based multilayer capacitors

  

16 July 2025

 

Abstract

 

Multilayer ceramic capacitors are cornerstone components of modern electronic systems. Yet ensuring reliability under demanding operational conditions, such as elevated temperatures and prolonged cycling, while achieving holistic optimization of recoverable energy density and efficiency remains a significant challenge. Herein, we implement a polar glass state strategy that catalyzes a profound enhancement in energy storage performance by modulating dynamic and thermodynamic processes. This approach minimizes hysteresis loss and improves breakdown strength through hierarchical structural engineering, disrupting nano-domains and refining grains. An ultra-high recoverable energy density of 22.92 J cm⁻³ and exceptional efficiency of 97.1%, accompanied with state-of-the-art high-temperature stability are achieved in Bi_0.5Na_0.5TiO₃-based multilayer ceramic capacitors. This strategy promises to be a transformative blueprint for developing cutting-edge dielectric capacitors for high-temperature applications.

 

https://www.nature.com/articles/s41467-025-61936-2

 

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Technique matters: A different way to make cathodes may mean better batteries

 

January 11, 2016

 

Lithium nickel manganese cobalt oxide, or NMC, is one of the most promising chemistries for better lithium batteries, especially for electric vehicle applications, but scientists have been struggling to get higher capacity out of them. Now researchers at Lawrence Berkeley National Laboratory (Berkeley Lab) have found that using a different method to make the material can offer substantial improvements.

http://phys.org/news/2016-01-technique-cathodes-batteries.html


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A Married Couple’s Sweet Music – A Graphene Battery Printing

  

October 25, 2014

 
http://www.greenoptimistic.com/married-couples-sweet-music-graphene-battery-printing-20141025/#.VSFr_eG-2zk


This couple is making beautiful music together – they’ve printed a battery made of graphene.  Dr. Elena Polyakova and Dr. Daniel Stolyarov, originally from Russia, founded Graphene 3D Lab and have since moved the company to Calverton, New York.  They spent more than five years researching raw materials that can be used to make a graphene battery using a 3D printer.

Graphene is a special form of carbon in which the atoms are arranged in a hexagonal lattice along a single layer.  In this configuration, the carbon is 200 times stronger than steel and it conducts electricity 30 times faster than silicon.  It is the latter feature that makes it ideal for making tough composites, computer chips and well, batteries.  Already batteries with lives 25 percent longer than lithium-ion batteries have already been made by other researchers.  Graphene 3D Lab’s design has one up on the competition, however, because it can be made anywhere and practically in any shape.
Although the prototype is able to produce the same amount of power as a common AA battery, it has already produced considerable interest from the military, as well as from the aerospace and car industries, according to Dr. Polyakova, Graphene 3D Lab’s CoO.  The company’s technology allows one to print batteries to fit crooks and nannies where space is tight. It can be used to print other graphene parts.  As such, this technology is very useful for space missions.  Dr. Polyakova says, “That is an exotic example, but a good one. A mission of that kind requires thousands of spare parts and dozens of different battery types. Our technology could remove the need to carry replacement batteries.”

 

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Looking at graphene and other 2d crystals in energy conversion and storage

3 February 2015

 http://graphene-flagship.eu/?news=looking-at-graphene-and-other-2d-crystals-in-energy-conversion-and-storage


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Scientists see the light on microsupercapacitors: Laser-induced graphene makes simple, powerful energy storage possible

December 3, 2015


Rice University researchers who pioneered the development of laser-induced graphene have configured their discovery into flexible, solid-state microsupercapacitors that rival the best available for energy storage and delivery.

http://phys.org/news/2015-12-scientists-microsupercapacitors.html

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KIST Pioneers Next-Gen Energy Storage with Breakthrough Supercapacitor Technology

 

May 9, 2025

 

In a remarkable stride towards the future of energy storage, researchers from the Korea Institute of Science and Technology (KIST) and Seoul National University have unveiled a game-changing supercapacitor technology that promises to revolutionize existing energy storage systems. Spearheaded by Dr. Bon-Cheol Ku and Dr. Seo Gyun Kim from KIST and Professor Yuanzhe Piao of SNU, this pioneering advancement centers on a unique fiber composition integrating single-walled carbon nanotubes (CNTs) and polyaniline (PANI), a conductive polymer. The implications of this research not only demonstrate enhanced performance in supercapacitors but could also redefine their role in various practical applications.

https://scienmag.com/kist-pioneers-next-gen-energy-storage-with-breakthrough-supercapacitor-technology/

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Long-sought chiral anomaly detected in crystalline material

 

September 3, 2015 

 

A study by Princeton researchers presents evidence for a long-sought phenomenon—first theorized in the 1960s and predicted to be found in crystals in 1983—called the "chiral anomaly" in a metallic compound of sodium and bismuth. The additional finding of an increase in conductivity in the material may suggest ways to improve electrical conductance and minimize energy consumption in future electronic devices.

http://phys.org/news/2015-09-long-sought-chiral-anomaly-crystalline-material.html#jCp



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Scientists copy structure of cork to produce 3D blocks of graphene

 

December 6, 2012

 (A scanning electron microscope image of the cork-like 3D graphene (Image: Ling Qiu, Monash University).


 Imagine how limiting it would be if steel, wood or plastic only existed in the form of thin sheets. Well, that’s been the case so far when it comes to graphene. While its incredible strength and high conductivity make it very useful in things like semiconductors, batteries and solar cells, there’s no doubt that it would be even more useful if it could be produced in three-dimensional blocks. Scientists at Australia’s Monash University have now managed to do just that – by copying the structure of cork.

http://www.gizmag.com/3d-graphene-cork-blocks/25342/

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A new wrinkle for cell culture

 

Apr 23, 2015 

 

Researchers from Brown University have developed new graphene surfaces, engineered with tiny wrinkles, as environments for cell culture. The surfaces could provide a way to culture cells in the lab that better approximates the complex environments in which cells grow in the body.

http://phys.org/news/2015-04-wrinkle-cell-culture.html?utm_source=menu&utm_medium=link&utm_campaign=item-menu


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From Disorder to Order: Scientists Rejuvenate Aging Batteries

2025-04-17

A team of scientists led by Prof. LIU Zhaoping at the Ningbo Institute of Materials Technology and Engineering (NIMTE) of the Chinese Academy of Sciences, in collaboration with researchers from the University of Chicago and other institutions, has developed zero thermal expansion (ZTE) materials. This innovation has achieved nearly 100% voltage recovery in aging lithium-ion batteries (LIBs), as detailed in a study published in Nature.

https://en.ncsti.gov.cn/Latest/news/202504/t20250418_202143.html

 

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Scientists Invent Self-healing Battery Electrode

 

November 18, 2013


https://scienceblog.com/scientists-invent-self-healing-battery-electrode/

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Renewable energy from evaporating water (w/ Video)

 

June 16, 2015 

 

(The "moisture mill" is a new kind of turbine engine that turns continuously as water evaporates from the wet paper lining the walls of the engine.)

 

An immensely powerful yet invisible force pulls water from the earth to the top of the tallest redwood and delivers snow to the tops of the Himalayas. Yet despite the power of evaporating water, its potential to propel self-sufficient devices or produce electricity has remained largely untapped—until now.
In the June 16 online issue of Nature Communications, Columbia University scientists report the development of two novel devices that derive power directly from evaporation - a floating, piston-driven engine that generates electricity causing a light to flash, and a rotary engine that drives a miniature car.

http://phys.org/news/2015-06-renewable-energy-evaporating-video.html



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World's first "aqueous solar flow battery" outperforms traditional lithium-iodine batteries

  

August 3, 2015

 The scientists that revealed the "world's first solar battery" last year are now, following some modifications, reporting its first significant performance milestone. The device essentially fits a battery and solar cell into the one package, and has now been tested against traditional lithium-iodine batteries, over which the researchers are claiming energy savings of 20 percent.


It was last October that researchers at Ohio State University (OSU) first detailed their patent-pending design for a dye-sensitized solar cell also capable of storing its own power. With three electrodes rather than the typical four, it featured a lithium plate base, two layers of electrode separated by a thin sheet of porous carbon, and a titanium gauze mesh that played host to a dye-sensitive titanium dioxide photoelectrode.
The reasoning behind the porous nature of the materials was to allow the battery's ions to oxidize into lithium peroxide, which was in turn chemically decomposed into lithium ions and stored as lithium metal. But the team has redesigned the battery so that air no longer needs to pass through it in order to function.


http://www.gizmag.com/aqueous-solar-flow-battery-osu/38748/?li_source=LI&li_medium=default-widget

 

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First Quantum Phase “Supercurrent” Battery Ever Developed

 

January 26, 2022

https://science-atlas.com/technology/first-quantum-phase-supercurrent-battery-ever-developed/

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Identifying material properties for more efficient solid-state batteries

Jan. 30, 2025

https://www.llnl.gov/article/52366/identifying-material-properties-more-efficient-solid-state-batteries

 

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Unlocking safer batteries: New study uncovers key insights into electrolyte materials for all-solid-state batteries

February 10, 2025

https://www.anl.gov/article/unlocking-safer-batteries-new-study-uncovers-key-insights-into-electrolyte-materials-for

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‘Cold’ manufacturing approach to make next-gen batteries

April 24, 2025

Fabrication challenge for solid-state batteries solved through advanced technique, researchers report 

UNIVERSITY PARK, Pa. — Lithium-ion batteries have been a staple in device manufacturing for years, but the liquid electrolytes they rely on to function are quite unstable, leading to fire hazards and safety concerns. Now, researchers at Penn State are pursuing a reliable alternative energy storage solution for use in laptops, phones and electric vehicles: solid-state electrolytes (SSEs). 

According to Hongtao Sun, assistant professor of industrial and manufacturing engineering, solid-state batteries — which use SSEs instead of liquid electrolytes — are a leading alternative to traditional lithium-ion batteries. He explained that although there are key differences, the batteries operate similarly at a fundamental level. 

“Rechargeable batteries contain two internal electrodes: an anode on one side and a cathode on the other,”" Sun said. “Electrolytes serve as a bridge between these two electrodes, providing fast transport for conductivity. Lithium-ion batteries use liquid electrolytes, while solid-state batteries use SSEs.” 

Solid-state batteries offer improved stability and safety when compared to traditional lithium-ion batteries but face several manufacturing and conductivity challenges, Sun explained. For example, the high temperatures introduced in the fabrication process, especially with ceramic-based SSE

https://www.psu.edu/news/engineering/story/cold-manufacturing-approach-make-next-gen-batteries

 

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Scientists Turn Nuclear Waste into Electricity with New Micro-Battery Design

February 25, 2025

Ohio State researchers have developed a novel battery that harnesses gamma radiation—typically considered a harmful waste product—to generate usable electricity. The prototype device, roughly the size of a sugar cube, might eventually help power sensors in nuclear facilities or deep space missions.

https://scienceblog.com/scientists-turn-nuclear-waste-into-electricity-with-new-micro-battery-design/


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Electricity-producing slime could power floors, shoes and more

February 6, 2025

 

University of Guelph (U of G) researchers have developed a slime-like material that produces electricity when compressed. When the team studied their prototype using the Canadian Light Source (CLS) at the University of Saskatchewan, they discovered the material has an array of potential applications.

If installed in floors, it could produce clean energy when people walk on it. If incorporated into a shoe insole, it could be used to analyze your gait. In theory, says lead researcher Erica Pensini, their material could even be used as the basis for a synthetic skin to train robots to know how much pressure to use when checking the pulse of a patient.

"The synchrotron is like a super-microscope," says Pensini. "It allowed us to see that if you apply an electric field, you can change the crystalline structure of this material."

Pensini, an associate professor at U of G, and colleagues, found that the "slime" could form different structures at the microscopic level so that it either arranged itself like a sponge, formed layers like a lasagna, or took on a hexagonal form. Pensini conducted the work in collaboration with U of G professors Alejandro G. Marangoni, Aicheng Chen, and Stefano Gregori. Their findings are published in the Journal of Molecular Liquids.

This property, explains Pensini, could offer an opportunity for the targeted delivery of medicine within the body. "Imagine you have the material take an initial structure that contains a pharmaceutical substance and then, when an electric field is applied to it, the structure changes to release the medicine."

The team's prototype is composed of natural materials that are highly compatible with the body. It is 90% water plus oleic acid (found in olive oil) and amino acids (the building blocks of protein in the body). "I wanted to make something that is 100% benign and that I would put on my skin without any concerns," she says.

The material could also be used to make bandages that actively promote healing. "Our bodies produce small electric fields to attract healing cells to an open wound," says Pensini. "By creating a bandage that increases this electric field, healing could theoretically happen faster. In this case, the bandage would be activated by our natural movements and breathing."

Pensini is excited about the potential uses for their "slime." In the meantime, she plans to use it as a salve for her hands after rock climbing. "I need an initial guinea pig, so it might as well be me, right?"

 

Polarized light microscopy of mixtures containing equimolar ratios of oleic acid and DEA without water (A) and in the presence of 57 wt% water (B and C, which show different features). The scale bar is 200 μm. Credit: Journal of Molecular Liquids (2024). 

https://techxplore.com/news/2025-02-electricity-slime-power-floors.html

 

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Waste to wealth: Pomelo peel can be used for electricity generation and sensing devices

February 21, 2025

Pomelo is a large citrus fruit commonly grown in Southeast and East Asia. It has a very thick peel, which is typically discarded, resulting in a considerable amount of food waste. In a new study, University of Illinois Urbana-Champaign researchers explore ways to utilize waste pomelo-peel biomass to develop tools that can power small electric devices and monitor biomechanical motions.

https://fshn.illinois.edu/news/waste-wealth-pomelo-peel-can-be-used-electricity-generation-and-sensing-devices

 

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Scientists turn dead battery waste, CO2 into fuel, killing 2 birds with 1 stone

Mar 05, 2025

Researchers extracted nickel from Ni-MH batteries and alumina from aluminum foil, converting them into a high-performance nanocatalyst using green chemistry.

https://interestingengineering.com/innovation/battery-waste-into-clean-fuel


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Battery waste and kitchen foil create nanocatalyst for CO₂ to methane fuel conversion

March 4, 2025 

Battery waste is a serious environmental problem: It contains substances that pose a threat to both human health and ecosystems. At the same time, however, batteries also contain valuable materials such as nickel, which we need—for example, for the production of new batteries. Better recycling methods for batteries are therefore urgently required.

https://phys.org/news/2025-03-battery-kitchen-foil-nanocatalyst-methane.html

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Scientific breakthrough brings CO2 'breathing' batteries closer to reality

May 20, 2025

Scientists at the University of Surrey have made a breakthrough in eco-friendly batteries that not only store more energy but could also help tackle greenhouse gas emissions. Lithium-CO₂ 'breathing' batteries release power while capturing carbon dioxide, offering a greener alternative that may one day outperform today's lithium-ion batteries.

Until now, Lithium-CO₂ batteries have faced setbacks in efficiency -- wearing out quickly, failing to recharge and relying on expensive rare materials such as platinum. However, researchers from Surrey have found a way to overcome these issues by using a low-cost catalyst called caesium phosphomolybdate (CPM). Using computer modelling and lab experiments, tests showed this simple change allowed the battery to store significantly more energy, charge with far less power and run for over 100 cycles.

https://www.sciencedaily.com/releases/2025/05/250520122027.htm

 

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New nanomaterial offers breakthrough in energy storage and environmental sustainability 

 21-May-2025 

Researchers from Shinshu University developed a low-cost nanocomposite by embedding bimetallic and trimetallic molybdates into nitrogen-, boron-, and fluorine-doped hollow carbon nanofibers. This material demonstrated excellent electrochemical performance for supercapacitors, with high capacitance and long-term stability, as well as strong catalytic efficiency in degrading 4-nitrophenol, a common industrial pollutant. The composite offers promising dual functionality for energy storage and environmental remediation, providing a scalable and efficient solution to address pressing global energy and pollution challenges.

https://www.eurekalert.org/news-releases/1084692

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Breakthrough could enable diamond transistors for high-power applications

30 January 2025

A landmark development led by researchers from the University of Glasgow could help create a new generation of diamond-based transistors for use in high-power electronics.

Their new diamond transistor overcomes the limitations of previous developments in the technology to create a device much closer to being of practical use across a range of industries which rely on high power systems.

The team have found a new way to use diamond as the basis of a transistor that remains switched off by default - a development crucial for ensuring safety in devices which carry a large amount of electrical current when switched on.

Diamond has an inherent property known as a wide band gap, meaning it is capable of handling much higher voltages than silicon - the material the majority of transistors are made from - before electrically breaking down. In power electronic applications, that means that transistors made from materials such as diamond can withstand significantly higher voltages and deliver higher power than Si transistors.

The team’s diamond transistor could find applications in sectors where largely voltages are required and efficiency is highly-valued, like power grids or electric vehicles. 

https://www.myscience.org/en/news/2025/breakthrough_could_enable_diamond_transistors_for_high_power_applications-2025-glasgow


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Metal-free supercapacitor stack delivers 200 volts from just 3.8 cm³

22-Jul-2025

https://sciencesources.eurekalert.org/news-releases/1092126

____________________________________

 

 New metal design for solid-state batteries enables operation at lower pressures

June 9, 2025

Lithium-ion batteries power everything from electric cars to laptops to leaf blowers. Despite their widespread adoption, lithium-ion batteries carry limited amounts of energy, and rare overheating can lead to safety concerns. Consequently, for decades, researchers have sought a more reliable battery.

https://techxplore.com/news/2025-06-metal-solid-state-batteries-enables.html

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Stanford and MIT engineers find new way to harness waste heat

 

May 21, 2014

Researchers have developed a new battery technology that captures waste heat and converts it into electricity.

https://engineering.stanford.edu/news/stanford-and-mit-engineers-find-new-way-harness-waste-heat

____________________________________

 

A new solid-state battery surprises the researchers who created it 

 

Sep 24, 2021

 

Engineers created a new type of battery that weaves two promising battery sub-fields into a single battery. The battery uses both a solid state electrolyte and an all-silicon anode, making it a silicon all-solid-state battery. The initial rounds of tests show that the new battery is safe, long lasting, and energy dense. It holds promise for a wide range of applications from grid storage to electric vehicles.

 

The battery technology is described in the 24 September, 2021 issue of the journal Science. University of California San Diego nanoengineers led the research, in collaboration with researchers at LG Energy Solution.

 

https://www.spacedaily.com/reports/A_new_solid_state_battery_surprises_the_researchers_who_created_it_999.html
 

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Solid state battery design charges in minutes, lasts for thousands of cycles

 

Research paves the way for better lithium metal batteries

 

January 8, 2024

 

https://seas.harvard.edu/news/2024/01/solid-state-battery-design-charges-minutes-lasts-thousands-cycles
 

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University of Texas Scientists Develop Anode-Free Solid-State Battery with Increased Energy Density

 

April 7, 2023

 

https://evmagz.com/university-of-texas-scientists-develop-anode-free-solid-state-battery-with-increased-energy-density/

 

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Self-adaptive electrolytes expand stability for fast charging and high-energy batteries

 

August 9, 2025

 

https://techxplore.com/news/2025-08-electrolytes-stability-fast-high-energy.html

 

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17 Tech Experts Discuss What’s New And Next In Nanotech

 

Apr 26, 2023

 

1. Advances In Addressing Neurodiversity And Disabilities

 

2. Graphene As An Accurate And Efficient Sensor Material

 

3. Nanorobot Applications In Multiple Industries

 

4. Upgrades To Computers And Other Digital Devices

 

5. Personalized, Smart Living Spaces

 

6. More Durable And Energy-Efficient Buildings

 

7. Water Testing And Treatment

 

8. ‘Green’ Growth In Agricultural Productivity

 

9. Medical Condition Monitoring And Targeted Treatment

 

10. Enhanced Access To Big Data

 

11. Nanocellulose As An Eco-Friendly Alternative To Plastics

 

12. DNA Origami

 

13. New Teaching Aids And Learning Tools

 

14. Nanocomposites For Lighter, Stronger Aircraft And Automobiles

 

15. Nanobots That Carry Out Critical Natural Functions

 

16. Higher-Energy, Faster-Charging Batteries

 

17. Safer, More Efficient Space Exploration

 

https://www.forbes.com/councils/forbestechcouncil/2023/04/26/17-tech-experts-discuss-whats-new-and-next-in-nanotech/

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Chapter 16: Magnetic energy



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Magnetic energy

 

https://en.wikipedia.org/wiki/Magnetic_energy

Magnetic energy and electric energy are related by Maxwell's equations. The potential energy of a magnet of magnetic moment m in a magnetic field B is defined as the mechanical work of magnetic force (actually of magnetic torque) on re-alignment of the vector of the magnetic dipole moment.


____________________________________

 

New class of "non-Joulian magnets" have potential to revolutionize electronics

May 21, 2015

Magnets are at the heart of much of our technology, and their properties are exploited in a myriad ways across a vast range of devices, from simple relays to enormously complex particle accelerators. A new class of magnets discovered by scientists at the University of Maryland (UMD) and Temple University may lead to other types of magnets that expand in different ways, with multiple, cellular magnetic fields, and possibly give rise to a host of new devices. The team also believes that these new magnets could replace expensive, rare-earth magnets with ones made of abundant metal alloys.

http://www.gizmag.com/expanding-alloy-magnets/37621/

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Electromagnetic fields as cutting tools

Dec 01, 2009

http://phys.org/news178914974.html

 

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Melt metal with magnets

 https://www.youtube.com/watch?v=8i2OVqWo9s0

 

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 Molecular trick alters rules of attraction for non-magnetic metals

August 5, 2015

Scientists have demonstrated for the first time how to generate magnetism in metals that aren't naturally magnetic, which could end our reliance on some rare and toxic elements currently used...

- Magnets are used in many industrial and technological applications, including power generation in wind turbines, memory storage in hard disks and in medical imaging.

"Future technologies, such as quantum computers, will require a new breed of magnets with additional properties to increase storage and processing capabilities. Our research is a step towards creating such 'magnetic metamaterials' that can fulfil this need," said Al Ma'Mari.

http://phys.org/news/2015-08-molecular-non-magnetic-metals.html#jCp




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MERS Device Harnesses Residual Magnetic Power Produced by Electrical Current

 

September 27, 2010

Researchers at the Tokyo Institute of Technology in collaboration with the Office of Naval Research Global plan to develop a new device for capturing residual magnetic energy from electrical current.

http://www.greenoptimistic.com/mers-device-magnetic-power-recovery-20100927/

 

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Magnetic Pendulum: A Free Energy Device Running for Three Years Now

 

January 19, 2010

http://www.greenoptimistic.com/magnetic-pendulum-a-free-energy-device-running-for-three-years-now-20100119/#.VSFjmuG-2zk


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World's first magnetic "wormhole" produces magnetic monopole

 September 4, 2015

It may not instantly whisk you to far-flung reaches of the universe like the gravitational wormholes of Stargate, Star Trek and Interstellar, but researchers at Universitat Autònoma de Barcelona (UAB) claim to have created the first experimental wormhole that links two regions of space magnetically.


http://www.gizmag.com/magnetic-wormhole/39257/

 

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Scientists At NASA Announce That Space Portals Actually Do Exist

 

Is science finally catching up with spirituality?

 

A few years ago now it was announced that  NASA funded plasma physicist Jack Scudder at the University of Iowa had discovered what science fiction lovers have dreamt about since day one: a wormhole, the portal that links the Earth to far away galaxies that would otherwise be impossible to reach.
Well, that’s what we hoped they meant. It turns out these so called “X-points”, or electronic diffusion regions, is a connection linking the Earth’s magnetic field to the sun’s magnetic field.
Alas it is not the galaxy hopping wormhole we were hoping for, but it could be potentially be a start into finding something along those lines.

http://www.neonnettle.com/news/1432-scientists-at-nasa-announce-that-space-portals-actually-do-exist


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Converting Magnetic Energy Into Electric Voltage Using Power Spintronics

 

January 4, 2013

The American Institute of Physics’ (AIP) journal Applied Physics Letters, published a report, which shows a new application of spintronics. According to the study, it is now possible to convert magnetic energy into electric voltage by changing the dynamics of magnetization using magnetic nanostructures.

http://www.greenoptimistic.com/converting-magnetic-energy-into-electric-voltage-using-power-spintronics-20130104/ 




____________________________________

New Technology 2014 Floating Magnetic Cars

 

Dec 15, 2013
 

https://www.youtube.com/watch?v=mmMbyAGlnI4

 
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Tiny magnets mimic steam, water and ice

 

September 21, 2015

Researchers at the Paul Scherrer Institute (PSI) created a synthetic material out of 1 billion tiny magnets. Astonishingly, it now appears that the magnetic properties of this so-called metamaterial change with the temperature, so that it can take on different states; just like water has a gaseous, liquid and a solid state. This material made of nanomagnets might well be refined for electronic applications of the future – such as for more efficient information transfer.

 http://phys.org/news/2015-09-tiny-magnets-mimic-steam-ice.html#jCp

 

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 New tool for studying magnetic, self-propelled bacteria that resemble compass needles

September 15, 2015

 In the Marvel Comics universe, Professor Xavier and the X-Men are only able to fend off their archrival Magneto, the magnetic mutant with the ability to control metals, once they truly understand the scope of the villain's powers. To better understand the behavior of the microbial world's Magnetos—the magnetically influenced water-dwellers known as magnetotactic bacteria—three researchers from Europe and Russia have developed a new tool that allows these unique microscopic species to be studied more easily, especially in their natural environment.

http://phys.org/news/2015-09-tool-magnetic-self-propelled-bacteria-resemble.html#jCp

 

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Giant enhancement of magnetic effect will benefit spintronics

 

December 21, 2015

 Researchers have demonstrated that coating a cobalt film in graphene doubles the film's perpendicular magnetic anisotropy (PMA), so that it reaches a value 20 times higher than that of traditional metallic cobalt/platinum multilayers that are being researched for this property. In a material with a high PMA, the magnetization is oriented perpendicular to the interface of the material's layers. High-PMA materials are being researched for their applications in next-generation spintronic devices, such as high-density memories and heat-tolerant logic gates.

The researchers, Hongxin Yang, et al., have published a paper on the giant PMA enhancement in a recent issue of Nano Letters.

http://phys.org/news/2015-12-giant-magnetic-effect-benefit-spintronics.html#jCp


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 Cooled down and charged up, a giant magnet is ready for its new mission

September 24, 2015

The Fermi National Accelerator Laboratory—or Fermilab—announced that a 680-ton superconducting magnet is secure in its new home and nearly ready for a new era of discovery in particle physics. This achievement follows the delicate, 3,200-mile transport of the magnet's 17-ton, 50-foot-wide housing ring to the U.S. Department of Energy facility outside Chicago two years ago. The fully assembled magnet will drive high-energy particle experiments as part of an international partnership among 34 institutions, of which the University of Washington is a leading contributor.

http://phys.org/news/2015-09-cooled-giant-magnet-ready-mission.html#jCp

 

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Massive Research Magnets Are on the Move for Groundbreaking Experiments

August 13, 2025

 

 

Scientists and engineers across the United States are currently undertaking an awe-inspiring task: moving massive research magnets across the country to power new, groundbreaking experiments. These magnets are nothing like everyday refrigerator magnets—they are enormous, highly complex, and incredibly powerful electromagnets designed to steer and manipulate subatomic particles in advanced scientific facilities. By repurposing these magnets instead of building new ones from scratch, national laboratories achieve huge cost savings while pushing the boundaries of fundamental physics, materials science, and quantum research. 

 
https://stc-mditr.org/massive-research-magnets-are-on-the-move-for-groundbreaking-experiments/

 

 ____________________________________

 

 

Decades-long experiment finds muon still behaving unexpectedly

 

June 3, 2025

https://phys.org/news/2025-06-decades-muon-unexpectedly.html

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Control of spin qubits at near absolute zero provides path forward for scalable quantum computing

June 25, 2025

Developing technology that allows quantum information to be both stable and accessible is a critical challenge in the development of useful quantum computers that operate at scale. Research published in the journal Nature provides a pathway for scaling the number of quantum transistors (known as qubits) on a chip from current numbers under 100 to the millions needed to make quantum computation a practical reality. The result is enabled by new cryogenic control electronics that operate at close to absolute zero, developed at the University of Sydney.

https://phys.org/news/2025-06-qubits-absolute-path-scalable-quantum.html#google_vignette

 

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Researcher develop an electrical switch for magnetic current

Mar 01,2012

 

Researchers at the Max Planck Institute of Microstructure Physics in Halle developed a new switching mechanism for magnetic current. The idea is to use a short electric pulse to change the magnetic transport properties of a material sandwich consisting of a ferroelectric layer between two ferromagnetic materials. The new mechanism could be used to store information in four states of a storage point, not just two - which doubles storage density or lowers the size of MRAM devices. 

 

 In ferroelectric materials, voltage switches between the two directions of an electric polarisation – depending on its polarity – not unlike when a magnetic field permanently reverses the polarity of a ferromagnet. As ions shift within the material structure during this process, the polarisation remains intact, even after the voltage has been reduced. It is possible, however, to reverse the switch again with a similarly large voltage with reversed polarity.

https://www.spintronics-info.com/researcher-develop-electrical-switch-magnetic-current

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Superconducting Magnets Could Unlock a Hidden Universe of Gravitational Waves

June 28, 2025

https://www.sciencenewstoday.org/superconducting-magnets-could-unlock-a-hidden-universe-of-gravitational-waves


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A newly discovered type of superconductor is also a magnet

May 22, 2025

Magnets and superconductors go together like oil and water—or so scientists have thought. But a new finding by MIT physicists is challenging this century-old assumption.

In a paper appearing in the journal Nature, the physicists report that they have discovered a "chiral superconductor"—a material that conducts electricity without resistance, and also, paradoxically, is intrinsically magnetic. What's more, they observed this exotic superconductivity in a surprisingly ordinary material: graphite, the primary material in pencil lead.

Graphite is made from many layers of graphene—atomically thin, lattice-like sheets of carbon atoms—that are stacked together and can easily flake off when pressure is applied, as when pressing down to write on a piece of paper. A single flake of graphite can contain several million sheets of graphene, which are normally stacked such that every other layer aligns. But every so often, graphite contains tiny pockets where graphene is stacked in a different pattern, resembling a staircase of offset.

The MIT team has found that when four or five sheets of graphene are stacked in this "rhombohedral" configuration, the resulting structure can exhibit exceptional electronic properties that are not seen in graphite as a whole.

In their new study, the physicists isolated microscopic flakes of rhombohedral graphene from graphite, and subjected the flakes to a battery of electrical tests. They found that when the flakes are cooled to 300 millikelvins (about -273 degrees Celsius), the material turns into a superconductor, meaning that any electrical current passing through the material can flow through without resistance.

They also found that when they swept an external magnetic field up and down, the flakes could be switched between two different superconducting states, just like a magnet. This suggests that the superconductor has some internal, intrinsic magnetism. Such switching behavior is absent in other superconductors.

https://phys.org/news/2025-05-newly-superconductor-magnet.html


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The secrets of world’s thinnest superconductor uncovered

 
June 22, 2021

 

 The world’s thinnest superconductor exhibits unusual electronic behavior. The superconductor, which is just an atomic layer thick, has several applications as it conducts electricity exceptionally efficiently.

 

The work could transform the fields of medical diagnostics, quantum computing, and energy transport.

 

It can superconducting at 65 K. In contrast, bulk samples of the same material superconduct at a much lower temperature (8 K).

 

n new work, MIT scientists offered the first experimental evidence of spin excitations in this superconductor.

 

Until now, physicists assume that it is impossible to quantify spin excitations in material only an atomic layer thick. In this new work, scientists did not only detect spin excitations but, among other things, also showed that the spin dynamics in the ultra-thin sample were dramatically different from those in the bulk sample. They found that the energy of fluctuating spins in the ultra-thin sample was much higher than the energy of the spins in the bulk sample.

 

Jonathan Pelliciari, a former MIT postdoc, said, “This is the first experimental evidence of the presence of spin excitations in an atomically thin material.”

 

Usually, neutron scattering is used to study magnetism. Since spin is the principal property of magnetism, neutron scattering would give off an impression of being a decent test. However, the technique doesn’t work on a material that is only one atomic layer thick.

 

Hence, scientists used a new experimental technique called resonant inelastic X-ray scattering (RIXS).

 

 https://www.techexplorist.com/secrets-world-thinnest-superconductor-uncovered/39720/

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'Thermoelectric permanent magnet' achieves record power density for energy harvesting

 

June 23, 2025

https://techxplore.com/news/2025-06-thermoelectric-permanent-magnet-power-density.html

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Topological magnetic field textures

 

20 December 2021

 

Curvilinear DNA-shaped magnetic double helices enable tunable magnetic field nanotextures. 

https://www.nature.com/articles/s41565-021-00984-3

 
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Decoding nanomaterial phase transitions with tiny drums

 

 March 16, 2025

 

When water freezes into ice or boils into vapor, its properties change dramatically at specific temperatures. These so-called phase transitions are fundamental to understanding materials. But how do such transitions behave in nanomaterials? A team of scientists now presents new insights into the complex nature of phase transitions in magnetic nanomaterials. Their findings reveal the coupling between magnetic and mechanical properties, paving the way for ultra-sensitive sensors.

https://www.sciencedaily.com/releases/2025/03/250312124608.htm

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Physicists Reveal Non-Reciprocal Flow Round the Quantum World Utilizing an Artificial Magnetic Field

 

April 24, 2021

 

Physicists reveal non-reciprocal flow around the quantum world. Physicists have created a theory describing how non-reciprocity can be induced at the quantum level, paving the way for non-reciprocal transport in the next generation of nanotechnology.

 

Theory of non-reciprocal flow could lead to new quantum devices – Synthetic magnetic fields control flow around quantum trimers.

 

Their results pave the way for new experimental studies of nanoscale directional currents, which could lead to the development of new ways of controlling the flow of energy and information. The research could also lead to new studies of exotic states of matter that feature strongly interacting quantum systems.

 

• Synthetic magnetic fields
• Exotic states of matter

 

Physicists from Exeter and Zaragoza have created a theory describing how non-reciprocity can be induced at the quantum level, paving the way for non-reciprocal transport in the next generation of nanotechnology...

 
https://science-atlas.com/physics/physicists-reveal-non-reciprocal-flow-round-the-quantum-world/

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Generating Megatesla Magnetic Fields on Earth Using Intense-Laser-Driven Microtube Implosions

 

October 12, 2020

 

A team of researchers led by Osaka University discovers “microtube implosion,” a novel mechanism that demonstrates the generation of megatesla-order magnetic fields.

 

Magnetic fields are used in various areas of modern physics and engineering, with practical applications ranging from doorbells to maglev trains. Since Nikola Tesla’s discoveries in the 19th century, researchers have strived to realize strong magnetic fields in laboratories for fundamental studies and diverse applications, but the magnetic strength of familiar examples are relatively weak. Geomagnetism is 0.3−0.5 gauss (G) and magnetic tomography (MRI) used in hospitals is about 1 tesla (T = 10⁴ G). By contrast, future magnetic fusion and maglev trains will require magnetic fields on the kilotesla (kT = 10⁷ G) order. To date, the highest magnetic fields experimentally observed are on the kT order.

 

Recently, scientists at Osaka University discovered a novel mechanism called a “microtube implosion,” and demonstrated the generation of megatesla (MT = 10¹⁰G) order magnetic fields via particle simulations using a supercomputer. Astonishingly, this is three orders of magnitude higher than what has ever been achieved in a laboratory. Such high magnetic fields are expected only in celestial bodies like neutron stars and black holes.

 

https://scitechdaily.com/generating-megatesla-magnetic-fields-on-earth-using-intense-laser-driven-microtube-implosions/ 

 

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Nanomagnets power micromachine bird

November 8th, 2019

 

Researchers assembled the micromachine from materials that contain small nanomagnets. They can program these nanomagnets to assume a particular magnetic orientation. When the programmed nanomagnets are then exposed to a magnetic field, specific forces act on them. If these magnets are located in flexible components, the forces acting on them cause the components to move.

 

For the construction of the microrobot, the researchers fabricated arrays of cobalt magnets on thin sheets of silicon nitride. The bird constructed from this material could then perform various movements, such as flapping, hovering, turning, or side-slipping. The researchers report the work in the journal Nature.

 

 

https://www.futurity.org/micromachine-bird-nanomagnets-2205972-2/

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‘Microflower’ structure amplifies magnetic fields 5x, can boost devices’ efficiency

Mar 29, 2025

Precise control over the elemental blocks of magnetic metamaterials enables the concentration, focusing, and guiding of magnetic fields.

https://interestingengineering.com/science/magnetic-microflowers-enhance-magnetic-fields

 

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New Way of Using Spin Waves in Magnetic Materials Can lead to Smaller sized, Faster Electronics

 

July 23, 2021

 

Magnets and electricity – The basic principles of electricity and electrical magnets.

 

Have you ever held two magnets close to each other? They don’t act like most objects. If you try to push the two north poles or two south poles together, they repel each other. But if you put a north pole and a south pole together, the magnets will stick together because the north and south poles attract each other. Just like protons and electrons—opposites attract in magnets.

Video advice: Spin Waves & Magnons

 

This video is about spin waves and magnons. It has been explained with the help of ferromagnetic chain of spins. The next video will cover dispersion relation of ferromagnetic magnons...

 

Physics – Electroengineering – 06. 12. 2019 In surprise breakthrough, scientists create quantum states in everyday electronicsAfter decades of miniaturization, the electronic components we’ve relied on for computers and modern technologies are now starting to reach fundamental limits. Faced with this challenge, engineers and scientists around the world are turning toward a radically new paradigm: quantum information technologies. Quantum technology, which harnesses the strange rules that govern particles at the atomic level, is normally thought of as much too delicate to coexist with the electronics we use every day in phones, laptops and cars.

 

Physicists find a way to eliminate unwanted damping. Smaller, faster, more energy-efficient – this is the goal that developers of electronic devices have been working towards for years. In order to be able to miniaturize individual components of mobile phones or computers, for example, magnetic wav.

https://science-atlas.com/physics/new-way-of-using-spin-waves-in-magnetic-materials-can-lead-to-smaller/

 

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Innovative Approach to Controlling Magnetism Opens Route to Ultra-Low-Power Microchips

 

November 15, 2018

 

All machines convert one form of energy into another form - for example a car engine turns the energy stored in fuel into motion energy. Those processes of energy conversion, described by the theory called thermodynamics, don't only take place on the macro-level of big machines, but also at the micro-level of molecular machines that drive muscles or metabolic processes and even on the atomic level. The research team of Prof. Massimiliano Esposito of the University of Luxembourg studies the thermodynamics of small nanomachines only consisting of a few atoms. In a paper published in the prestigious scientific journal Physical Review X, they outline how these small machines behave in concert. Their insights could be used to improve the energy efficiency of all kinds of machines, big or small. 

 
https://www.powersystemsdesign.com/articles/nanomachine-swarms-could-improve-efficiency-of-any-machine/8/13499

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New single-molecule magnet tech could unlock hard drives with 100x more capacity — drives could store half a million TikTok views on a hard drive the size of a postage stamp, or three terabytes per square centimeter

June 26, 2025

https://www.tomshardware.com/pc-components/storage/new-single-molecule-magnet-tech-could-unlock-hard-drives-with-100x-more-capacity-drives-could-store-three-terabytes-per-square-centimeter

 

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Spintronics Advances: Efficient Magnetization Direction Control of Magnetite for High-Density Spintronic Memory Devices

June 25, 2021

 

 Scientists develop an energy-efficient strategy to reversibly change ‘spin orientation’ or magnetization direction in magnetite at room temperature.

 

https://scitechdaily.com/spintronics-advances-efficient-magnetization-direction-control-of-magnetite-for-high-density-spintronic-memory-devices/

 

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Magnetic Memory Breakthrough: Physicists Observe an Exotic “Multiferroic” State in an Atomically Thin Material

 

February 27, 2022 

 

Discovery shows for the first time that multiferroic properties can exist in a two-dimensional material; could lead to more efficient magnetic memory devices.

https://scitechdaily.com/magnetic-memory-breakthrough-physicists-observe-an-exotic-multiferroic-state-in-an-atomically-thin-material/

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How Magnetite Nanoparticles Are Transforming Digital Communications

August 15, 2023

We could be on the brink of an unprecedented change in digital communications, similar in importance to when the internet was first introduced. 

This change, a blend of the natural world with advanced nanotechnology, suggests a new age of high-speed internet connectivity, primarily utilising magnetite nanoparticles...

https://elnano.com/how-magnetite-nanoparticles-are-transforming-digital-communications/

 

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Could hBN Become Quantum Technology’s Go-To Material?

October 19, 2023

Nanotechnology is a rapidly evolving field that continually pushes the boundaries of what is possible at the nanoscale. In recent years, diamond has been the go-to material for quantum sensing, thanks to its nitrogen-vacancy centers, controllable spin, and sensitivity to magnetic fields. Diamond, a default choice for quantum sensing, has met its match in hexagonal boron nitride (hBN), an often-overlooked material that is gaining attention as a potential quantum technology future material.

https://elnano.com/could-hbn-become-quantum-technologys-go-to-material/

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Room temperature coherent control of spin defects in hexagonal boron nitride

 

2 Apr 2021

 

Abstract

 

Optically active spin defects are promising candidates for solid-state quantum information and sensing applications. To use these defects in quantum applications coherent manipulation of their spin state is required. Here, we realize coherent control of ensembles of boron vacancy centers in hexagonal boron nitride (hBN). Specifically, by applying pulsed spin resonance protocols, we measure a spin-lattice relaxation time of 18 microseconds and a spin coherence time of 2 microseconds at room temperature. The spin-lattice relaxation time increases by three orders of magnitude at cryogenic temperature. By applying a method to decouple the spin state from its inhomogeneous nuclear environment the optically detected magnetic resonance linewidth is substantially reduced to several tens of kilohertz. Our results are important for the employment of van der Waals materials for quantum technologies, specifically in the context of high resolution quantum sensing of two-dimensional heterostructures, nanoscale devices, and emerging atomically thin magnets.

 

https://www.science.org/doi/10.1126/sciadv.abf3630


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Researchers Have Found A New Way To Control Magnets – Here Is How

 

September 24, 2021 

 

Researchers at MIT have developed a way of quickly changing the magnetic polarity of a ferrimagnet 180 degrees, using just a small applied voltage. According to the researchers, the discovery could herald a new era of ferrimagnetic logic and data storage systems.  

 

The findings were published in the journal Nature Nanotechnology in a paper co-authored by postdoctoral researcher Mantao Huang, MIT professor of materials science and technology Geoffrey Beach, and professor of nuclear science and technology Bilge Yildiz, as well as 15 other researchers from MIT and other institutions in Minnesota, Germany, Spain, and Korea.

 

The majority of magnets we come across are of “ferromagnetic” materials. The atoms in these materials are oriented in the same direction with their north-south magnet axes; thus, their combined strength is strong enough to create attraction. As a result, these materials are often used in the modern high-tech environment.

 

https://wonderfulengineering.com/researchers-have-found-a-new-way-to-control-magnets-here-is-how/



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New Method to Control Nanoparticles with Light and Magnets

 

October 10, 2014

 

A team of researchers has developed particles that can glow with color-coded light and be manipulated with magnets, improving the likelihood of tracking the position of the nanoparticles as they move within the body or inside a cell. 

 

A long-sought goal of creating particles that can emit a colorful fluorescent glow in a biological environment, and that could be precisely manipulated into position within living cells, has been achieved by a team of researchers at MIT and several other institutions. The finding is reported this week in the journal Nature Communications.

https://scitechdaily.com/new-method-control-nanoparticles-light-magnets/

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Quantum twist: In a first, magnet-free spin transport achieved in graphene

Jul 06, 2025

Scientists have found that they can trigger and control quantum spin currents without magnets by placing graphene on a chosen magnetic material, paving way for ultrathin, next-gen quantum devices.

https://interestingengineering.com/science/graphene-shows-spin-currents-without-magnets

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Findings to Help Achieve Holy Grail of 2D Materials – Superfast Electronic Devices

 

November 13, 2020

 

Researchers discover new family of quasiparticles in graphene-based materials. 

 

A group of researchers led by Sir Andre Geim and Dr. Alexey Berdyugin at The University of Manchester have discovered and characterized a new family of quasiparticles named ‘Brown-Zak fermions’ in graphene-based superlattices.

 

The team achieved this breakthrough by aligning the atomic lattice of a graphene layer to that of an insulating boron nitride sheet, dramatically changing the properties of the graphene sheet.

 

The study follows years of successive advances in graphene-boron nitride superlattices which allowed the observation of a fractal pattern known as the Hofstadter’s butterfly — and today (Friday, November 13, 2020) the researchers report another highly surprising behavior of particles in such structures under applied magnetic field.

 
https://scitechdaily.com/findings-to-help-achieve-holy-grail-of-2d-materials-superfast-electronic-devices/

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Quantum materials quest could benefit from graphene that buckles

 

Aug 14, 2020

 

Cooled graphene mimics effect of enormous magnetic fields that would benefit electronics. 

 
https://www.nanotechnologyworld.org/post/quantum-materials-quest-could-benefit-from-graphene-that-buckles

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Revolutionizing Spintronics: Electric Field Control Eliminates Need for Magnets

 

April 3, 2025

 

Spintronics is a promising and rapidly evolving field that could transform the world of  electronics. Unlike traditional electronics, which rely on the charge of electrons to carry information, spintronics takes advantage of an additional property of electrons known as spin. This spin, a quantum mechanical property of electrons, can be manipulated to process and store data, leading to potentially faster, more efficient devices that consume significantly less power. However, one major challenge has persisted: controlling spin without the need for bulky magnetic fields. A breakthrough published in Materials Horizons provides a game-changing solution to this issue, bringing us one step closer to ultra-compact and energy-efficient spintronic devices.

 

https://www.sciencenewstoday.org/revolutionizing-spintronics-electric-field-control-eliminates-need-for-magnets

 

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DNA Origami Enables Fabricating Superconducting Nanowires

 

Fabricating nanoelectronic circuits of the future just got a lot more interesting, thanks to DNA origami

 

January 19, 2021

 

The following news release, issued by the American Institute of Physics (AIP) on Jan. 19, describes research published in AIP Advances on exploiting DNA origami as a platform to build wire-like nanostructures that can conduct electricity without resistance. Scientists from the U.S. Department of Energy’s (DOE) Brookhaven National Laboratory and collaborating institutions first reported this platform in Nature Communications last November. Oleg Gang, leader of the Soft and Bio Nanomaterials Group at Brookhaven Lab’s Center for Functional Nanomaterials—a DOE Office of Science User Facility—has been developing novel strategies using DNA to guide the self-assembly of nanoparticles in desired ways for particular applications. The new AIP study shows the potential of this platform for applications including interconnects for nanoelectronics and novel devices such as 3-D magnetometers for measuring magnetic fields.

 

WASHINGTON, January 19, 2021 — The quest for ever-smaller electronic components led an international group of researchers to explore using molecular building blocks to create them. DNA is able to self-assemble into arbitrary structures, but the challenge with using these structures for nanoelectronic circuits is the DNA strands must be converted into highly conductive wires.

 

Inspired by previous works using the DNA molecule as a template for superconducting nanowires, the group took advantage of a recent bioengineering advance known as DNA origami to fold DNA into arbitrary shapes.

 

In AIP Advances, from AIP Publishing, researchers from Bar-Ilan University, Ludwig-Maximilians-Universität München, Columbia University, and Brookhaven National Laboratory describe how to exploit DNA origami as a platform to build superconducting nanoarchitectures. The structures they built are addressable with nanometric precision that can be used as a template for 3D architectures that are not possible today via conventional fabrication techniques.

 

 The group’s fabrication process involves a multidisciplinary approach, namely the conversion of the DNA origami nanostructures into superconducting components. And the preparation process of DNA origami nanostructures involves two major components: a circular single-strand DNA as the scaffold, and a mix of complementary short strands acting as staples that determine the shape of the structure.

 

 

 

Transmission electron microscopy (TEM) image of DNA origami wires before the coating. 

https://www.bnl.gov/newsroom/news.php?a=117656



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Performing artificial intelligence using tiny nanomagnets that interact like neurons in the brain

 

May 5, 2022

 

(Nanowerk News) Researchers have shown it is possible to perform artificial intelligence using tiny nanomagnets that interact like neurons in the brain.

The new method, developed by a team led by Imperial College London researchers, could slash the energy cost of artificial intelligence (AI), which is currently doubling globally every 3.5 months.

In a paper published in Nature Nanotechnology ("Reconfigurable training and reservoir computing in an artificial spin-vortex ice via spin-wave fingerprinting"), the international team have produced the first proof that networks of nanomagnets can be used to perform AI-like processing. The researchers showed nanomagnets can be used for ‘time-series prediction’ tasks, such as predicting and regulating insulin levels in diabetic patients. 

 

https://www.nanowerk.com/nanotechnology-news2/newsid=60560.php

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MIT Physicists Detect Strange Hybrid Particle Held Together by Uniquely Intense “Glue”

 

January 11, 2022

 

 Researchers at MIT have identified a new hybrid particle in NiPS3, combining an electron and a phonon with exceptional bonding strength, paving the way for dual control over electronic and magnetic properties in materials.

 

In the particle world, sometimes two is better than one. Take, for instance, electron pairs. When two electrons are bound together, they can glide through a material without friction, giving the material special superconducting properties. Such paired electrons, or Cooper pairs, are a kind of hybrid particle — a composite of two particles that behave as one, with properties that are greater than the sum of its parts.

 

In a new, two-dimensional magnetic substance, MIT scientists have now discovered a different kind of hybrid particle. They discovered that the hybrid particle is a combination of an electron and a phonon (a quasiparticle created by the vibrating atoms of a substance). They discovered that the glue, or bond, between the electron and phonon was 10 times stronger than any previous electron-phonon hybrid up to that point.

 

Dual Control of Electronic and Magnetic Properties

 

The particle’s exceptional bond suggests that its electron and phonon might be tuned in tandem; for instance, any change to the electron should affect the phonon, and vice versa. In principle, an electronic excitation, such as voltage or light, applied to the hybrid particle could stimulate the electron as it normally would, and also affect the phonon, which influences a material’s structural or magnetic properties. Such dual control could enable scientists to apply voltage or light to a material to tune not just its electrical properties but also its magnetism.

 

Potential Applications in Magnetic Semiconductors

 

The results are especially relevant, as the team identified the hybrid particle in nickel phosphorus trisulfide (NiPS₃), a two-dimensional material that has attracted recent interest for its magnetic properties. If these properties could be manipulated, for instance through the newly detected hybrid particles, scientists believe the material could one day be useful as a new kind of magnetic semiconductor, which could be made into smaller, faster, and more energy-efficient electronics.

 

“Imagine if we could stimulate an electron, and have magnetism respond,” says Nuh Gedik, professor of physics at MIT. “Then you could make devices very different from how they work today.”

 

Gedik and his colleagues have published their results on January 10, 2022, in the journal Nature Communications. His co-authors include Emre Ergeçen, Batyr Ilyas, Dan Mao, Hoi Chun Po, Mehmet Burak Yilmaz, and Senthil Todadri at MIT, along with Junghyun Kim and Je-Geun Park of Seoul National University in Korea.

 

Exploring Two-dimensional Magnetic Materials

 

The field of modern condensed matter physics is focused, in part, on the search for interactions in matter at the nanoscale. Such interactions, between a material’s atoms, electrons, and other subatomic particles, can lead to surprising outcomes, such as superconductivity and other exotic phenomena. Physicists look for these interactions by condensing chemicals onto surfaces to synthesize sheets of two-dimensional materials, which could be made as thin as one atomic layer.

 

NiPS3 is a two-dimensional material that becomes antiferromagnetic at temperatures as low as 150 kelvin, or -123 degrees Celsius. In 2018, a research team in Korea found some unexpected interactions in sheets of NiPS3 that had been produced. An antiferromagnet’s microstructure is composed of atoms whose spins are directly opposed to those of their neighbors, much like a honeycomb lattice. A ferromagnetic substance, on the other hand, consists of atoms with their spins aligned in the same direction.

 

https://scitechdaily.com/mit-physicists-detect-strange-hybrid-particle-held-together-by-uniquely-intense-glue/

 

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Don't make an ion trap at home

2023 Apr 15

https://www.youtube.com/shorts/3HIWR0UfC8I 

 

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On the Edge: New Magnetic Phenomenon Discovered With Industrial Potential

 

May 15, 2022

 

Working with the tiniest magnets, Hebrew University discovers a new magnetic phenomenon with industrial potential.

 

For physicists, exploring the realm of the very, very small is a wonderland. Totally new and unexpected phenomena are discovered in the nanoscale, where materials as thin as 100 atoms are explored. Here, nature ceases to behave in a way that is predictable by the macroscopic law of physics, unlike what goes on in the world around us or out in the cosmos.

 

Dr. Yonathan Anahory at Hebrew University of Jerusalem (HU)’s Racah Institute of Physics led the team of researchers, which included HU doctoral student Avia Noah. He spoke of his astonishment when looking at images of the magnetism generated by nano-magnets, “it was the first time we saw a magnet behaving this way,” as he described the images that revealed the phenomenon of “edge magnetism.”

 
https://scitechdaily.com/on-the-edge-new-magnetic-phenomenon-discovered-with-industrial-potential/

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Scientists discover unusual ultrafast motion in layered magnetic materials

 August 1, 2023

 

https://physics.mit.edu/news/scientists-discover-unusual-ultrafast-motion-in-layered-magnetic-materials/

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MIT Discovers Magnetic Superconductor in Pencil Lead

 

June 3, 2025 

 

MIT scientists have identified a bizarre new material: a superconductor that also acts like a magnet. Using a special stacking of graphene layers from graphite, they observed this dual behavior — something thought to be impossible until now. 

 

https://scitechdaily.com/mit-discovers-magnetic-superconductor-in-pencil-lead/ 

 

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MIT Physicists Transform Pencil Lead Into Electronic “Gold”

 

November 5, 2023

 

Isolate thin flakes that can be tuned to exhibit three important properties.

 

MIT physicists have metaphorically turned graphite, or pencil lead, into gold by isolating five ultrathin flakes stacked in a specific order. The resulting material can then be tuned to exhibit three important properties never before seen in natural graphite.

“It is kind of like one-stop shopping,” says Long Ju, an assistant professor in the MIT Department of Physics and leader of the work, which is reported in the October 5 issue of Nature Nanotechnology. “Nature has plenty of surprises. In this case, we never realized that all of these interesting things are embedded in graphite.”

 

Further, he says, “It is very rare material to find materials that can host this many properties.”

 

The Rise of “Twistronics”

 

Graphite is composed of graphene, which is a single layer of carbon atoms arranged in hexagons resembling a honeycomb structure. Graphene, in turn, has been the focus of intense research since it was first isolated about 20 years ago. Then about five years ago researchers including a team at MIT discovered that stacking individual sheets of graphene, and twisting them at a slight angle to each other, can impart new properties to the material, from superconductivity to magnetism. The field of “twistronics” was born.

 

In the current work, “we discovered interesting properties with no twisting at all,” says Ju, who is also affiliated with the Materials Research Laboratory.

https://scitechdaily.com/mit-physicists-transform-pencil-lead-into-electronic-gold/

 

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For more information on magnets, energy and light view the chapter titled "Light energy."

 

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Chapter 17: Piezoelectric & mechanical energy 


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Energy harvesting

 

https://en.wikipedia.org/wiki/Energy_harvesting


Energy harvesting (also known as power harvesting or energy scavenging) is the process by which energy is derived from external sources (e.g. solar power, thermal energy, wind energy, salinity gradients, and kinetic energy), captured, and stored for small, wireless autonomous devices, like those used in wearable electronics and wireless sensor networks.

Energy harvesters provide a very small amount of power for low-energy electronics. While the input fuel to some large-scale generation costs money (oil, coal, etc.), the energy source for energy harvesters is present as ambient background and is free. For example, temperature gradients exist from the operation of a combustion engine and in urban areas, there is a large amount of electromagnetic energy in the environment because of radio and television broadcasting.

Piezoelectric

The piezoelectric effect converts mechanical strain into electric current or voltage. This strain can come from many different sources. Human motion, low-frequency seismic vibrations, and acoustic noise are everyday examples. Except in rare instances the piezoelectric effect operates in AC requiring time-varying inputs at mechanical resonance to be efficient.
Most piezoelectric electricity sources produce power on the order of milliwatts, too small for system application, but enough for hand-held devices such as some commercially available self-winding wristwatches. One proposal is that they are used for micro-scale devices, such as in a device harvesting micro-hydraulic energy. In this device, the flow of pressurized hydraulic fluid drives a reciprocating piston supported by three piezoelectric elements which convert the pressure fluctuations into an alternating current.

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Preparation on transparent flexible piezoelectric energy harvester based on PZT films by laser lift-off process

 

http://www.sciencedirect.com/science/article/pii/S0924424712006516

 

 The piezoelectric energy generation properties of transparent flexible devices (TFD) based on PbZr_0.52Ti_0.48O₃ (PZT) films, which were fabricated by laser lift-off (LLO) process, were studied for a piezoelectric energy harvester. Through the introduction of indium-tin-oxide (ITO) and polyethylene terephthalate (PET) substrates, TFDs were implemented, respectively. The TFDs based on PZT films generated an AC-type output signal and output power of 8.4 nW/cm², at periodically bending and releasing motion. In addition, inverted output signals were observed when the manufactured TFDs were connected to the measuring equipment in reverse and were bended to the reverse direction, demonstrating that the generating signals originated from the piezoelectric effect of TFDs. The experimental results clearly showed that the TFDs based PZT film have potential for use in next generation of electronic devices applications such as flexible devices, transparent electronics, and energy harvester.


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Scientists use shape-fixing nanoreactor to make a better fuel cell catalyst

 

May 11, 2015

 http://phys.org/news/2015-05-scientists-shape-fixing-nanoreactor-fuel-cell.html?utm_source=menu&utm_medium=link&utm_campaign=item-menu

 

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Laser-machined piezoelectric cantilevers for mechanical energy harvesting

 

 In this study, we report results on a piezoelectric- material-based mechanical energy-harvesting device that was fabricated by combining laser machining with microelectronics packaging technology. It was found that the laser-machining process did not have significant effect on the electrical properties of piezoelectric material. The fabricated device was tested in the low-frequency regime of 50 to 1000 Hz at constant force of 8 g (where g = 9.8 m/s²). The device was found to generate continuous power of 1.13 muW at 870 Hz across a 288.5 kOmega load with a power density of 301.3 muW/cm³.


 http://ieeexplore.ieee.org/xpl/login.jsp?tp=&arnumber=4626918&url=http%3A%2F%2Fieeexplore.ieee.org%2Fiel5%2F58%2F4626908%2F04626918.pdf%3Farnumber%3D4626918
 

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Bismuth-Ferrite Piezoelectric Material Opens New Roads for Energy Generation

November 15, 2009

 http://www.greenoptimistic.com/bismuth-ferrite-piezoelectric-material-opens-new-roads-for-energy-generation-20091115/#.VSIYCeG-2zk

 

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Chinese Scientists Find Alternative to Lead-Containing Mainstream Piezoelectric Material

 

April 2, 2012

 
http://www.greenoptimistic.com/zinc-oxide-vanadium-piezoelectric-20120402/#.VSIYEOG-2zk

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Energy-Saving Thermoelectric Material Made From Dirt

November 29, 2012

A team of researchers at Michigan State University have developed a new type of thermoelectric material by using common materials found in dirt. The researchers developed this material using what they know about tetrahedrites, one of the most abundant minerals on Earth.

MSU Professor of Chemical Engineering, Donald Morelli, and his team figured out how to synthesize compounds that have the same chemical composition as natural minerals and closely mimic tetrahedrites. By modifying the composition, researchers have been able produce even more efficient thermoelectric material.

Why is this important? Themoelectric energy needs to be more efficient to be a viable energy source. For example, if thermoelectric was more efficient, the heat generated by a car engine that travels through the tail pipe could then be converted into actual electricity. By tweaking the composition, researchers are coming closer to making this a reality.

 http://www.greenoptimistic.com/thermoelectric-material-dirt-20121129/

 

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Fungus turns wood piezoelectric, allowing it to power LEDs

 

09 Apr 2021 

 

 Infecting wood with wood-decay fungus can boost its piezoelectric output by 55 times, researchers in Switzerland have discovered. The material scientists found that after 10 weeks of infection, blocks of decayed wood could power LEDs. They say that floors built from fungus-treated wood could generate renewable electricity from people’s footsteps.

 

Decades ago, scientists discovered that wood generates an electrical charge under mechanical stress. This piezoelectric effect is caused by the displacement of crystalline cellulose when it is deformed, whereby shear stress in one plane produces an electrical polarization perpendicular to it. But the piezoelectric effect is not very strong – around twenty times smaller than that of a quartz crystal – and wood does not deform easily.

 

Despite this, some researchers are keen on exploiting this property by creating piezoelectric construction materials that could help make buildings more energy efficient. Globally buildings are responsible for around 40% of our energy consumption and nearly 25% of our greenhouse gas emissions. Current attempts to minimize emissions involve reducing energy consumption or fitting buildings with solar panels so they generate their own electricity. While this can be effective, it is weather dependent and does not work everywhere. Piezoelectric construction materials could offer another source of clean energy.

 

Dissolving lignin

 

The piezoelectrical performance of wood can be improved by changing its structure. Recently Ingo Burgert, at ETH Zurich, and his colleagues found that placing wood in a mixture of hydrogen peroxide and acetic acid increases its piezoelectric output. This process dissolves the lignin in the wood leaving behind a cellulose framework that is much more flexible and elastic. When squeezed, 1.5 cm cubes of this acid-treated wood generated an output of 0.69 V, which is 85 times higher than untreated wood. This performance was stable for 600 cycles and 30 connected blocks powered light-emitting diodes (LEDs) and a simple liquid-crystal display.

 

Keen to create the same effect, but without the harsh chemicals, Burgert and colleagues turned to a natural process that alters the structure of wood: decay by fungi. In their latest work, described in Science Advances, they infected balsa wood with the white rot fungus Ganoderma applanatum for 4–12 weeks. After 10 weeks the wood had lost 45% of its weight and the researchers found that at this point it showed the best compressibility performance, while still returning to its original shape once the stress was released.

 

A single 1.5 cm cube of this decayed wood produced a maximum voltage of 0.87 V under 45 kPa of stress, while uninfected balsa wood generated 0.015 V. The treated wood maintained its performance for 500 cycles. Electrical output increased with mechanical stress, rising to 1.32 V at 100 kPa. Nine of the decayed-wood blocks connected in parallel were able to power an LED, when pressed strongly.

 

Cellulose remains intact

 

Infrared spectroscopy and X-ray diffraction analysis of decayed and untreated wood showed how the fungus altered the wood. “The selected wood decay fungi secrete enzymes that enable degradation of lignin and hemicelluloses in the wood, whereas cellulose remains intact,” Burgert told Physics World. “This type of wood decay is also known as selective delignification. This process changes the structure and chemistry of the wood cell wall enhancing the natural piezoelectric properties of wood.”

 

The researchers say that their results indicate that the material could be used to produce large-scale wooden floors, such as those in ballrooms, that could generate electricity from human activity.

 

“We are currently working at the demonstrator scale with delignified wood that can be used for sensors integrated into wooden floors,” Burgert says. “For instance, these systems could be used as security systems in wooden floors for detection of any kind of applied stress. In terms of power generation, it is on the level of lighting up LED lights, and therefore, at present the application as a sensor is more suitable. However, it is a first step and we are currently optimizing towards wood-based systems better suited for energy harvesting.”

 

Due to its lignin composition delignification during fungal infection is much faster in balsa than other woods such as spruce, pine and fir. “The next step is to use this concept for native wood species and incorporate the generated materials in future smart buildings,” Burgert adds.

 
https://physicsworld.com/a/fungus-turns-wood-piezoelectric-allowing-it-to-power-leds/

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Proof-of-Concept Piezoelectric Generators Used to Recover Energy from Wind

 

November 24, 2009

 

http://www.greenoptimistic.com/andreopoulos-piezoelectric-wind-power-20091124/#.VSIbWOG-2zk

 
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 Scientists harvest energy from beam's self-induced, self-sustaining vibrations in airflow

July 27, 2015

http://phys.org/news/2015-07-scientists-harvest-energy-self-induced-self-sustaining.html#jCp

 

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Nanogenerator “Scavenges” Power from atmosphere

 

August 7, 2021

 

Australian researchers led by Flinders University are picking up the challenge of ‘scavenging’ invisible power from low-frequency vibrations in the surrounding environment, including wind, air, or even contact-separation energy (static electricity).

 

“These so-called triboelectric nanogenerators (or ‘TENGs’) can be made at low cost in different configurations, making them suitable for driving small electronics such as personal electronics (mobile phones), biomechanics devices (pacemakers), sensors (temperature/pressure/chemical sensors), and more,” says Professor Youhong Tang, from Flinders University’s College of Science and Engineering.

 

 https://nanodigest.in/nanogenerator-scavenges-power-from-atmosphere/

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How to squeeze electricity out of crystals - Ashwini Bharathula

  

September 23, 2024

 

It might sound like science fiction, but if you press on a crystal of sugar, it will actually generate its own electricity. This simple crystal can act like a tiny power source because sugar happens to be piezoelectric. Ashwini Bharathula explains how piezoelectric materials turn mechanical stress, like pressure, sound waves and other vibrations into electricity, and vice versa.

https://ed.ted.com/lessons/how-to-squeeze-electricity-out-of-crystals-ashwini-bharathula

 

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What Are Piezoelectric Crystals And How Do They Work?

 

September 23, 2024

 

We’ve found a lot of ways to make use of this strange property of certain crystals, but the most important effects were here long before us.

 

 What Is Piezoelectricity?

 

Certain substances, when placed under physical stress, develop imbalances of charges. Electrons accumulate in certain parts, creating a negative electric potential; while other areas are depleted in electrons, and so form a positive potential.

 

Quartz, the most common material to display piezoelectricity, is so abundant that it’s likely many people have noticed that when squeezed it can become able to attract charged objects. Of course, quartz is not easy to squeeze, which may be why there is no record of these observations before Pierre Curie and his brother Jacques published research on it in 1880. 

 

The Curies showed that certain crystals become electrically polarized when stressed, and the field strength is proportional to the force applied. The name comes from the ancient Greek word piézō, “to squeeze”. For Jacques, this was the highlight of his scientific career, whereas Pierre went on to be far more famous for many other things. 

 

At a time when our understanding of electricity was in its infancy, and only a few practical applications had been developed, the discovery helped build excitement in the general phenomenon but was initially just a curiosity itself.

 

When an electric field is applied to a piezoelectric material, it will deform, a phenomenon known as the converse piezoelectric effect. The change is usually tiny – perhaps one part in a thousand – but that’s enough for some practical applications.

 

Why Are A Few Things Piezoelectric But Most Aren’t?

 

Piezoelectricity was initially observed in crystals. The Curies tried squeezing all sorts of crystalline materials to see which ones proved piezoelectric and to find the strongest effect. Along with Rochelle salt, a form of tartaric acid and quartz were their star examples.

 

Despite the limited knowledge available at the time about the way atoms lined up in crystals, the brothers were able to deduce that the common feature of the piezoelectric crystals related to their axes of symmetry. Piezoelectric behavior requires a crystal to have a polar bond, where some atoms hold onto their electrons more tightly than others. They also must lack inversion symmetry, that is they are not the same when components are placed on the opposites side of a center of symmetry,

 

Although more classes of crystal are piezoelectric than not, those that show strong piezoelectric effects are rare in nature, quartz is the only one that is common.

 

In piezoelectric crystals, the pressure causes electric dipoles to line up, rather than be arranged randomly, so that their cumulative effect produces a field.

 

We have since learned that piezoelectricity is not confined to crystals. Ferroelectric ceramics (those that electrically polarize in ways that resist reversal from external fields) with randomly orientated grains can be piezoelectric. That includes the class of materials known as perovskites that probably represent the future of solar energy. 

 

Some polymers also show weak piezoelectric behavior because electric charges build up around voids within the material, and become concentrated when the voids are deformed. The big surprise in this area came by chance when piezoelectric liquids were discovered, shocking researchers both literally and intellectually.

 

Why Does Piezoelectricity Matter? 

 

Piezoelectricity has found many applications. In most substances, the piezoelectric effect is so weak that it is too difficult to harness to bother. There are exceptions, however – suitable pressure on quartz crystals can produce electrical potential differences of thousands of volts, without the need to carry around an impractically large device.

 

The surge of electricity generated by sudden pressure on a quartz crystal can produce sparks that jump a gap, and is the basis of cigarette lighters and ignition devices for gas heaters and stoves.

 

On the other hand, by varying the electric fields around piezoelectric crystals, the converse effect can make metal plates glued to the crystals vibrate very rapidly. When performed thousands of times a second these vibrations were used to produce the first sonar, which mapped the ocean floor and detected submarines. A similar approach made it possible to produce lighter radio transmitters, allowing planes to communicate with each other while in flight during World War II.

 

A recent paper reveals that quartz’s piezoelectric properties may be why gold settles in quartz veins and forms concentrated nuggets. The economic effects of these nuggets – and the way their presence has made empires rise and fall – mean that, if this is true, natural piezoelectricity may have shaped our history more than any application humans designed.

 

There are probably even more important piezoelectric effects, but we don’t yet fully understand them. Many body parts, such as bones, are piezoelectric, and it is thought they use this to grow. It may be why bones atrophy in orbit, for example; the stresses created in Earth gravity keep them regenerating through piezoelectricity.

 

Piezoelectricity has fascinated enough scientists that some see potential for more world-changing applications. For example, ideas to underlay roads with piezoelectric materials and produce large amounts of power from cars driving over the top, or electricity-producing shoes draw publicity now and then. However, these reports usually fail to consider the inefficiency of the approach, even before one gets to the enormous cost. More modest versions serve as marketing devices, such as nightclubs that power the lights from people dancing on a piezoelectric floor.

 
https://www.iflscience.com/what-are-piezoelectric-crystals-and-how-do-they-work-76057

 

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Did You Know That Hitting Crystals Can Make Electricity? This Is How ‘Piezoelectricity’ Works

 

December 11, 2021

 

Cell phones, diesel fuel injectors, acoustic guitar pickups, grill igniters, ultrasonic transducers, vibration sensors, some printers, and musical greeting cards all have something in common. And that is: all of these applications, aside from being electronic devices, make use of piezoelectricity in some way.

 

If you are not aware of what Piezoelectricity actually is, then don’t worry, we have the answer. As per the definition on Wikipedia, Piezoelectricity is the electric charge that builds up in certain solid materials, such as crystals and ceramics, as well as biological matter like bone, DNA, and different proteins, in reaction to mechanical stress. The term piezoelectricity refers to the generation of electricity from pressure and latent heat. It comes from the Greek words piezein, which means squeeze or press, and lektron, which refers to amber, an early source of electric charge.

 
https://wonderfulengineering.com/did-you-know-that-hitting-crystals-can-make-electricity-this-is-how-piezoelectricity-works/

 

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New Piezo Crystals Harness Sound Waves to Generate Hydrogen Fuel

 03/17/10

http://inhabitat.com/new-piezo-crystals-harness-sound-waves-to-generate-hydrogen-fuel/


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Nano-Rogues: From Mythic Ocean Waves to Micro-Manufacturing Marvels

October 24, 2023

 

Scientists have adapted the principles of large, unexpected oceanic rogue waves to a nanoscale, revealing potential applications in nano-manufacturing and medical insights, supported by mathematical models inspired by quantum physics.

 

Researchers have shown how the principles of rogue waves – huge 30-meter waves that arise unexpectedly in the ocean – can be applied on a nanoscale, with dozens of applications from medicine to manufacturing.

 

Long considered to be a myth, rogue waves strike from comparably calm surroundings, smashing oil rigs and ships in their path. Unlike tsunamis, rogue waves form by the chance combination of smaller waves in the ocean, creating an event that is very rare.

 

Nanoscale Application of Rogue Wave Principles

 

There has been a lot of research into rogue waves in recent years but now, for the first time, scientists are showing how this can be applied on a much smaller scale – nanometrically. A nanometer is a million times smaller than the thickness of the page of a book. This is a completely new approach to the behavior of liquids on a nanometric scale, published as a Letter in Physical Review Fluids.

 

The holes and bumps caused by rogue waves can be manipulated to spontaneously produce patterns and structures for use in nano-manufacturing (manufacturing on a scale one-billionth of a meter). For example, patterns formed that rupture liquid films can be used to build microelectronic circuits, which could be used in the production of low-cost components of solar cells. Furthermore, the behavior of thin liquid layers could help to explain why millions of people worldwide suffer from dry eye. This occurs when the tear film covering the eye ruptures.

 

Uncovering the Behavior of Nanoscopic Liquid Layers

 

Through direct simulations of molecules and new mathematical models, the study led by the University of Warwick’s Mathematics Institute discovered how nanoscopic layers of liquid behave in counterintuitive ways. While a layer of spilled coffee on a table may sit apparently motionless, at the nanoscale the chaotic motion of molecules creates random waves on a liquid’s surface. A rare event occurs when these waves conspire to create a large ‘rogue nanowave’ that bursts through the layer and creates a hole. The new theory explains both how and when this hole is formed, giving new insight into a previously unpredictable effect, by taking their large oceanic cousins as a mathematical blueprint.

 

The team of researchers is excited about the potential of this research in different industries; the applications are far-reaching.

 
https://scitechdaily.com/nano-rogues-from-mythic-ocean-waves-to-micro-manufacturing-marvels/

 
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Fuel-free nanomotor is powered by ultrasound and magnetic fields

 

Jun 26, 2015 

 

 Nanoscale motors, like their macroscale counterparts, can be built to run on a variety of chemical fuels, such as hydrogen peroxide and others. But unlike macroscale motors, some nanomotors can also run without fuel, instead being powered by either magnetic or acoustic fields. In a new paper, researchers for the first time have demonstrated a nanomotor that can run on both magnetic and acoustic fields, making it the first magneto-acoustic hybrid fuel-free nanomotor.



 http://phys.org/news/2015-06-fuel-free-nanomotor-powered-ultrasound-magnetic.html?utm_source=menu&utm_medium=link&utm_campaign=item-menu

 
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Sonic Breakthrough: MIT Unlocks Ultrasound Control With Advanced Metamaterials

 

 December 14, 2024

 

Researchers at MIT have developed a design framework for controlling ultrasound wave propagation in microscale acoustic metamaterials, focusing on the precise positioning of microscale spheres within a lattice.

 

This approach enables tunable wave velocities and responses, and is applicable in fields like ultrasound imaging and mechanical computing.

https://scitechdaily.com/sonic-breakthrough-mit-unlocks-ultrasound-control-with-advanced-metamaterials/

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Tiny Motors Take a Big Step Forward: First-Ever Solid-State Optical Nanomotor

7/17/2022

 

Motors are ubiquitous in our everyday lives — from cars to washing machines, even if we rarely notice them. A futuristic scientific field is working on the development tiny motors that could power a network of nanomachines and replace some of the power sources we currently use in electronic devices.

 

Researchers from the Cockrell School of Engineering at The University of Texas at Austin created the first ever solid-state optical nanomotor. All previous iterations of these light-driven motors reside in a solution of some sort, which limited their potential for the majority of real-world applications.

 

One of the biggest hurdles holding back implementation of these devices is Brownian Motion, which is avoided by bringing these nanomotors on land and out of water, so to speak. Brownian Motion happens when water molecules push these little motors off their spin. The smaller the motor, the stronger effect this motion has. Removing the solution from the equation side steps this problem entirely.

 

The reason scientists are so enamored with creating these tiny motors is that they mimic some of the most important biological structures. In nature, these motors drive the division of cells and help them move. They combine to help organisms move.

https://us.headtopics.com/news/tiny-motors-take-a-big-step-forward-first-ever-solid-state-optical-nanomotor-28186808

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Ear-Piercing Sounds Harvested for Energy

 

Dec 6, 2013

 

http://news.discovery.com/tech/alternative-power-sources/ear-piercing-sounds-harvested-for-energy-131206.htm

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Engineering students use sound waves to put out fires

 

Mar 26, 2015

 

 http://phys.org/news/2015-03-students.html

 

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Advancement in piezoelectric nanogenerators for acoustic energy harvesting

 

18 December 2024

 

https://www.nature.com/articles/s41378-024-00811-4 

 

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German student creates electromagnetic harvester that gathers free electricity from thin air

February 12, 2013 


 A German student has built an electromagnetic harvester that recharges an AA battery by soaking up ambient, environmental radiation. These harvesters can gather free electricity from just about anything, including overhead power lines, coffee machines, refrigerators, or even the emissions from your WiFi router or smartphone.
 

http://www.extremetech.com/extreme/148247-german-student-creates-electromagnetic-harvester-that-gathers-free-electricity-from-thin-air


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New technique for generating electricity from mechanical vibrations

 

Nov 12, 2014

http://www.gizmag.com/mechanical-vibration-generate-electricity/34701/


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New Cell Phone Charging System Harvests Energy from Vibrations

02/28/14

 http://inhabitat.com/university-of-wisconsin-develops-cell-phone-charging-system-that-harvests-energy-from-vibrations/


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Pavegen looking to harness energy from pedestrian footsteps

 

May 28th, 2015

 http://phys.org/news/2015-05-pavegen-harness-energy-pedestrian-footsteps.html#nRlv

 

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Portland to generate electricity within its own water pipes

 February 17, 2015

 http://www.gizmag.com/portland-lucidpipe-power-system/36130/

 

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Shape-shifting nanoprobes report on internal body conditions using magnetic fields

 

April 5, 2015

 Scientists at the National Institute of Standards and Technology (NIST) and the National Institutes of Health (NIH) have developed a new type of shape-shifting nanoprobe that can perform high-resolution remote biological sensing not possible with current technology. Around one-tenth the size of a single red blood cell, the nanoprobes are designed to provide feedback on internal body conditions by altering their magnetic fields in response to their environment. The researchers predict wide-spread applications for the nanoprobes in the fields of chemistry, biology, engineering and, one day, to aid physicians in high-accuracy clinical diagnostics.

http://www.gizmag.com/nanoprobes-nist-gem-biosensing-magnetic-fields/36803/


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Study Confirms Magnetic Properties of Silicon Nano-Ribbons

 

October 24, 2012

 

http://www.bangscience.org/2012/10/study-confirms-magnetic-properties-of-silicon-nano-ribbons/

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Heat makes electrons spin in magnetic superconductors

 

4/24/2015


http://article.wn.com/view/2015/04/24/Heat_makes_electrons_spin_in_magnetic_superconductors_Univer/

 

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 Scientists fabricate hexagonal silicon, potentially leading to light-emitting semiconductors

 

August 18, 2015

 Virtually all semiconductors used in today's electronic devices are made of silicon having a cubic crystal structure, as silicon naturally crystallizes in the cubic form. In a new study, researchers have fabricated silicon in a hexagonal crystal structure, which is expected to exhibit novel optical, electrical, superconducting, and mechanical properties compared with cubic silicon.
 

http://phys.org/news/2015-08-scientists-fabricate-hexagonal-silicon-potentially.html#jCp

 

 
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Device harvests energy from low-frequency vibrations

August 29, 2018

 

UNIVERSITY PARK, Pa. — A wearable energy-harvesting device could generate energy from the swing of an arm while walking or jogging, according to a team of researchers from Penn State's Materials Research Institute and the University of Utah. The device, about the size of a wristwatch, produces enough power to run a personal health monitoring system. 

https://www.psu.edu/news/research/story/device-harvests-energy-low-frequency-vibrations

 

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Researchers prove magnetism can control heat, sound

 

May 28th, 2015

 http://phys.org/news/2015-05-magnetism.html

 

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Ultrafast heat conduction can manipulate nanoscale magnets

 

 June/8/2015

 Researchers at the University of Illinois at Urbana-Champaign have uncovered physical mechanisms allowing the manipulation of magnetic information with heat. These new phenomena rely on the transport of thermal energy, in contrast to the conventional application of magnetic fields, providing a new, and highly desirable way to manipulate magnetization at the nanoscale.

http://phys.org/news/2015-06-ultrafast-nanoscale-magnets.html#jCp

 

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Magnetostrictive resonators as sensors and actuators

http://www.sciencedirect.com/science/article/pii/S0924424712007509

Two types of magnetostrictive resonators – magnetostrictive microcantilever (MSMC) and magnetostrictive particle (MSP) – have been introduced as sensor platforms. Their principles and advantages as sensor platforms are discussed along with the materials selection. A detailed and complete comparison between the MSMC and MSP is given. It is concluded that for the resonators with the same size, an MSP exhibits a higher sensitivity and has a much higher resonant frequency. For the resonators with the same resonant frequency, MSMCs exhibit a much higher sensitivity and have a much smaller size than MSPs. Using antibody as the sensing element, MSP biosensors for in situ detection of Escherichia coli and Listeria monocytogenes are developed and characterized. These biosensors exhibit a high performance. For example, the MSP-antibody biosensors of 1 mm × 0.3 mm × 15 μm exhibit a detection limit less than 100 cfu/ml for in situ detection of bacterial cell in water. A new type actuator is introduced using MSPs. The MSP actuator is operated using AC magnetic field with a frequency close to, but different than, its resonant frequency. The MSP actuator exhibits an unlimited displacement, and its moving direction is controlled by the operating frequency used.




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Levitating Magnet May Yield New Approach to Clean Energy

 

http://engineering.columbia.edu/levitating-magnet-may-yield-new-approach-clean-energy

 

 Achieving nuclear fusion in the laboratory has been a cherished goal of physicists and energy researchers for more than 50 years. That’s because it offers the possibility of nearly endless supplies of energy with no carbon emissions and far less radioactive waste than that produced by today’s nuclear plants, which are based on fission, the splitting of atoms (the opposite of fusion, which involves fusing two atoms together). But developing a fusion reactor that produces a net output of energy has proved to be more challenging than initially thought.

 

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Anti-Gravity Transport of Water Droplets: Material Channels Mechanical Energy in a Preferred Direction

July 5, 2023

 

A research group led by scientists from the RIKEN Center for Emergent Matter Science have developed a unique material, based on nanofillers embedded in a hydrogel, that can channel mechanical energy in one direction but not the other, acting in a “nonreciprocal” way. Using the composite material—which can be constructed at various sizes—the team was able to use vibrational, up-and-down movements, to make liquid droplets rise within a material. Using the material could thus make it possible to use random vibration usefully to move matter in a preferred direction. 

 

https://scitechdaily.com/anti-gravity-transport-of-water-droplets-material-channels-mechanical-energy-in-a-preferred-direction/

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Cleaner Fuel Cells on the Way from Moscow

 

 January 1, 2016

 A European research team has been working on ion-exchange membranes that convert energy created by chemical reactions. These membranes are based on amphiphilic compounds, and are synthetic. This has great implications for the use of clean fuel cells.
The team, comprised of Russian, French and German scientists, have been collaborating to create this process that can be possibly used in fuel cells. The study was conducted at the Moscow Institute of Physics and Technology, at the Laboratory of Functional Organic and Hybrid materials.
Batteries produce energy by utilizing the reaction of oxidizing and reducing agents. The batteries’ lifespan is complete when both the agents are consumed. When an accumulator is used, electric energy can be stored in packets.


 http://www.greenoptimistic.com/moscow-clean-fuel-cells/

 

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Scientists Discover Smart Way to Generate Energy with Tiny Beads

11/03/2025

 

 
An international team of researchers from the Department of Chemical Engineering at Vrije Universiteit Brussel, Riga Technical University, the Royal Melbourne Institute of Technology, and the MESA+ Institute at the University of Twente has discovered a new method to generate electricity using small plastic beads. By placing these beads close together and bringing them into contact, they generate more electricity than usual. This process, known as triboelectrification, is similar to the static electricity produced when rubbing a balloon against hair.

https://chemicalengineering.research.vub.be/scientists-discover-smart-way-to-generate-energy-with-tiny-beads

 

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Atomic Eavesdropping: How Carbyne Talks Through Quantum Vibrations

 

May 31, 2025

 

Researchers revealed a bizarre quantum link between carbyne and carbon nanotubes—two materials that shouldn’t “talk” but somehow do. The discovery could reshape how we design ultra-sensitive nano-devices.

 

https://scitechdaily.com/atomic-eavesdropping-how-carbyne-talks-through-quantum-vibrations/

 

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Physicists Caught Two Atoms ‘Talking’ to Each Other

 

May 27, 2021

 

A team of physicists in the Netherlands and Germany recently placed a bunch of titanium atoms under a scanning tunneling microscope. Those atoms were in constant, quiet interaction with each other through the directions of their spins. In a clever feat, the researchers were able to home in on a single pair of atoms, zapping one with an electric current in order to flip its spin. They then measured the reaction of its partner. 

https://gizmodo.com/physicists-caught-two-atoms-talking-to-each-other-1846967872

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'Electron shower' technique unlocks advanced piezoelectric films for next-generation electronics

June 5, 2025

 

 

Argon plasma in the vacuum chamber during magnetron sputtering, with the substrate in the center of the photograph.

https://phys.org/news/2025-06-electron-shower-technique-advanced-piezoelectric.html

 

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Biofuel Cell: Wearable Device Turns the Touch of Finger Into a Source of Power

July 26, 2021

A new wearable device turns the touch of a finger into a source of power for small electronics and sensors. Engineers at the University of California San Diego developed a thin, flexible strip that can be worn on a fingertip and generate small amounts of electricity when a person’s finger sweats or presses on it.

What’s special about this sweat-fueled device is that it generates power even while the wearer is asleep or sitting still. This is potentially a big deal for the field of wearables because researchers have now figured out how to harness the energy that can be extracted from human sweat even when a person is not moving.

https://fuelcellsworks.com/news/biofuel-cell-wearable-device-turns-the-touch-of-a-finger-into-a-source-of-power

 

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Energy harvesting goes organic, gets more flexible: Self-assembled peptides, when aligned, show great promise for electricity generation

 

15th, Sep 2020 

 

The race is on to create natural biocompatible piezoelectric materials for energy harvesting, electronic sensing, and stimulating nerves. A group of researchers has explored peptide-based nanotubes and reports using a combination of ultraviolet and ozone exposure to generate a wettability difference and an applied field to create horizontally aligned polarization of nanotubes on flexible substrates with interlocking electrodes. The work will enable the use of organic materials more widely.

 

https://statnano.com/world-news/82410/Energy-harvesting-goes-organic-gets-more-flexible-Self-assembled-peptides-when-aligned-show-great-promise-for-electricity-generation

 

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Flexible piezoelectrics: integration of sensing, actuating and energy harvesting

 

14 June 2025

 

https://www.nature.com/articles/s41528-025-00432-5

 

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Designing transparent piezoelectric metasurfaces for adaptive optics

 

27 January 2024

 

https://www.nature.com/articles/s41467-024-45088-3 

 

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Piezoelectric actuation for integrated photonics

 

14 May 2024 

 

https://arxiv.org/html/2405.08836v1

 

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Scientists Twist Chemistry’s Rules with New Mechanically Chiral Molecule

April 29, 2025

 

In the invisible world of molecules, some structures are less like rigid statues and more like acrobatic performers—twisting, turning, interlocking, and responding to subtle nudges from their environment. Among the most dazzling of these molecular contortionists are catenanes, a class of organic compounds whose key feature isn’t just how they’re built, but how they’re mechanically entwined. Like a pair of Olympic gymnasts permanently linked at the wrists, these molecules are composed of interlocked rings that can’t be pulled apart unless their covalent bonds are broken—a task requiring deliberate chemical intervention.

These ring-shaped structures don’t merely coexist; they are mechanically interlocked, meaning their very existence as a single entity depends on their entanglement. But now, researchers are delving deeper than ever before—not just into how these catenanes hold together, but how their dynamic structure can generate chirality—a mirror-image asymmetry that has profound implications across chemistry and biology.

https://www.sciencenewstoday.org/scientists-twist-chemistrys-rules-with-new-mechanically-chiral-molecule

 

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A generalized approach on bending and stress analysis of beams with piezoelectric material bonded

 

2019

 

https://www.sciencedirect.com/science/article/abs/pii/S0924424719300019 

 

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Laminated piezoelectric beam element for dynamic analysis of piezolaminated smart beams and GA-based LQR active vibration control

 

2020

 

https://www.sciencedirect.com/science/article/abs/pii/S0263822319348755 

 

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Performance of piezoelectric beam type energy harvester under flow-induced vibration

 

18 April 2025 

  

https://www.nature.com/articles/s41598-025-98147-0 

 

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Design method for piezoelectric cantilever beam structure under low frequency condition

 

 2017

 

https://www.sciencedirect.com/science/article/pii/S1996681416301912

 

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Fast Steering Mirrors

 

For Laser Beam Steering - Tip/Tilt Platforms, Piezo & Voice Coil-Driven

 

PI's ultra-fast steering mirrors, mirror platforms and dither scanners are based on frictionless flexure guides and high-speed solid-state piezoelectric drives. These compact 2-axis scan mirrors integrate pitch and roll motion into one device with a single moving mirror or optic. They are faster than galvo-scanners and voice-coil beam steering systems (also available from PI) and can be used in both static and highly dynamic operation (e.g. scanning, tracking, image resolution enhancement, drift/vibration cancellation).

 

https://www.pi-usa.us/en/products/fast-steering-mirrors-fsm-and-piezo-tiptilt-platforms-for-active-optics 

 

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High-Speed Piezoelectric MEMS Laser Tracking System for Different Intensity Illuminations

 

16 June 2025 

 

https://ieeexplore.ieee.org/document/11037358 

 

____________________________________

 

Femtosecond-Laser-Enabled Geometric Microengineering of PZT Films for Boosted Piezoelectric Response and Rainfall Monitoring Demonstration

 

November 20, 2024

 

https://pubs.acs.org/doi/10.1021/acsami.4c15162

 

____________________________________

 

 

Pulsed-Laser-Triggered Piezoelectric Photocatalytic CO₂ Reduction over Tetragonal BaTiO₃ Nanocubes

  

02 August 2023

 

Abstract

 

The recombination of photoinduced carriers in photocatalysts is considered one of the biggest barriers to the increase of photocatalytic efficiency. Piezoelectric photocatalysts open a new route to realize rapid carrier separation by mechanically distorting the lattice of piezoelectric nanocrystals to form a piezoelectric potential within the nanocrystals, generally requiring external force (e.g., ultrasonic radiation, mechanical stirring, and ball milling). In this study, a low-power UV pulsed laser (PL) (3 W, 355 nm) as a UV light source can trigger piezoelectric photocatalytic CO₂ reduction of tetragonal BaTiO₃ (BTO-T) in the absence of an applied force. The tremendous transient light pressure (5.7 × 10⁷ Pa, 2.7 W) of 355 nm PL not only bends the energy band of BTO-T, thus allowing reactions that cannot theoretically occur to take place, but also induces a pulsed built-in electric field to determine an efficient photoinduced carrier separation. On that basis, the PL-triggered piezoelectric photocatalytic CO₂ reduction realizes the highest reported performance, reaching a millimole level CO yield of 52.9 mmol g⁻¹ h⁻¹ and achieving efficient photocatalytic CO₂ reduction in the continuous catalytic system. The method in this study is promising to contribute to the design of efficient piezoelectric photocatalytic reactions.

 

https://advanced.onlinelibrary.wiley.com/doi/10.1002/adma.202305257?af=R 

 

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Chapter 18: Lazers


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____________________________________

 

 

 

 

 

 

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From Sci-Fi to Reality: Laser-Powered Sails Are Changing the Future of Space Travel

February 9, 2025

 
https://scitechdaily.com/from-sci-fi-to-reality-laser-powered-sails-are-changing-the-future-of-space-travel/

____________________________________

Laser propulsion

 http://en.wikipedia.org/wiki/Laser_propulsion


____________________________________ 

Laser Travel by Photonic Thruster

 

October 21, 2013



 http://www.centauri-dreams.org/?p=29341

 

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Blue Light and Sunshine May be the Next Gen Weapons Against Antibiotic-Resistant Infections

 

March 14, 2014

 

http://articles.mercola.com/sites/articles/archive/2013/03/14/blue-light-therapy.aspx

 

Skin and soft tissue infections are among the most common bacterial infections encountered in clinical practice.
Such infections can be caused by a number of bacteria that gain entrance into your body via cuts, scrapes, bites or open wounds. Even bacteria that normally live on your skin can cause an infection when introduced into your body this way.
Skin and soft tissue infections account for more than 14 million hospital visits each year, costing the health care system an estimated $24 billion.
Unfortunately, many infections are becoming increasingly difficult to treat. Antibiotic overuse has led to the emergence of antibiotic-resistant bacteria, such as methicillin-resistant Staphylococcus aureus, also known as MRSA.
Finding effective countermeasures to this growing public health threat has turned out few options, but the remedy may be as simple as colored light.
According to a new proof-of-principle study,¹ blue light can selectively eliminate infections caused by Pseudomonas aeruginosa. According to lead researcher Michael R. Hamblin of the Massachusetts General Hospital:²

 

"Microbes replicate very rapidly, and a mutation that helps a microbe survive in the presence of an antibiotic drug will quickly predominate throughout the microbial population. Recently, a dangerous new enzyme, NDM-1, that makes some bacteria resistant to almost all antibiotics available has been found in the United States. Many physicians are concerned that several infections soon may be untreatable.

Blue light is a potential non-toxic, non-antibiotic approach for treating skin and soft tissue infections, especially those caused by antibiotic resistant pathogens."

 

Could Blue Light Replace Antibiotics?

 

In the study, lab animals were infected with P. aeruginosa. Incredibly, ALL of the animals treated with blue light survived, while 82 percent of the controls died. Could this possibly be the beginning of a whole new treatment paradigm for infections? Clearly, we’re nearing the end of the road of the antibiotic era, as antibiotic-resistance spreads.
Blue light therapy has also been shown to be effective against MRSA and other resistant bugs, offering new hope for effective treatments.
In a previous study published in 2009,³ over 90 percent of community acquired and hospital acquired strains of MRSA were successfully eradicated within mere minutes of exposure to blue light. According to the authors:

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In plasmonics, 'optical losses' could bring practical gain

 

January 26, 2016

 What researchers had thought of as a barrier to developing advanced technologies based on the emerging field of plasmonics is now seen as a potential pathway to practical applications in areas from cancer therapy to nanomanufacturing.

Plasmonic materials contain features, patterns or elements that enable unprecedented control of light by harnessing clouds of electrons called surface plasmons. It could allow the miniaturization of optical technologies, bringing advances such as nano-resolution imaging and computer chips that process and transmit data using light instead of electrons, representing a potential leap in performance.

However, the development of advanced optical technologies using plasmonics has been hampered because components under development cause too much light to be lost and converted into heat. But now researchers are finding that this "loss-induced plasmonic heating" could be key to development of various advanced technologies, said Vladimir M. Shalaev, co-director of the new Purdue Quantum Center, scientific director of nanophotonics at the Birck Nanotechnology Center in the university's Discovery Park and a distinguished professor of electrical and computer engineering.

 http://phys.org/news/2016-01-plasmonics-optical-losses-gain.html


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ESA's Proba-V infrared sensor has a future in medicine and industry

March 12, 2015

http://www.gizmag.com/esa-proba-v-infrared-sensor-terrestrial-uses/36518/

 


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Low level laser therapy

 Low-level laser therapy (LLLT) is a form of laser medicine used in physical therapy and veterinary treatment that uses low-level (low-power) lasers or light-emitting diodes to alter cellular function. Other names for the therapy include low-power laser, soft laser, cold laser, biostimulation laser, therapeutic laser, and laser acupuncture.^[1] Whereas high-power lasers ablate tissue, low-power lasers are claimed to stimulate it and to encourage the cells to function.
 

http://en.wikipedia.org/wiki/Low_level_laser_therapy

 

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Veterinary Use of Laser Therapy Expands

 

April 05, 2011

http://healthypets.mercola.com/sites/healthypets/archive/2011/04/05/veterinary-use-of-laser-therapy-for-pets-expands.aspx

Laser therapy works in a number of ways to heal injuries and manage pain. Among them:

• It increases the release of endorphins (natural painkillers).
• Laser therapy decreases inflammation, which helps return tissue to a normal state.
• It restores metabolic function.

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History of Cold Laser Therapy

 

http://www.spine-health.com/treatment/pain-management/history-cold-laser-therapy

 Cold Laser Therapy has been used in clinical practice all around the world for over four decades. In 1916, Albert Einstein conceived the theory of Light Amplification through Stimulated Emission of Radiation or LASER. In 1967, Professor Andre Mester began using low power lasers in medicine. Dr. Mester is recognized by many as the grandfather of laser therapy.


The first experimental FDA clearance of Class 3B Lasers occurred in February of 2002, after a successful study for carpal tunnel syndrome on workers at General Motors. The laser that was used had a power of 90mw at 830nm.

Certain low level laser devices are also FDA approved for relief of the following conditions^3,4:

• Muscle and joint pain
• Stiffness associated with arthritis
• Pain associated with muscle spasms
• Hand pain and wrist pain associated with Carpal Tunnel Syndrome
• Neck pain
• Lower back pain
• Wound healing

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Cold Laser Therapy Advantages and Disadvantages

 

http://www.spine-health.com/treatment/pain-management/cold-laser-therapy-advantages-and-disadvantages

 

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Laser Light Could Make Flu Vaccine 7 Times More Effective

July 29, 2014

http://www.popsci.com/article/science/laser-light-could-make-flu-vaccine-7-times-more-effective

 

____________________________________

Laser medicine

 

http://en.wikipedia.org/wiki/Laser_medicine

 

____________________________________

Near-Infrared Laser Adjuvant for Influenza Vaccine

 

http://journals.plos.org/plosone/article?id=10.1371/journal.pone.0082899

 

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Laser vaccine adjuvants

• Received: 14 Feb 2014
• Accepted: 9 Apr 2014
• Published online: 29 Apr 2014

 

Immunologic adjuvants are essential for current vaccines to maximize their efficacy. Unfortunately, few have been found to be sufficiently effective and safe for regulatory authorities to permit their use in vaccines for humans and none have been approved for use with intradermal vaccines. The development of new adjuvants with the potential to be both efficacious and safe constitutes a significant need in modern vaccine practice. The use of non-damaging laser light represents a markedly different approach to enhancing immune responses to a vaccine antigen, particularly with intradermal vaccination. This approach, which was initially explored in Russia and further developed in the US, appears to significantly improve responses to both prophylactic and therapeutic vaccines administered to the laser-exposed tissue, particularly the skin. Although different types of lasers have been used for this purpose and the precise molecular mechanism(s) of action remain unknown, several approaches appear to modulate dendritic cell trafficking and/or activation at the irradiation site via the release of specific signaling molecules from epithelial cells. The most recent study, performed by the authors of this review, utilized a continuous wave near-infrared laser that may open the path for the development of a safe, effective, low-cost, simple-to-use laser vaccine adjuvant that could be used in lieu of conventional adjuvants, particularly with intradermal vaccines. In this review, we summarize the initial Russian studies that have given rise to this approach and comment upon recent advances in the use of non-tissue damaging lasers as novel physical adjuvants for vaccines.

 http://www.tandfonline.com/doi/abs/10.4161/hv.28840?journalCode=khvi20#preview

 

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ESA's Proba-V infrared sensor has a future in medicine and industry

 

http://www.gizmag.com/esa-proba-v-infrared-sensor-terrestrial-uses/36518/

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Discover the Benefits of K-Laser Class 4 Laser Therapy Treatments

 

 

 

 July 28, 2013

                                                                    

 

What You Need to Know About Lasers 

 

Lasers are classified according to their power output:

 

• Class 3a—maximum of 5 milliwatts of power (standard laser pointer)
• Class 3b—maximum of 500 milliwatts/0.5 watts
• Class 4—anything over 500 milliwatts/0.5 watts

 

The most significant issue with the clinical use of lasers is the depth of penetration. Some practitioners make the mistake of using low-power Class 3 lasers, which basically amounts to a standard laser pointer.
Most class 3a lasers only use a red wavelength – 635 nanometers in the visible red. When you look at the depth of penetration with laser, red laser light only penetrates about one to two millimeters (far less than 1/8 inch) into the human body.
Granted, red laser is highly useful for treating superficial wounds, cuts, abrasions, and perhaps even for the treatment of vitiligo, but they will not penetrate far enough for deep seated pain reduction. However, infrared lasers (around 800 nanometers) penetrate far deeper and able to go several centimeters, into your body which will reach most tissue injuries.
Power is also another crucial factor when it comes to laser therapy. Power is measured in watts, and you can think of it as the brightness of the light. A higher-powered laser is a brighter light, and it can produce more energy per unit of time. When it comes to doing laser therapy treatment, a higher-powered laser (Class 4) provides two benefits:

 

• A therapeutic dose of laser light can be applied to a much larger volume of tissue
• By shining that brighter light at the surface, photons of light are able to penetrate deeper into the tissues, which allows you to treat deep-seated pain conditions

____________________________________

 

The Effect of Low-Level Laser in Knee Osteoarthritis: A Double-Blind, Randomized, Placebo-Controlled Trial

 Aug, 2009 

 http://www.ncbi.nlm.nih.gov/pubmed/19530911



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Photonic device that could change physics and lasers forever

04 June 2024

 

SciTechDaily carries an article about Rensselaer Polytechnic Institute researchers who have developed the first topological quantum simulator device in the strong light-matter interaction regime, Caliber.Az reprints the article.

 

Rensselaer Polytechnic Institute researchers have developed the first topological quantum simulator device in the strong light-matter interaction regime that operates at room temperature, revolutionizing quantum studies and laser efficiency, and making advanced research more accessible.

 

Researchers at Rensselaer Polytechnic Institute (RPI) have fabricated a device no wider than a human hair that will help physicists investigate the fundamental nature of matter and light. Their findings, published in the journal Nature Nanotechnology, could also support the development of more efficient lasers, which are used in fields ranging from medicine to manufacturing.

 

The device is made of a special kind of material called a photonic topological insulator. A photonic topological insulator can guide photons, the wave-like particles that make up light, to interfaces specifically designed within the material while also preventing these particles from scattering through the material itself.

 

https://caliber.az/en/post/photonic-device-that-could-change-physics-and-lasers-forever 

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Harmonizing single photons with a laser pulse

26 April 2022

 

A fast laser pulse stimulates the decay in a quantum dot and suppresses the timing uncertainty in the generation of single photons, which substantially improves the coherence of the source. 

https://www.nature.com/articles/s41565-022-01117-0

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Researchers demonstrate the world's first white lasers

 

July 29, 2015

http://phys.org/news/2015-07-world-white-lasers.html?utm_source=menu&utm_medium=link&utm_campaign=item-menu

 

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NASA Beams Mona Lisa to Moon with Laser

 

January 17, 2013

 Call it the ultimate in high art: Using a well-timed laser, NASA scientists have beamed a picture of Leonardo da Vinci's masterpiece, the Mona Lisa, to a powerful spacecraft orbiting the moon, marking a first in laser communication.

 http://www.space.com/19323-mona-lisa-moon-laser-photo.html

 

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 Paintballs to deflect killer-asteroids


 Mar 07, 2013

 
 Having reviewed these traditional asteroid deflection techniques, Sung Wook Paek, a graduate from the Massachusetts Institute of Technology, suggests an unusual alternative: Mr Paek proposes using paintballs to pull an asteroid off course.

The argument behind Mr Paek's idea is reasonably simple; after measuring the velocity and rotation of an incoming asteroid, two unmanned spacecraft would approach the celestial body close enough to be able to shoot large clouds of white paintballs at it! Two probes would be needed because, as the asteroid rotates, a shot from only one spacecraft would not cover the entire asteroid with white paint and so the first probe strikes one side of the asteroid, the second probe covers the other.

The white paint would reflect light and other electromagnetic radiation from the asteroid's surface, and, over time, the cumulative effect of billions of photons would result in the asteroid changing course. The white paint would effectively act as a 'solar sail', increasing the balance of solar radiation absorbed and emitted by the asteroid, gently easing it away from its original destination.
Another deflection technique, also based on light reflectivity or laser sublimation was proposed by a team of American researchers who suggested launching a swarm of 'mirror bees' towards the potential killer.

Tiny probes, equipped with mirrors, would position themselves in such a way as to reflect a concentration of sunlight on one specific point of the asteroid. This 'beam of light' would then generate enough heat for it to start to vaporise, creating propulsive gas jets. In essence, vapour emitted from the asteroid would push it off-course. Alternatively, the asteroid might 'simply' be wrapped in reflective 'foil'.


http://www.spacedaily.com/reports/Paintballs_to_deflect_killer_asteroids_999.html

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Laser Bees

 

A New Way to Deflect a Dangerous Asteroid

 

What do we do if an asteroid is found to be on a collision course with Earth? At this point, the answer is not clear, so The Planetary Society has partnered with researchers to discover ways to protect Earth when we one-day find a dangerous space rock.

We've been working with a team at the University of Strathclyde and the University of Glasgow in Scotland to study a new technique which uses concentrated light to gently move an asteroid -- a project we called "Mirror Bees" -- using mirrors on several spacecraft swarming around an asteroid to focus sunlight onto a spot on the asteroid. As part of the initial Mirror Bees project, researchers found that lasers are more effective than mirrors and can be used from greater distances. So, now the project is called "Laser Bees."

 

 http://www.planetary.org/explore/projects/laser-bees/

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Physicist unveils plan for entangling massive objects

 

August 5, 2015 

 

 Schnabel's plan is to place two of the mirrors in a Michelson-type interferometer in such a way as to have both sides of both mirrors hit by light that is sent in. The mirrors would also be placed in the interferometer in a way that would allow them to oscillate when struck by the light. This would allow for momentum to be transferred between the mirrors and the light. The mirror oscillations would then have an impact on the phase of the reflected light, causing the momentum and the light to become entangled. At that point, the entanglement could be "swapped" to the mirrors, causing them to be entangled, by measuring the light beams as they exit.

 http://phys.org/news/2015-08-physicist-unveils-entangling-massive.html#jCp

 

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Asteroid Impact Avoidance

July 2013


DE-STAR is designed to vaporize or divert asteroids that threaten Earth. This isn't science fiction—I build things that have to work in practice. DE-STAR stands for Directed Energy Solar Targeting of Asteroids and exploRation. It looks like an open matchbook with lasers on one flap and a photovoltaic panel for power from sunlight on the other. By synchronizing the laser beams, we can create a phased array, which produces a steerable 70-gigawatt beam. An onboard system receives orders on what to target. Our laser beam would then produce a spot about 100 feet in diameter on an asteroid that's as far away from the satellite as we are from the sun. The laser would raise an asteroid's surface temperature to thousands of degrees Celsius—hot enough that all known substances evaporate. In less than an hour, DE-STAR could have completely vaporized the asteroid that broke up over Russia this winter, if we had seen it coming. Plus, as the material evaporates, it creates a thrust in the opposite direction, comparable to the space shuttle's rocket booster. That means you could divert the asteroid by changing its orbit with a shorter laser blast.
DE-STAR could also power things on Earth or in space. You could send the electrical power it produces—not via laser beam but via microwaves. Or you could use the laser to directly propel spacecraft. But here's the thing: For full-blown asteroid vaporization, each flap of the matchbook would have to be six miles long. We've never built a structure this size in space, but if there were the worldwide will, I could see building this within 30 to 50 years. But since it's completely modular, we propose starting smaller. We could begin with a version that's three feet per side right now. With that, you could cook your dinner from 600 miles away.
—Philip Lubin is a physicist at UC Santa Barbara and co-inventor of DE-STAR with statistician Gary Hughes, of California Polytechnic State University.
This article originally appeared in the July 2013 issue of Popular Science. 

http://www.popsci.com/science/article/2013-06/death-star

 

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Researchers use laser to levitate, glowing nanodiamonds in vacuum

 

September 7, 2015

 
Researchers have, for the first time, levitated individual nanodiamonds in vacuum. The research team is led by Nick Vamivakas at the University of Rochester who thinks their work will make extremely sensitive instruments for sensing tiny forces and torques possible, as well as a way to physically create larger-scale quantum systems known as macroscopic Schrödinger Cat states.

Read more at: http://phys.org/news/2015-09-laser-levitate-nanodiamonds-vacuum.html#jCp

 

 
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Scientists Produce Unprecedented 1 Megajoule Laser Shot, Step Towards Fusion Ignition

January 28, 2010


US scientists have produced a laser shot with an unprecedented energy level that could be a key step towards nuclear fusion, the US National Nuclear Security Administration said Wednesday.

http://phys.org/news/2010-01-scientists-unprecedented-megajoule-laser-shot.html#nRlv

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Physicists demonstrate conditions for laser-driven fusion

 

March 15, 2011

Currently, commercial nuclear power plants generate electricity using nuclear fission, in which an atom’s nucleus is split into lighter nuclei. But scientists are also researching the reverse reaction, nuclear fusion, in which two light atomic nuclei fuse to form a single heavier nucleus. Compared with fission, fusion has the potential to produce less radioactive waste while still generating large amounts of energy.

http://phys.org/news/2011-03-physicists-conditions-laser-driven-fusion.html#nRlv

 

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First atomic X-ray laser created

 

January 25, 2012 

 

Scientists working at the U.S. Department of Energy's (DOE) SLAC National Accelerator Laboratory have created the shortest, purest X-ray laser pulses ever achieved, fulfilling a 45-year-old prediction and opening the door to a new range of scientific discovery.

The researchers, reporting today in Nature, aimed SLAC's Linac Coherent Light Source (LCLS) at a capsule of neon gas, setting off an avalanche of X-ray emissions to create the world's first "atomic X-ray laser." 

 

http://phys.org/news/2012-01-atomic-x-ray-laser.html#nRlv

 

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New laser power converters transmit power further and better

 

July 28, 2025

 

https://www.ise.fraunhofer.de/en/press-media/news/2025/new-laser-power-converters-transmit-power-further-and-better.html

 

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Generating Megatesla Magnetic Fields on Earth Using Intense-Laser-Driven Microtube Implosions

 

October 12, 2020

 

A team of researchers led by Osaka University discovers “microtube implosion,” a novel mechanism that demonstrates the generation of megatesla-order magnetic fields.

 

Magnetic fields are used in various areas of modern physics and engineering, with practical applications ranging from doorbells to maglev trains. Since Nikola Tesla’s discoveries in the 19th century, researchers have strived to realize strong magnetic fields in laboratories for fundamental studies and diverse applications, but the magnetic strength of familiar examples are relatively weak. Geomagnetism is 0.3−0.5 gauss (G) and magnetic tomography (MRI) used in hospitals is about 1 tesla (T = 10⁴ G). By contrast, future magnetic fusion and maglev trains will require magnetic fields on the kilotesla (kT = 10⁷ G) order. To date, the highest magnetic fields experimentally observed are on the kT order.

 

Recently, scientists at Osaka University discovered a novel mechanism called a “microtube implosion,” and demonstrated the generation of megatesla (MT = 10¹⁰G) order magnetic fields via particle simulations using a supercomputer. Astonishingly, this is three orders of magnitude higher than what has ever been achieved in a laboratory. Such high magnetic fields are expected only in celestial bodies like neutron stars and black holes.

 

https://scitechdaily.com/generating-megatesla-magnetic-fields-on-earth-using-intense-laser-driven-microtube-implosions/ 

 

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New technique for capturing ultra-intense laser pulses in a single shot

26 June 2025

 Physicists at the University of Oxford have unveiled a pioneering method for capturing the full structure of ultra-intense laser pulses in a single measurement. The breakthrough, published in close collaboration with Ludwig-Maximilian University of Munich and the Max Planck Institute for Quantum Optics, could revolutionise the ability to control light-matter interactions. This would have transformative applications in many areas, including research into new forms of physics and realising the extreme intensities required for fusion energy research. The results have been published today in Nature Photonics.

 

https://www.physics.ox.ac.uk/news/new-technique-capturing-ultra-intense-laser-pulses-single-shot

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Nanostructures Enable Record High-Harmonic Generation From Ultra-Intense Laser Pulses

 

September 24, 2021

 

Nanostructures enable record high-harmonic generation. Researchers have developed nanostructures that enable record-breaking conversion of laser pulses into high-harmonic generation, paving the way for new scientific tools for high-resolution imaging.

 

“It opens up new opportunities to study matter at ultrahigh fields, a regime not readily accessible before,” Shcherbakov said. “With our method, we envision that people can study materials beyond metasurfaces, including but not limited to crystals, 2D materials, single atoms, artificial atomic lattices and other quantum systems. “

 

https://science-atlas.com/physics/nanostructures-enable-record-high-harmonic-generation-from-ultra/ 



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Chip-Based Optical Tweezers Levitate Nanoparticles in a Vacuum

21 October 2021

 

WASHINGTON — Researchers have created tiny chip-based optical tweezers that can be used to optically levitate nanoparticles in a vacuum. Optical tweezers — which employ a tightly focused laser beam to hold living cells, nanoparticles and other objects — can be used for a variety of precision measurements and sensing applications. However, these optical traps are usually produced with bulky optical components. 

 

“By using an ultrathin metalens, we reduced the diameter of the focusing lens from about 25 mm to about 0.4 mm,” said research team leader Tongcang Li from Purdue University. “The chip-based design can be used to create an integrated and flexible optical system for studying near-surface forces by trapping an object less than 1 micrometer away from a surface. It might also be useful for trapping cold atoms in a vacuum to study quantum processes.”

 

In Optica, Optica Publishing Group’s journal for high-impact research, researchers at Purdue University and Pennsylvania State University report the first realization of on-chip optical levitation in a vacuum with an ultrathin metalens.  Accomplishing this feat in a vacuum helps improve the sensitivity of the system.

 

“Optically levitated particles can be used to create accelerometers and gyroscopes that could potentially be used in navigation,” said Li. “Scientists are also using optically levitated particles to search for dark matter and dark energy and to study gravity at short distances, which will deepen our understanding of nature.”

https://www.optica.org/about/newsroom/news_releases/2021/chip-based_optical_tweezers_levitate_nanoparticles/

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The following will discuss Lazers as weapons, including the use of lazers for weather modification. 



____________________________________



Indium phosphide, Diode Lazers & Dupont

Lazers & Dupont


Diode lazer

DuPont originally began the research into building a blue diode laser for CD read/write devices, however they were unable to make the lasers suitable for commercial use. AdvR licensed the patents from DuPont and received BMDO funding to create a solid-state replacement for the Argon-ion laser.

http://www.mdatechnology.net/techprofile.aspx?id=555

 

____________________________________

DuPont - LASER WELDING

http://www2.dupont.com/Hyundai_Kia/en_US/assets/downloads/presentations/Laser%20Welding_Korea_Fujita.pdf

____________________________________

DuPont Introduces Water Resistant Somos(R) 7110 Epoxy Resin for Helium Cadmium Laser Systems 

http://www.thefreelibrary.com/DuPont+Introduces+Water+Resistant+Somos%28R%29+7110+Epoxy+Resin+for...-a019781521

____________________________________

 


A. Felix du Pont, Jr. 

http://en.wikipedia.org/wiki/A._Felix_du_Pont,_Jr.


Known for being a philanthropist


For five years, Felix du Pont worked for the family owned DuPont and for a short time became involved in the investment business. With a lifelong interest in aviation, he partnered with brother Richard to found All American Aviation Company which became Allegheny Airlines and eventually US Airways. He later was a vice president of the Piasecki Helicopter Corp. of which he and Laurence Rockefeller were early investors on its founding in 1946.

____________________________________

 

Piasecki Helicopter 

  

Piasecki Helicopter Corporation was a designer and manufacturer of helicopters located in Philadelphia, Pennsylvania and nearby Morton, Pennsylvania in the late 1940s and the 1950s. Its founder, Frank Piasecki, was ousted from the company in 1956 and started a new company, Piasecki Aircraft. Piasecki Helicopter was renamed Vertol Corporation in early 1956. 

Vertol was acquired by Boeing in 1960 and renamed Boeing Vertol. 

http://en.wikipedia.org/wiki/Piasecki_Helicopter   

____________________________________

  

Electric Laser Race Heats Up

 

http://sites.psu.edu/thebigbangtheory/2012/10/29/the-holographic-excitation/


Not wanting to be left out of the race to field compact battlefield lasers, Boeing announced yesterday that it’s tested its own solid-state laser technology. "In each laser firing at Boeing’s facility in West Hills, Calif., the high-energy laser achieved power levels of over 25 kilowatts for multi-second durations, with a measured beam quality suitable for a tactical weapon system," says Boeing.
What’s interesting about this announcement is that Boeing is not part of the Defense Department’s Joint High-Powered Solid State Laser, a program that has funded Northrop Grumman and Textron to build a deployable laser weapon. Boeing at one point teamed with the Livermore lab on a solid-state work, but that laser, which was powerful but large, was not selected by the program for funding. Similarly, Raytheon also has a solid state laser that was passed over for funding. Both Livermore and Raytheon have continued their solid-state laser work on their own dime, however. Boeing, until this point, did not appear to be that active on solid-state lasers, and it appears this new effort is self-funded.

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____________________________________

 

Boeing Laser Systems Destroy Unmanned Aerial Vehicles in Tests

 

Boeing's Matrix laser

 

http://news.cnet.com/2300-11386_3-10012168-17.html

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Neither rain, nor fog, nor wind stops Boeing's laser weapon destroying targets

 

September 8, 2014
 

http://www.gizmag.com/boeing-laser-directed-energy-weapon-fog/33672/

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Lockheed Martin begins manufacturing vehicle-mounted laser weapon

 

October 8, 2015

Lockheed Martin announced this week that production of a new laser weapon system has begun at the company's Bothell, Washington facility. The high-powered laser weapon modules will be used as the heart of a 60-kilowatt system designed to be fitted to a US Army vehicle.

The laser can be operated by a single person and is made up of multiple fiber laser modules, which not only allows for greater flexibility, but also lessens the chance of the weapon being knocked out by a minor malfunction, so frequent repairs aren't required. Lockheed Martin also says that the modular design means that the laser power can be varied across an extremely wide range to suit specific mission needs. Using off-the-shelf commercial fiber laser components to keep down costs, the modules can be linked together to produce lasers of up to 120 kW.


http://www.gizmag.com/lockheed-martin-athena-laser-weapon-manufacture/39753/?li_source=LI&li_medium=default-widget 

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MIRACL

 MIRACL, or Mid-Infrared Advanced Chemical Laser, is a directed energy weapon developed by the US Navy. It is a deuterium fluoride laser, a type of chemical laser.

http://en.wikipedia.org/wiki/MIRACL

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Tactical High Energy Laser

 

http://en.wikipedia.org/wiki/Tactical_High_Energy_Laser

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Electrolaser

 

An electrolaser is a type of electroshock weapon which is also a directed-energy weapon. It uses lasers to form an electrically conductive laser-induced plasma channel (LIPC). A fraction of a second later, a powerful electric current is sent down this plasma channel and delivered to the target, thus functioning overall as a large-scale, high energy, long-distance version of the Taser electroshock gun.


http://en.wikipedia.org/wiki/Electrolaser


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Laser Weapons

 

https://www.youtube.com/watch?v=ZxcwlJ30uAw

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Sonic weapon

 Sonic and ultrasonic weapons (USW) are weapons of various types that use sound to injure, incapacitate, or kill an opponent. Some sonic weapons are currently in limited use or in research and development by military and police forces. Others exist only in the realm of science fiction. Some of these weapons have been described as sonic bullets, sonic grenades, sonic mines, or sonic cannons. Some make a focused beam of sound or ultrasound; some make an area field of sound.

 https://en.wikipedia.org/wiki/Sonic_weapon

 

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Protocol on Blinding Laser Weapons

 

http://en.wikipedia.org/wiki/Protocol_on_Blinding_Laser_Weapons

 

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Solid-state laser

 

https://en.wikipedia.org/wiki/Solid-state_laser

 A solid-state laser is a laser that uses a gain medium that is a solid, rather than a liquid such as in dye lasers or a gas as in gas lasers. Semiconductor-based lasers are also in the solid state, but are generally considered as a separate class from solid-state lasers (see Laser diode).

 Solid-state lasers are being developed as optional weapons for the F-35 Lightning II, and are reaching near-operational status, as well as the introduction of Northrop Grumman's FIRESTRIKE laser weapon system. In April 2011 the United States Navy tested a high energy solid state laser. The exact range is classified, but they said it fired "miles not yards".

 


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Lockheed Martin Weapon Prototype Immobilizes Truck Over A Mile Away 'In Matter Of Seconds': Here's How

 

March 7th, 2015

http://www.techtimes.com/articles/38044/20150307/lockheed-martin-weapon-prototype-immobilizes-truck-over-a-mile-away-in-matter-of-seconds-heres-how.htm

ATHENA was designed based on Lockheed Martin's Area Defense Anti-Munitions (ADAM) laser weapon system used in demonstrations against small airborne and sea-based targets. Lockheed Martin developed a technique called spectral beam combining together three 10-kilowatt fiber laser modules into a single, powerful, high-quality 30-kilowatt beam that is more powerful than its 10-kilowatt components.




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Shooting lightning out of the sky

 

New methods to make longer streams of plasma with greater longevity could lead to laser-powered lightning rods

 

Date:

September 24, 2015

 

 A team of researchers has demonstrated new techniques that bring lasers as lighting rods closer to reality. When a powerful laser beam shoots through the air, it ionizes the molecules, leaving a thin trail of hot, ionized particles in its wake. Because this stream of plasma conducts electricity, it could be used to channel away a potentially damaging lightning bolt. The researchers found ways to make the length of such a plasma channel reach more than 10 times longer -- a necessary advance for using the channel to redirect a lightning strike.

 http://www.sciencedaily.com/releases/2015/09/150924124045.htm

 

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Boeing says laser weapon a success in Pentagon testing

 

 2013

 

Boeing Co.'s Directed Energy Systems division says it has achieved a sufficient level of power and beam quality to allow a solid-state laser system to be deployed to battlefields. The system - which could eventually bring down rockets and drones and destroy IEDs with a blast of light- is part of a major effort towards the development of directed energy weapons.

 

Boeing announced last week its Thin Disk Laser System, which uses a series of high-powered industrial lasers to generate a single concentrated, high-energy beam, has achieved the required thresholds for power and beam quality during demonstrations for the Department of Defense's Robust Electric Laser Initiative, or RELI, effort.

 http://blog.al.com/breaking/2013/08/one_step_closer_to_star_wars_b.html

 

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Boeing to be awarded contract for Laser SDB

28 June, 2013

28 June, 2013

  28 June, 2013
 
The US Air Force intends to award Boeing a contract to develop and test a new laser-guided version of its 250lb (113kg) small diameter bomb (SDB).

The company says that the weapons can carry out many of the functions of Raytheon’s SDB II, which has a tri-modal seeker with millimeter wave radar, infrared, and semi-active laser guidance capabilities, at far lower cost. The new weapon is based on Boeing’s laser joint direct attack munition (JDAM) technology.

 http://www.flightglobal.com/blogs/the-dewline/2013/06/boeing-to-be-awarded-contract/#sthash.wOJQCrub.dpuf

The US Air Force intends to award Boeing a contract to develop and test a new laser-guided version of its 250lb (113kg) small diameter bomb (SDB).

The company says that the weapons can carry out many of the functions of Raytheon’s SDB II, which has a tri-modal seeker with millimeter wave radar, infrared, and semi-active laser guidance capabilities, at far lower cost. The new weapon is based on Boeing’s laser joint direct attack munition (JDAM) technology.

- See more at: http://www.flightglobal.com/blogs/the-dewline/2013/06/boeing-to-be-awarded-contract/#sthash.wOJQCrub.dpuf

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Raytheon Government Agencies and Companies to Come to Consensus on Weather Modification

2012

 

A Plan for the next phase in Weather Modification Science and Technology

Development

Weather Modification Association Annual Meeting, 2005


PDF: Raytheon says more WEATHER MODIFICATION!
 

http://r3zn8d.files.wordpress.com/2012/11/raytheon-says-moar-weather-modification.pdf

 

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Connecting the Raytheon, AMS, Lockheed, HAARP, NOAA, General Dynamics and DARPA dots….

Defense Advanced Research Program Association, or DARPA, has contracted co-operation command of the Highly Active Auroral Research Program (HAARP) electromagnetic microwave ionospheric heater in Gakona, Alaska, for military communication and weapon “defense” purposes. They also take part in biological warfare “testing” over land, water, and city, whereby defense contractor jets, such as those crafted especially for war or weather programs by BAE Systems (owner of the HAARP facility) or Raytheon (owner of the HAARP patent), for the Navy and Air Force and NATO, disperse hazardous toxins into the air and then attempt to eradicate them with chemicals or jet-mounted microwave radiation weapons (like AESA). In addition, the Lockheed Martin and Boeing corporations joined up in a B2B contract with BAE and Raytheon, hardware and software hosted by none other than Microsoft, so that their defense contractor industry market could remain consistently and wirelessly networked, and would never be halted by distance, time, or situational awareness. The NOAA, a member of the Weather Modification Operations and Research Board, (partnered on that board with the American Meteorological Society and the National Science Foundation) sold its weather reporting functionality to Raytheon, who operates it now under the name Advanced Weather Information Processing System. Raytheon happens to contract many of its services and industrial airliners to the tune of global weather modification programs, such as those ever popular “global warming mitigation” or “global dimming” programs, (whereby jets utilizing liquid propane, liquid nitrogen, silver iodide, potassium chlorate, barium oxide, acrylamides, and trimethyl aluminum, spray these chemicals to replace cloud cover over entire countries) and, they’ve even managed to create, through their sub-company General Dynamics Robotics, Unmanned Autonomous Vehicles such as the Global Hawk that can fly for 72 hours, with a payload of 20,000 lbs or more, running entirely on programming and artificial intelligence microwave signal networking, without landing or refueling. It’s not just local chemical “cloud seeding” or “storm prevention” anymore, as is still practiced by the state-and-regional program member companies of the Weather Modification Association.

http://geoengineeringwatch.org/html/weatherreportedbyraytheon.html

 
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Free Electron Laser (FEL)

http://www.popularmechanics.com/technology/military/research/8-laser-weapon-systems-to-zap-planes-boats-and-people#slide-6


Power: 100-kw class

In 1989 Boeing was awarded a contract to build a unique laser weapon made from a Free Electron Laser—essentially a laser made out of a particle accelerator.


After all these years, though, Boeing still has plenty of work to do to actually build serious FEL weapons. At minimum, the laser would need to reach 100 kilowatts, and so far the free electron laser power record is only 14. Pogue hopes to reach 100 kilowatts in the lab by 2015—and then figure out how the heck to get a particle accelerator on a ship.

 


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World's most powerful laser to tear apart the vacuum of space

 

Due to follow in the footsteps of the Large Hadron Collider, the latest "big science" experiment being proposed by physicists will see the world's most powerful laser being constructed.

Capable of producing a beam of light so intense that it would be equivalent to the power received by the Earth from the sun focused onto a speck smaller than a tip of a pin, scientists claim it could allow them boil the very fabric of space – the vacuum.

Contrary to popular belief, a vacuum is not devoid of material but in fact fizzles with tiny mysterious particles that pop in and out of existence, but at speeds so fast that no one has been able to prove they exist.

The Extreme Light Infrastructure Ultra-High Field Facility would produce a laser so intense that scientists say it would allow them to reveal these particles for the first time by pulling this vacuum "fabric" apart.

They also believe it could even allow them to prove whether extra-dimensions exist.

http://www.telegraph.co.uk/science/science-news/8857154/Worlds-most-powerful-laser-to-tear-apart-the-vacuum-of-space.html

 

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How we recreated the early universe in the laboratory

 

May 12, 2015

- Instead of focusing our attention on immense particle accelerators, we turned to the ultra-intense lasers available at the Central Laser Facility at the Rutherford Appleton Laboratory in Oxfordshire, UK. We used an ultra-high vacuum chamber with an air pressure corresponding to a hundredth of a millionth of our atmosphere to shoot an ultra-short and intense laser pulse (hundred billions of billions more intense that sunlight on the Earth surface) onto a nitrogen gas. This stripped off the gas' electrons and accelerated them to a speed extremely close to that of light.

The beam then collided with a block of lead, which slowed them down again. As they slowed down they emitted particles of light, photons, which created pairs of electrons and their anti-particle, the positron, when they collided with nuclei of the lead sample. A chain-reaction of this process gave rise to the plasma.

However, this experimental achievement was not without effort. The laser beam had to be guided and controlled with micrometer precision, and the detectors had to be finely calibrated and shielded – resulting in frequent long nights in the laboratory.

But it was well worth it as the development means an exciting branch of physics is opening up. Apart from investigating the important matter-antimatter asymmetry, by looking at how these plasmas interact with ultra powerful laser beams, we can also study how this plasma propagates in vacuum and in a low-density medium. This would be effectively recreating conditions similar to the generation of gamma-ray bursts, some of the most luminous events ever recorded in our universe.

 http://phys.org/news/2015-05-recreated-early-universe-laboratory.html#jCp

 

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No Big Bang? Quantum equation predicts universe has no beginning

Feb 09, 2015

http://phys.org/news/2015-02-big-quantum-equation-universe.html



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Holometer rules out first theory of space-time correlations

 

December 4, 2015

 

http://phys.org/news/2015-12-holometer-theory-space-time.html



The Holometer is a deceptively simple device. It uses a pair of laser interferometers placed close to one another, each sending a one-kilowatt beam of light through a beam splitter and down two perpendicular arms, 40 meters each. The light is then reflected back into the beam splitter where the two beams recombine. If no motion has occurred, then the recombined beam will be the same as the original beam. But if fluctuations in brightness are observed, researchers will then analyze these fluctuations to see if the splitter is moving in a certain way, being carried along on a jitter of space itself.

According to Fermilab's Aaron Chou, project manager of the Holometer experiment, the collaboration looked to the work done to design other, similar instruments, such as the one used in the Laser Interferometer Gravitational-Wave Observatory (LIGO) experiment. Chou said that once the Holometer team realized that this technology could be used to study the quantum fluctuation they were after, the work of other collaborations using laser interferometers (including LIGO) was invaluable.

"No one has ever applied this technology in this way before," Chou said. "A small team, mostly students, built an instrument nearly as sensitive as LIGO's to look for something completely different."

The challenge for researchers using the Holometer is to eliminate all other sources of movement until they are left with a fluctuation they cannot explain. According to Fermilab's Chris Stoughton, scientist on the Holometer experiment, the process of taking data was one of constantly adjusting the machine to remove more noise.

"You would run the machine for a while, take data, and then try to get rid of all the fluctuation you could see before running it again," he said. "The origin of the phenomenon we're looking for is a billion billion times smaller than a proton, and the Holometer is extremely sensitive, so it picks up a lot of outside sources, such as wind and traffic."

If the Holometer were to see holographic noise that researchers could not eliminate, it might be detecting noise that is intrinsic to space-time, which may mean that information in our universe could actually be encoded in tiny packets in two dimensions.

The fact that the Holometer ruled out his theory to a high level of significance proves that it can probe time and space at previously unimagined scales, Hogan said. It also proves that if this quantum jitter exists, it is either much smaller than the Holometer can detect, or is moving in directions the current instrument is not configured to observe.

So what's next? Hogan said the Holometer team will continue to take and analyze data, and will publish more general and more sensitive studies of holographic noise. The collaboration already released a result related to the study of gravitational waves.

And Hogan is already putting forth a new model of holographic structure that would require similar instruments of the same sensitivity, but different configurations sensitive to the rotation of space. The Holometer, he said, will serve as a template for an entirely new field of experimental science.

"It's new technology, and the Holometer is just the first example of a new way of studying exotic correlations," Hogan said. "It is just the first glimpse through a newly invented microscope."



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Nanoparticles found to violate second law of thermodynamics

 

April 3, 2014

It may be a little late for April Fool's, but some skepticism is nonetheless warranted when reading that researchers have shown nanoparticles to disobey a fundamental law of physics which dictates the flow of entropy and heat in, it was believed, any situation. Specifically, researchers from three universities theoretically proposed then demonstrated that a nanoparticle in a state of thermal non-equilibrium does not always behave as larger particles might under the same conditions, with implications for various fields of research.
The second law of thermodynamics is the one that makes perpetual motion machines impossible. It states that the entropy – the measure for the disorder of a system – of any isolated system cannot decrease spontaneously, with the system evolving towards the state of maximum entropy (favoring disorder). The team has shown that a nanoparticle trapped with laser light temporarily violates this law. This seeming violation of universal law is transient, something that the researchers first derived as a mathematical model of fluctuations expected at the nanoscale.

http://www.gizmag.com/nanoparticles-violate-law-thermodynamics/31491/?li_source=LI&li_medium=default-widget

 

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Quantum time freezing: Lasers freeze quantum states a thousand times longer

 

June 23, 2025 

 

Using powerful laser and X-ray pulses, researchers from Harvard and the Scherrer Institute have succeeded in breaking electronic symmetry and trapping a long-lasting quantum state – a move that could lead to breakthroughs in information storage and optoelectronic devices.

 
https://hayadan.com/quantum-time-freeze 

 

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This laser implosion just created a magnetic field like a neutron star

 

July 16, 2025

 

A new twist on magnetism: Helical currents from blade implosions

 

A powerful new technique harnesses swirling plasma inside laser-blasted microtubes to produce record-breaking magnetic fields—rivaling those near neutron stars—all within a compact laboratory setup. This innovation promises to transform astrophysics, quantum research, and fusion energy experiments by unleashing megatesla-level forces using nothing more than targeted laser pulses and clever engineering. 

 

https://www.sciencedaily.com/releases/2025/07/250716000839.htm

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Scientists announce breakthrough in quest for fusion power

  

February 13, 2014

 http://www.gizmag.com/fusion-breakthrough/30814/?li_source=LI&li_medium=default-widget

In a perfect example of beating swords into plowshares, a team of scientists at the Lawrence Livermore National Laboratory's (LLNL) National Ignition Facility (NIF) in California reached a milestone in the quest for practical fusion power using a process designed for the development and testing of nuclear weapons. The announcement in the February 12 issue of Nature claims that the team used the world’s most powerful laser barrage to produce a controlled fusion reaction where more energy was extracted from the fuel than was put into it.

If there is an ultimate engineering dream, then nuclear fusion is about as close as close as one can get. By literally harnessing the power of the stars, it holds the promise of what is, for all practical purposes, unlimited clean energy. Since man-made fusion was first demonstrated in 1951 with a boosted fission weapon, scientists and engineers have worked on some way to produce a practical fusion reactor instead of a hydrogen bomb.

The story of the fusion reactor is one of both great progress, but also constant frustration. When work began, the first reactor was predicted to be 25 years away. Since then and up until today, it’s still 25 years away. That’s because although nuclear fusion is relatively simple in theory, getting a controlled reaction started outside of the heart of a star is extremely difficult. The trick is to reach the “ignition” point, where the energy released by the reactor is greater than what’s put into it and the reaction becomes self-sustaining.

A fusion reactor works by simulating the conditions inside the Sun. Put simply, hydrogen atoms fuse in the Sun because its huge mass squashes the atoms together to form helium, releasing huge amounts of energy as the strong nuclear force that keeps them apart is overcome. A hydrogen bomb does the same thing, only with a fission bomb creating the necessary conditions for a millionth of a second.

 

____________________________________ 

Apparent breakthrough in nuclear fusion silenced by shutdown

 

Scientists have come one step closer to harnessing the power of the sun. Researchers at the National Ignition Facility (NIF) have passed a milestone in achieving self-sustaining nuclear fusion -- but you won't hear about it from the researchers. The NIF team has been furloughed as a result of the U.S. government shutdown, which began on Oct. 1, and is not releasing updates to the press.

According to the BBC, a research experiment conducted in late September succeeded in releasing more energy through a fusion reaction than it absorbed by the fuel going in. NIF is the first research facility in the world to achieve this goal. A spokesperson for the NIF could not give CBSNews.com a comment on the results of the experiment.


 NIF's method for achieving fusion involves sending 192 laser beams through a 1,500-meter journey that increases its energy output by a factor of more than a quadrillion. The laser beams' energy grows from one-billionth of a joule to 4 million joules in 5 millionths of a second.

A breakthrough in nuclear fusion is widely considered the holy grail of achieving an unlimited clean energy source.
Scientists believe that fusion can fuel our future without threat of nuclear proliferation or environmental damage because the process of creating fusion requires very few resources. One of the biggest challenges in producing energy derived from fusion has been to pass the break-even point -- a goal that has eluded scientists for nearly 50 years.
Nuclear fusion is not to be confused with nuclear fission. Instead of splitting an atom's nucleus, like in fission, nuclear fusion is the process of bringing together two atomic nuclei to form a new nucleus.
While the NIF has passed the break-even point, it is just shy of reaching "ignition" -- when nuclear fusion produces as much energy as is supplied to the lasers.


 http://www.cbsnews.com/8301-205_162-57606588/apparent-breakthrough-in-nuclear-fusion-silenced-by-shutdown/

 

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Weather could be controlled using lasers

 

Scientists are attempting to control the weather by using lasers to create clouds, induce rain and even trigger lightning. 

 

 Experts from around the world are to gather at the World Meteorological Organisation next month to discuss how powerful laser pulses can be used to generate changes in the atmosphere that influence the weather. 

 

Their experiments have shown that intense pulses of light can cause ice to form and water to condense, leading to the formation of clouds.

The scientists have now begun testing their equipment outside for the first time with extremely short pulses of laser light were fired into the sky.

Researchers have also proved that lightning discharges can be triggered and channelled through the air using laser pulses.

There is a long history of attempts by scientists to control the weather, including using techniques such as cloud seeding.

This involves spraying small particles and chemicals into the air to induce water vapour to condense into clouds.

In the 1960s the United States experimented with using silver iodide in an attempt to weaken hurricanes before they made landfall.

The USSR was also claimed to have flown cloud seeding missions in an attempt to create rain clouds to protect Moscow from radioactive fallout from the Chernobyl nuclear disaster.

More recently the Russian Air force has also been reported to have used bags of cement to seed clouds.

Before the 2008 Olympic Games in Beijing, the Chinese authorities used aircraft and rockets to release chemicals into the atmosphere.
Other countries have been reported to be experimenting with cloud seeding to prevent flooding or smog.

However, Professor Wolf, Dr Kasparian and their colleagues believe that lasers could provide an easier and more controllable method of changing the weather.
They began studying lasers for their use as a way of monitoring changes in the air and detecting aerosols high in the atmosphere. 

  http://www.telegraph.co.uk/topics/weather/10268455/Weather-could-be-controlled-using-lasers.html

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Laser-induced condensation shows promise for cloud seeding

Over the past decade, commercially-available lasers have increased in power by two orders of magnitude, reaching the petawatt level, with exawatts firmly within sight. The 2011 experiment used a 100 terawatt laser, and a "mobile" (actually the size of a shipping container) laser of five terawatts.
Further understanding of how lasers spur condensation will also help. The process, known as photodissociation, involves the laser's photons breaking down atmospheric compounds to produce ozone and nitrogen molecules. Those in turn form nitric acid particles, which bind water molecules together into droplets.

http://www.wired.co.uk/news/archive/2012-07/17/laser-coud-seeding

 
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Laser Beams May Be Next Rainmakers


http://www.livescience.com/15834-laser-cloud-seed-rain.html



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Second Conference on Laser, Weather and Climate (LWC 2013) 

http://www.laserweatherandclimate.com/


Welcome

As highlighted by the success of the first Conference on Laser-based Weather Control in 2011, ultra-short lasers launched into the atmosphere have emerged as a promising prospective tool for weather modulation and climate studies. Such prospects include lightning control and laser-assisted condensation, as well as the striking similarities between the non-linear optical propagation and natural phenomena like rogue waves or climate bifurcations.



Filaments generated by ultra-short laser pulses launched into the atmosphere have emerged as an unexpected prospective tool for weather modulation. In particular, lightning control and laser-assisted water condensation recently appeared as spectacular prospects in this direction.

Although these new perspectives triggered an increasing interest and activity in many groups worldwide, the highly interdisciplinary nature of the subject limited its development, due to the need for enhanced contacts between laser and atmospheric physicists, chemists, electrical engineers, and meteorologists.

 

____________________________________

 


Climate control: United States weather modification in the cold war and beyond. 

http://www.ncbi.nlm.nih.gov/pubmed/18313754


____________________________________

 

Weather modification

http://en.wikipedia.org/wiki/Weather_modification

Proposed US Legislation

2005 U.S. Senate Bill 517 and U.S. House Bill 2995 U.S. Senate Bill 517 and U.S. House Bill 2995 were two bills proposed in 2005 that would have expanded experimental weather modification, to establish a Weather Modification Operations and Research Board, and implemented a national weather modification policy. Neither were made into law. Former Texas State Senator John N. Leedom was the key lobbyist on behalf of the weather modification bills.

2007 U.S. Senate Bill 1807 & U.S. House Bill 3445 Senate Bill 1807 and House Bill 3445, identical bills introduced July 17, 2007, proposed to establish a Weather Mitigation Advisory and Research Board to fund weather modification research.



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Physicists observe attosecond real-time restructuring of electron cloud in molecule

 

May 14, 2015 

 

 http://phys.org/news/2015-05-physicists-attosecond-real-time-electron-cloud.html?utm_source=menu&utm_medium=link&utm_campaign=item-menu

 

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Physicist finds mysterious anti-electron clouds inside thunderstorm

 

May 13, 2015

In August 2009, Dwyer and colleagues were aboard a National Center for Atmospheric Research Gulfstream V when it inadvertently flew into the extremely violent thunderstorm—and, it turned out, through a large cloud of positrons, the antimatter opposite of electrons, that should not have been there.

To encounter a cloud of positrons without other associated physical phenomena such as energetic gamma-ray emissions was completely unexpected, thoroughly perplexing and contrary to currently understood physics.

"The fact that, apparently out of nowhere, the number of positrons around us suddenly increased by more than a factor of 10 and formed a cloud around the aircraft is very hard to understand. We really have no good explanation for it," says Dwyer, a lightning expert and the UNH Peter T. Paul Chair in Space Sciences at the Institute for the Study of Earth, Oceans, and Space.

It is known that thunderstorms can sometimes make flashes of energetic gamma rays, which may produce pairs of electrons and positrons when they interact with air. But the appearance of positrons should then coincide with a large increase in the number of gamma rays.

"We should have seen bright gamma-ray emissions along with the positrons," Dwyer says. "But in our observations, we first saw a positron cloud, then another positron cloud about seven kilometers away and then we saw a bright gamma-ray glow afterwards. So it's all not making a whole lot of sense."

 

http://phys.org/news/2015-05-physicist-mysterious-anti-electron-clouds-thunderstorm.html?utm_source=menu&utm_medium=link&utm_campaign=item-menu

 

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Researchers show presence of charge-density waves in superconductive material

 

December 10, 2015 

 

  Ultrafast laser techniques helped MIT physics graduate student Fahad Mahmood and colleagues establish that electrons form charge-density waves in the thin-film superconductive material LSCO cuprate.

 "The question is how does this fluctuating charge-density wave compete or not interfere with superconductivity, and what we found is that it actually competes with superconductivity," Mahmood explains. "Electrons for a very short amount of time are in this charge-density wave state, and in another time scale, if you take another snapshot, they'll be in the superconductivity state."

Charge-density waves occur when electron density in a conductor is distributed in a sinusoidal pattern, like ripples on water, instead of the common uniform density.

"It's a fluctuating order that lasts for a very short amount of time and equilibrium probes won't be able to detect it," he says. Using ultrafast spectroscopy, Mahmood and co-authors of a 2013 Nature Materials paper were able to show that for extremely short periods of time—up to about 2 picoseconds—electrons clustered in a density wave that could be measured by its amplitude and phase.

http://phys.org/news/2015-12-presence-charge-density-superconductive-material.html

 

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Extending life of plasma channels could allow lasers to be used as lightning rods

 

 September 25, 2015

 

 http://www.gizmag.com/plasma-channels-laser-lightning-rods/39588/

Today's simple metal lightning rods may be on their way to obsolescence. That's because scientists at The Hebrew University of Jerusalem are developing a high-tech alternative that could potentially reach higher and be more effective – laser lightning rods.

When a high-power laser is shot into the sky, it ionizes airborne molecules in the process. As a result, even once the laser itself is shut off, a trail of ionized particles known as a plasma channel is left in its place. Plasma channels conduct electricity, not unlike a good ol' steel rod.

Led by scientist Jenya Papeer, the Jerusalem team successfully created plasma channels measuring 100 microns in diameter, by firing a laser in pulses lasting just 100 femtoseconds each. Unfortunately, however, after three nanoseconds the plasma cooled off and the channels ceased to exist.

In order to boost those trails' longevity by a factor of 10, the researchers added a second laser that is fired in 10-nanosecond bursts along the path of the first one. Its wider beam envelopes the plasma created by the first beam, keeping it hot and conductive. By boosting the power of that second laser, or even by adding additional beams, it is hoped that the lifespan and the length of the plasma channels could be lengthened further.

Speaking of which, though, the first plasma channels to be produced were only a meter (3.3 ft) long. The researchers addressed this limitation by creating an array of lenses that change the way in which the laser is focused. As a result, it now creates a series of three one-meter-long channels linked end-to-end, effectively forming one 3-meter plasma channel.

That said, by further adjusting the focus and using a powerful enough laser, it should be possible to produce any number of linked plasma channels, creating a lightning rod of any desired length.

A paper on the research will be presented on Oct. 22nd at the Frontiers in Optics conference, in San Jose, California.

 

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Atmospheric Vortex Engine creates tornadoes to generate electricity

 

December 20, 2012

 Tornadoes generally evoke the destructive force of nature at its most awesome. However, what if all that power could be harnessed to produce cheaper and more efficient electricity? This is just what Canadian engineer Louis Michaud proposes to achieve, with an invention dubbed the “Atmospheric Vortex Engine” (or AVE).

AVE works by introducing warm air into a circular station, whereupon the difference in temperature between this heated air and the atmosphere above creates a vortex – or controlled tornado, which in turn drives multiple wind turbines in order to create electricity. The vortex could be shut down by simply turning off the source of warm air.

http://www.gizmag.com/vortex-engine-tornadoes-electricity/25508/?li_source=LI&li_medium=default-widget

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Tiny magnets mimic steam, water and ice

September 21, 2015

Researchers at the Paul Scherrer Institute (PSI) created a synthetic material out of 1 billion tiny magnets. Astonishingly, it now appears that the magnetic properties of this so-called metamaterial change with the temperature, so that it can take on different states; just like water has a gaseous, liquid and a solid state. This material made of nanomagnets might well be refined for electronic applications of the future – such as for more efficient information transfer.

 http://phys.org/news/2015-09-tiny-magnets-mimic-steam-ice.html#jCp

 

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Volcanic ash proves inefficient cloud ice maker

 

May 28th, 2015

When tons of ash spewed into the atmosphere from a 2010 Icelandic volcano it caused havoc for vacationers across Europe. But did it also dramatically change clouds? Researchers at Pacific Northwest National Laboratory found that volcanic ash is not as efficient as common dust in birthing clouds' ice particles. Using a novel laboratory testing chamber they formed cloud ice, a process called ice nucleation, around particles of dust and volcanic ash. Their results revealed the importance of optimal particle structure to efficiently attract super cold water vapor to nucleate ice.

 http://phys.org/news/2015-05-volcanic-ash-inefficient-cloud-ice.html#jCp

 

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Silicon Nanoparticles Allow Production of Hydrogen from Water Without Heat, Light or Electricity

January 26, 2013

 http://www.bangscience.org/2013/01/silicon-nanoparticles-allow-production-of-hydrogen-from-water-without-heat-light-or-electricity/




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Enhancement of electron energy during vacuum laser acceleration in an inhomogeneous magnetic field


 In this paper, the effect of a stationary inhomogeneous magnetic field on the electron acceleration by a high intensity Gaussian laser pulse is investigated. A focused TEM (0,0) laser mode with linear polarization in the transverse x-direction that propagates along the z-axis is considered. The magnetic field is assumed to be stationary in time, but varies longitudinally in space. A linear spatial profile for the magnetic field is adopted. In other words, the axial magnetic field increases linearly in the z-direction up to an optimum point zm and then becomes constant with magnitude equal to that at zm . Three-dimensional single-particle simulations are performed to find the energy and trajectory of the electron. The electron rotates around and stays near the z-axis. It is shown that with a proper choice of the magnetic field parameters, the electron will be trapped at the focus of the laser pulse. Because of the cyclotron resonance, the electron receives enough energy from the laser fields to be accelerated to relativistic energies. Using numerical simulations, the criteria for optimum regime of the acceleration mechanism is found. With the optimized parameters, an electron initially at rest located at the origin achieves final energy of γ=802 . The dynamics of a distribution of off-axis electrons are also investigated in which shows that high energy electrons with small energy and spatial spread can be obtained.

 http://scitation.aip.org/content/aip/journal/pop/22/3/10.1063/1.4916130

 

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MIT’s Game-Changer: Ion Irradiation in Nanoparticle Engineering for Sustainable Energy

 

January 7, 2024

 

MIT researchers and colleagues have demonstrated a way to precisely control the size, composition, and other properties of nanoparticles key to the reactions involved in a variety of clean energy and environmental technologies. They did so by leveraging ion irradiation, a technique in which beams of charged particles bombard a material... 

 

 https://scitechdaily.com/mits-game-changer-ion-irradiation-in-nanoparticle-engineering-for-sustainable-energy/

 

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Computational trick enables better understanding of exotic state of matter

 

June 25, 2025

 

It can be found inside gas giants such as Jupiter and is briefly created during meteorite impacts or in laser fusion experiments: warm dense matter. This exotic state of matter combines features of solid, liquid and gaseous phases. Until now, simulating warm dense matter accurately has been considered a major challenge.

https://phys.org/news/2025-06-enables-exotic-state.html

 

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Jellyfish proteins used to create polariton laser

 

August 22, 2016

A combined team of researchers from Scotland and Germany has developed a way to create a polariton laser by using jellyfish proteins cultivated in E. coli cells. In their paper published in the journal Science Advances, the team describes their technique and possible uses for the result.

As most people know, at a basic level, conventional lasers work by bouncing light around inside of a cavity and then emitting identical photons as a beam. There is another type of laser that is less well known, the polariton laser—it works by tossing photons back and forth between excited molecules. But the reason it has not made its way into commercial use is because it must be cooled to an extremely low temperature to work properly. In this new approach, the researchers report the development of such a laser that works at room temperatures.

http://phys.org/news/2016-08-jellyfish-proteins-polariton-laser.html#jCp

 

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For more information on lazers and energy view our book titled "The DuPont Investigation. - Http://dupontinvestigation.blogspot.com ."

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Chapter 19: Solar, Electrical & Hydrogen power


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Making Electricity Out of Thin Air: New Device Offers Clean Energy 24/7

 

Jul 02, 2021 

 

The new technology creates electricity using moisture in the air, and it sounds too good to be true.

 

The novel device uses a natural protein to create electricity from moisture in the air since moisture actually contains a certain amount of electrical charge. The technology is renewable, non-polluting, and low-cost. Furthermore, it can generate electricity even in regions with very little humidity, such as the Sahara Desert.

 

Unlike other forms of renewable energy such as wind and solar, this new tech does not require sunlight or wind. All it needs is a thin film of protein nanowires less than 10 microns thick, and it even works indoors. According to Lovley, this is “the most amazing and exciting application of protein nanowires yet.” 

 

But how does it work?

 

The bottom of the film is supported by an electrode, while the top is supported by a smaller electrode that only covers a portion of the nanowire film. Water vapor from the environment is absorbed by the film, and the electrical conductivity and surface chemistry of the protein nanowires, as well as the tiny pores between the nanowires inside the film, create the conditions for an electrical current to flow between the two electrodes. This is how it can generate clean energy 24/7.

 

With a current density of about 17 microamperes per square centimeter, the device generates a sustained voltage of around 0.5 volts over a 7-micrometer-thick film. This is enough for the current Air-gen devices to already power small electronics. Now, the researchers are seeking to bring their innovation to a commercial scale.

 

“The ultimate goal is to make large-scale systems. For example, the technology might be incorporated into wall paint that could help power your home. Or, we may develop stand-alone air-powered generators that supply electricity off the grid..

 
https://scitechdaily.com/new-invention-generates-electricity-out-of-thin-air-offers-clean-energy-24-7/

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New shortcut to solar cells: Discovery employs electrodes as catalysts to make black silicon

May 13, 2015

An electron microscope image shows fine, light-absorbing pores and spikes created in minutes on the surface of a silicon wafer for solar cells. Gold electrodes do double duty in the black silicon process developed by scientists at Rice University by serving as a catalyst to etch the surface in minutes.



 http://phys.org/news/2015-05-shortcut-solar-cells-discovery-electrodes.html#jCp

 


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Scientists Reveal "Artificial Leaf" That Turns Carbon Into Sustainable Fuels

 

 2019

 

This technology could be huge in the future.

 

https://futurism.com/artificial-leaf-carbon-sustainable-fuel


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Revolutionary Artificial Leaf Turns CO2 Into Valuable Fuels and Chemicals

 

February 8, 2025

https://scitechdaily.com/revolutionary-artificial-leaf-turns-co2-into-valuable-fuels-and-chemicals/


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Researchers create solar cells with record energy performance

 

Jun 05, 2015 

 

http://phys.org/news/2015-06-solar-cells-energy.html?utm_source=menu&utm_medium=link&utm_campaign=item-menu

 

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Team extracts more energy from sunlight with advanced solar panels

October 7, 2020

https://scienceblog.com/team-extracts-more-energy-from-sunlight-with-advanced-solar-panels/

 

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New Light Trick in Carbon Nanotubes Could Boost Solar Power

May 9, 2025

 

Three physicists from Japan’s RIKEN Center for Advanced Photonics have uncovered how ultra-thin carbon tubes, known as carbon nanotubes, can emit light that carries more energy than the light they absorb. This surprising discovery could pave the way for new technologies in solar energy harvesting and advanced biological imaging, the journal Physical Review B reported. 

 

https://ana.ir/en/news/8899/new-light-trick-in-carbon-nanotubes-could-boost-solar-power

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Reshaping the solar spectrum to turn light to electricity
 

July 28, 2015 

 

 

- "The infrared region of the solar spectrum passes right through the photovoltaic materials that make up today's solar cells," explained Christopher Bardeen, a professor of chemistry. The research was a collaborative effort between him and Ming Lee Tang, an assistant professor of chemistry. "This is energy lost, no matter how good your solar cell. The hybrid material we have come up with first captures two infrared photons that would normally pass right through a solar cell without being converted to electricity, then adds their energies together to make one higher energy photon. This upconverted photon is readily absorbed by photovoltaic cells, generating electricity from light that normally would be wasted."Bardeen added that these materials are essentially "reshaping the solar spectrum" so that it better matches the photovoltaic materials used today in solar cells. The ability to utilize the infrared portion of the solar spectrum could boost solar photovoltaic efficiencies by 30 percent or more.

http://phys.org/news/2015-07-reshaping-solar-spectrum-electricity.html#jCp


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New way to store solar energy could lead to more common solar cell usage

 

September 15, 2015 

 

 Researchers at Missouri University of Science and Technology have developed a relatively inexpensive and simple way to split water into hydrogen and oxygen through a new electrodeposition method. The method produces highly efficient solar cells that can gather solar energy for use as fuel.

 http://phys.org/news/2015-09-solar-energy-common-cell-usage.html#jCp



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Green storage for green energy

 

Rechargeable battery to power a home from rooftop solar panels

 

Date:

September 24, 2015

 

 http://www.sciencedaily.com/releases/2015/09/150924151401.htm

Harvard researchers wanted to improve on their 2014 flow battery. Their goal was to replace the conventional bromine-bearing electrolyte with something nontoxic. In a paper released today, the team's findings "deliver the first high-performance, nonflammable, nontoxic, noncorrosive, and low-cost chemicals for flow batteries." A prototype of the battery is pictured.

Credit: Eliza Grinnell/Harvard Paulson School

A team of Harvard scientists and engineers has demonstrated a rechargeable battery that could make storage of electricity from intermittent energy sources like solar and wind safe and cost-effective for both residential and commercial use. The new research builds on earlier work by members of the same team that could enable cheaper and more reliable electricity storage at the grid level.

 

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Watch A Spray-On Solar Cell Getting Made

December 9, 2014
 

http://www.popsci.com/watch-spray-solar-cell-getting-made

 

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Nanodomains hold the key to next-generation solar cells, researchers find

2 June 2025

https://www.ceb.cam.ac.uk/news/nanodomains_hold_key

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Breakthrough in Solar-Blind Tech: Diamond Nanowires Set a New Benchmark

 

 June 22, 2025

 

https://scitechdaily.com/breakthrough-in-solar-blind-tech-diamond-nanowires-set-a-new-benchmark/ 

 

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New Understanding of Ceramic Materials May Reveal Ways to Improve Solar Panels, Superconductors, and Biomedical Implants

 

June 18, 2020

https://scitechdaily.com/new-understanding-of-ceramic-materials-may-reveal-ways-to-improve-solar-panels-superconductors-and-biomedical-implants/

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Scientists make crucial breakthrough that could revolutionize solar energy: '[This] might open up new avenues'

 

April 4, 2024

 

Sunlight is a reliable energy source to supplement our energy needs, and this recent discovery will multiply the benefits of solar power.

 

Solar panels are one of many clean energy solutions that provide much-needed electrical energy to electrical grids worldwide. Solar panels function by allowing sunlight to shine on specialized receptors known as photovoltaic cells, or PV cells, which in turn transform the energy within the sunlight into an electrical current run through wires into the grid. 

 

A research team from Shanghai University of Engineering Science in China has developed a new glass-ceramic material to increase the energy absorption of solar panels, according to The Independent. 

 

But how does this all work? Sunlight contains multiple types of light, or wavelengths, from infrared (heat), to visible (colors), and to ultraviolet (aka UV, which causes sunburns on skin). 

 

https://www.thecooldown.com/green-tech/glass-ceramic-solar-panels-energy-conversion/

 

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 Unlock Tunable Photovoltaic Effects For Next-Gen Solar Energy Solutions

Jun 26, 2025

https://medium.com/@jckapadia003/engineered-heterostructures-unlock-tunable-photovoltaic-effects-for-next-gen-solar-energy-solutions-c75f79391931

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Solar cells that can face almost any direction and keep themselves clean

 

 December 16, 2015 

 

In recent years, a complicated discussion over which direction solar cells should face—south or west—has likely left customers uncertain about the best way to orient their panels. Now researchers are attempting to resolve this issue by developing solar cells that can harvest light from almost any angle, and the panels self-clean to boot. Their report appears in the journal ACS Nano.

http://phys.org/news/2015-12-solar-cells.html

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This Solar-Powered Engine Can Be Made With A 3D Printer

 

April, 2015

 http://www.popsci.com/solar-powered-engine-can-be-made-3d-printer


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DIY 3D Solar Panel Powers Electric Motor From 2 LED Flashlights

http://www.greenoptimistic.com/ryszard-dzikowski-3d-solar-panel-20100121/#.VSHSU-G-2zk

 
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Flexible tandem solar cells achieve 24.6% efficiency and withstand 3,000 bends in new study

April 18, 2025

https://techxplore.com/news/2025-04-flexible-tandem-solar-cells-efficiency.html

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Scientists develop Highly Efficient and Stable All-Perovskite Tandem Solar Cells

2025

 

http://english.nimte.cas.cn/rh/rp/202506/t20250613_1045520.html 

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Ultrafast spin-exchange in quantum dots enhances solar energy and photochemical efficiency

June 12, 2025

Quantum dots are microscopic semiconductor crystals developed in the lab that share many properties with atoms, including the ability to absorb or emit light, a technology that Los Alamos researchers have spent nearly three decades evolving. Through carrier multiplication, in which a single absorbed photon generates two electron-hole pairs, called excitons, quantum dots have the unique ability to convert photons more efficiently to energy.

https://phys.org/news/2025-06-ultrafast-exchange-quantum-dots-solar.html

 

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Colloidal Quantum Dots Allow Solar Panels to become Sprayed on Products

 

January 9, 2022

https://science-atlas.com/technology/colloidal-quantum-dots-allow-solar-panels-to-become-sprayed-on/

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Magnesium-doped quantum dots boost perovskite/organic tandem solar cell stability

March 27, 2025

Photovoltaic (PV) solutions, which are designed to convert sunlight into electrical energy, are becoming increasingly widespread worldwide. Over the past decades, engineers specialized in energy solutions have been trying to identify new solar cell designs and PV materials that could achieve even better power conversion efficiencies, while also retaining their stability and reliably operating for long periods of time.

https://techxplore.com/news/2025-03-magnesium-doped-quantum-dots-boost.html

 

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Self-Healing Nanomaterials: Self-Repairing Electronics Are in route

September 13, 2021

 

Researchers at Case Western Reserve University say fixing scratches on cars and furniture may be cheap and easy to do yourself in the not-too-distant future. Together with partners in the USA and Switzerland, they have developed a polymer-based material that can heal itself when placed under ultraviolet light for less than a minute.

 

From the Terminator to Spiderman’s suit, self-repairing robots and devices abound in sci-fi movies. In reality, though, wear and tear reduce the effectiveness of electronic devices until they need to be replaced. What is the cracked screen of your mobile phone healing itself overnight, or the solar panels providing energy to satellites...

 

The field of self-repairing materials is rapidly expanding, and what used to be science fiction might soon become reality, thanks to Technion — Israel Institute of Technology scientists who developed eco-friendly nanocrystal semiconductors capable of self-healing. Their findings, recently published in Advanced Functional Materials, describe the process, in which a group of materials called double perovskites display self-healing properties after being damaged by the radiation of an electron beam. The perovskites, first discovered in 1839, have recently garnered scientists’ attention due to unique electro-optical characteristics that make them highly efficient in energy conversion, despite inexpensive production. A special effort has been put into the use of lead-based perovskites in highly efficient solar cells. 

https://science-atlas.com/technology/self-healing-nanomaterials-self-repairing-electronics-are-in-route/

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Highly Efficient Solar Energy Collectors Grown From Microscopic Seeds

 

June 24, 2021

 

 

 

Rice University chemical engineering graduate student Siraj Sidhik holds a container of 2D perovskite “seeds” (left) and a smaller vial containing a solution of dissolved seeds that can be used to produce thin films for use in highly efficient optoelectronic devices like high efficiency solar panels. 

 

Engineers Create Seeds for Growing Near-Perfect 2D Perovskite Crystals

 

Rice University engineers have created microscopic seeds for growing remarkably uniform 2D perovskite crystals that are both stable and highly efficient at harvesting electricity from sunlight.

 

Halide perovskites are organic materials made from abundant, inexpensive ingredients, and Rice’s seeded growth method addresses both performance and production issues that have held back halide perovskite photovoltaic technology.

 

In a study published online in Advanced Materials, chemical engineers from Rice’s Brown School of Engineering describe how to make the seeds and use them to grow homogenous thin films, highly sought materials comprised of uniformly thick layers. In laboratory tests, photovoltaic devices made from the films proved both efficient and reliable, a previously problematic combination for devices made from either 3D or 2D perovskites.

https://scitechdaily.com/highly-efficient-solar-energy-collectors-grown-from-microscopic-seeds/

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Critical nanoscale phenomena for more efficient and stable perovskite solar cells

March 7, 2025

https://www.sciencedaily.com/releases/2025/02/250226125005.htm


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New liquid crystal method makes perovskite nanocrystals easier to produce

February 23, 2025

https://knowridge.com/2025/02/new-liquid-crystal-method-makes-perovskite-nanocrystals-easier-to-produce/

 

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Organic vs. Inorganic Solar Paint: A Comparative Analysis of OPV and Perovskite Technologies

 

May 22, 2025 

 

Introduction: Painting a Brighter Future with Solar Energy

https://tayloramarel.com/2025/04/organic-vs-inorganic-solar-paint-a-comparative-analysis-of-opv-and-perovskite-technologies/

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New Transparent Electrode Developed That Boosts Solar Cell Efficiency

  

May 29, 2021

 

 

Scientists found using a chromium seed layer allowed them to grow ultrathin gold film that serves as a transparent electrode with good conductivity for perovskite solar cells. 

 

Gold-based electrodes boost semitransparent perovskite cells to record efficiency. 

 
https://scitechdaily.com/new-transparent-electrode-developed-that-boosts-solar-cell-efficiency/

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  Solar Power Towers Are 'Vaporizing' Birds

February 20, 2015



The Crescent Dunes Solar Energy Project in Nevada is set to come online in March. Once completed, it will use thousands of mirrors to focus sunlight on a tower, melting millions of pounds of salt contained inside. The molten salt will heat water into steam, which then turns turbines and generates electricity without any carbon byproducts. There’s just one little problem: During a test run on January 14, the intense heat from the mirrors reportedly incinerated and/or vaporized more than 100 birds.



Rewire reports that during the test, operators fired up a third of the 110-megawatt facility’s mirrors, concentrating sunlight on a spot 1,200 feet off the ground. Over a six-hour period, biologists counted 130 "streamers," or trails of smoke and water left behind as birds ignited and plummeted to their deaths. Rewire’s anonymous source said that at least one of the birds "turned white hot and vaporized completely."

http://www.popsci.com/solar-power-towers-are-vaporizing-birds

 

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Marine Algae Found to Harness Power of Quantum Mechanics

 February 3, 2010



Scientists still struggle to understand and harness the spooky physics of quantum mechanics, but nature may have a head start on us humans. Tiny marine algae apparently use the mysterious phenomenon called superposition -- where a particle can be in two places at the same time -- to move around solar energy they harvest through the process of photosynthesis.
This astounding find suggests that biological creatures may have adapted quantum mechanics for survival billions of years ago. It also demonstrates that quantum mechanics can prevail over classical physics even at normal temperatures, given that the algae can send energy flowing through several alternate biological paths simultaneously.

http://www.popsci.com/technology/article/2010-02/marine-algae-harness-power-quantum-mechanics


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Algae could both provide biofuel and clean up wastewater

 

 April 6, 2015

Algae may indeed be a potential source of biofuel, but it can also find use in things like nutritional supplements and cosmetics. When it's grown commercially, its growth is usually aided with chemical fertilizers. The cost of those chemicals cuts into the profits, however, plus the fertilizers are also needed for more traditional crops. That's why scientists from Houston's Rice University are looking into growing algae in municipal wastewater – the water would already contain its own free fertilizer, plus the algae would help clean it up.

 http://www.gizmag.com/algae-wastewater/36875/?li_source=LI&li_medium=default-widget


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Energy transfer between carotenoids and bacteriochlorophylls in light-harvesting complex II of purple bacteria

In photosynthetic light-harvesting systems carotenoids and chlorophylls jointly absorb light and transform its energy within about a picosecond into electronic singlet excitations of the chlorophylls only. This paper investigates this process for the light-harvesting complex II of the purple bacterium Rhodospirillum molis-chianum, for which a structure and, hence, the exact arrangement of the participating bacteriochlorophylls and carotenoids have recently become known. Based on this structure and on CI expansions of the electronic states of individual chromophores~bacteriochlorophylls and carotenoids as well as on an exciton description of a circular aggregate of bacteriochlorophylls, the excitation transfer between carotenoids and bacteriochlorophylls is described by means of Fermi’s golden rule...

http://www-s.ks.uiuc.edu/Publications/Papers/PDF/DAMJ99/DAMJ99.pdf

 

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We question the uses of genetically modified bacteria for harvesting energy. This includes BPV types of technologies, which is able tap into the power of the use of photosynthesis of living organisms and plants. Many inventors want to use biotechnology to create energy from living organisms. Many people think that this could solve the energy crisis, while others question how ethical many of these experiments are. This includes how far certain scientists are willing to go, to experiment with genetically modified organisms for a source of energy. 



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"Living furniture" could power laptops and desk lamps

 

May 3, 2012

The BPV technology is able to generate electricity by tapping into the photosynthesis of living organisms such as cyanobacteria, moss, algae and vascular plants. As the name suggests, the Moss Table incorporates an array of BPV devices which generate electricity from a cluster of moss plants. While the present amount of energy generated by the table is not enough to power the featured table-lamp, it is the envisioned goal of the project. However, the research group was able to illustrate how the same BPV technology is able to power small devices like a digital clock, by applying some of the units that operate inside the Moss Table.

http://www.gizmag.com/living-furniture-moss-table/22397/?li_source=LI&li_medium=default-widget

 

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New method for converting solar energy into electrical power using photo-bioelectrochemical cells

 

January 19, 2016

A new paradigm for the development of photo-bioelectrochemical cells has been reported in the journal Nature Energy by researchers from The Hebrew University of Jerusalem, in Israel, and the University of Bochum, in Germany.

The design of photo-bioelectrochemical cells based on native photosynthetic reaction is attracting substantial recent interest as a means for the conversion of solar light energy into electrical power.

In the natural photosynthetic apparatus, photosynthetic reaction is coupled to biocatalytic transformations leading to CO2 fixation and O2 evolution. Although significant progress has been achieved in the integration of native photosystems with electrodes for light-to-electrical energy conversion, the conjugation of the photosystems to enzymes to yield photo-bioelectrocatalytic solar cells remains a challenge.

Now, researchers report on the construction of photo-bioelectrochemical cells using the native photosynthetic reaction and the enzymes glucose oxidase or glucose dehydrogenase. The system consists of modified integrated electrodes that include the natural photosynthetic reaction center, known as photosystem I, conjugated to the enzymes glucose oxidase or glucose dehydrogenase. The native proteins are electrically wired by means of chemical electron transfer mediators. Photoirradiation of the electrodes leads to the generation of electrical power, while oxidizing the glucose substrate acting as a fuel.

The system provides a model to harness the native photosynthetic apparatus for the conversion of solar light energy into electrical power, using biomass substrates as fuels. In contrast to numerous bioelectrochemical systems using electrical power to oxidize glucose, the present study introduces the implementation of the native photosystem to produce electrical power using light as the energy source.

http://phys.org/news/2016-01-method-solar-energy-electrical-power.html

 

 
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Unveiling the nanoscale frontier: Innovating with nanoporous model electrodes

 

 Jun 02, 2023

 

 (Nanowerk News) Researchers at Tohoku University and Tsinghua University have introduced a next-generation model membrane electrode that promises to revolutionize fundamental electrochemical research. This innovative electrode, fabricated through a meticulous process, showcases an ordered array of hollow giant carbon nanotubes (gCNTs) within a nanoporous membrane, unlocking new possibilities for energy storage and electrochemical studies.

 

https://www.nanowerk.com/nanotechnology-news2/newsid=63098.php

 

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Clean Energy 24/7: Engineers Use Nanotechnology To Harvest Electricity “From Thin Air”

 

May 24, 2023

 

Engineers describe the “generic Air-gen effect”—nearly any material can be engineered with nanopores to harvest, cost-effective, scalable, interruption-free electricity.

 

Researchers at the University of Massachusetts Amherst have discovered a method to harvest continuous electricity from air humidity using any material with nanopores smaller than 100 nanometers, called the “generic Air-gen effect.” This technique, scalable and interruption-free, paves the way for a broad range of cost-effective, continuous electricity generation from various materials, overcoming limitations of condition-dependent renewables like solar and wind power.

 
https://scitechdaily.com/clean-energy-24-7-engineers-use-nanotechnology-to-harvest-electricity-from-thin-air/

 

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Scientists thread rows of metal atoms into nanofiber bundles

 

Mar 04, 2023

 

(Nanowerk News) Researchers from Tokyo Metropolitan University have successfully threaded atoms of indium metal in between individual fibers in bundles of transition metal chalcogenide nanofibers. By steeping the bundles in indium gas, rows of atoms were able to make their way in between the fibers to create a unique nanostructure via intercalation. Through simulations and resistivity measurements, individual bundles were shown to have metallic properties, paving the way for application as flexible nanowires in nanocircuitry.

 

https://www.nanowerk.com/nanotechnology-news2/newsid=62498.php



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Harnessing All-Solar Energy: Nanocrystal Breakthrough Transforms Infrared Light Conversion

 

September 15, 2023

 

 

A single copper-doped tungstic acid nanocrystal; (right) Atomic resolution image of the nanocrystal. 

 
https://scitechdaily.com/harnessing-all-solar-energy-nanocrystal-breakthrough-transforms-infrared-light-conversion/

 

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Nanoparticles Self-Assemble to Harvest Solar Energy

 

February 21, 2023

 

WASHINGTON, Feb. 21, 2023 – Solar-thermal technology is a promising environmentally friendly energy harvesting method with a potential role to play in solving the fossil fuel energy crisis.

 

The technology transforms sunlight into thermal energy, but it’s challenging to suppress energy dissipation while maintaining high absorption. Existing solar energy harvesters that rely on micro- or nanoengineering don’t have sufficient scalability and flexibility, and will require a novel strategy for high-performance solar light capture while simultaneously simplifying fabrication and reducing costs.

 
https://publishing.aip.org/publications/latest-content/nanoparticles-self-assemble-to-harvest-solar-energy/

 

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Paper-thin solar cell can turn any surface into a power source

 

December 9, 2022 

 

Researchers develop a scalable fabrication technique to produce ultrathin, lightweight solar cells that can be seamlessly added to any surface.

https://news.mit.edu/2022/ultrathin-solar-cells-1209


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New MIT metal-mesh membrane could solve longstanding problems with liquid metal displacement batteries; inexpensive grid power storage

25 January 2018

https://www.greencarcongress.com/2018/01/20180125-mesh.html


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Study: Superconductivity switches on and off in “magic-angle” graphene

 

January 30, 2023

 

 

A quick electric pulse completely flips the material’s electronic properties, opening a route to ultrafast, brain-inspired, superconducting electronics.

 

With some careful twisting and stacking, MIT physicists have revealed a new and exotic property in “magic-angle” graphene: superconductivity that can be turned on and off with an electric pulse, much like a light switch.

 

The discovery could lead to ultrafast, energy-efficient superconducting transistors for neuromorphic devices — electronics designed to operate in a way similar to the rapid on/off firing of neurons in the human brain.

 

Magic-angle graphene refers to a very particular stacking of graphene — an atom-thin material made from carbon atoms that are linked in a hexagonal pattern resembling chicken wire. When one sheet of graphene is stacked atop a second sheet at a precise “magic” angle, the twisted structure creates a slightly offset “moiré” pattern, or superlattice, that is able to support a host of surprising electronic behaviors.

 

In 2018, Pablo Jarillo-Herrero and his group at MIT were the first to demonstrate magic-angle twisted bilayer graphene. They showed that the new bilayer structure could behave as an insulator, much like wood, when they applied a certain continuous electric field. When they upped the field, the insulator suddenly morphed into a superconductor, allowing electrons to flow, friction-free.

 

That discovery was a watershed in the field of “twistronics,” which explores how certain electronic properties emerge from the twisting and layering of two-dimensional materials. Researchers including Jarillo-Herrero have continued to reveal surprising properties in magic-angle graphene, including various ways to switch the material between different electronic states. So far, such “switches” have acted more like dimmers, in that researchers must continuously apply an electric or magnetic field to turn on superconductivity, and keep it on.

 

Now Jarillo-Herrero and his team have shown that superconductivity in magic-angle graphene can be switched on, and kept on, with just a short pulse rather than a continuous electric field. The key, they found, was a combination of twisting and stacking.

 

In a paper appearing today in Nature Nanotechnology, the team reports that, by stacking magic-angle graphene between two offset layers of boron nitride — a two-dimensional insulating material — the unique alignment of the sandwich structure enabled the researchers to turn graphene’s superconductivity on and off with a short electric pulse.

 

“For the vast majority of materials, if you remove the electric field, zzzzip, the electric state is gone,” says Jarillo-Herrero, who is the Cecil and Ida Green Professor of Physics at MIT. “This is the first time that a superconducting material has been made that can be electrically switched on and off, abruptly. This could pave the way for a new generation of twisted, graphene-based superconducting electronics.”

 

https://news.mit.edu/2023/study-superconductivity-switches-and-magic-angle-graphene-0130

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Physicists discover a “family” of robust, superconducting graphene structures

 

July 8, 2022

 

The findings could inform the design of practical superconducting devices.

When it comes to graphene, it appears that superconductivity runs in the family.

 

Graphene is a single-atom-thin material that can be exfoliated from the same graphite that is found in pencil lead. The ultrathin material is made entirely from carbon atoms that are arranged in a simple hexagonal pattern, similar to that of chicken wire. Since its isolation in 2004, graphene has been found to embody numerous remarkable properties in its single-layer form.

 

In 2018, MIT researchers found that if two graphene layers are stacked at a very specific “magic” angle, the twisted bilayer structure could exhibit robust superconductivity, a widely sought material state in which an electrical current can flow through with zero energy loss. Recently, the same group found a similar superconductive state exists in twisted trilayer graphene — a structure made from three graphene layers stacked at a precise, new magic angle.

 

Now the team reports that — you guessed it — four and five graphene layers can be twisted and stacked at new magic angles to elicit robust superconductivity at low temperatures. This latest discovery, published this week in Nature Materials,  establishes the various twisted and stacked configurations of graphene as the first known “family” of multilayer magic-angle superconductors. The team also identified similarities and differences between graphene family members.

 

The findings could serve as a blueprint for designing practical, room-temperature superconductors. If the properties among family members could be replicated in other, naturally conductive materials, they could be harnessed, for instance, to deliver electricity without dissipation or build magnetically levitating trains that run without friction.

 

“The magic-angle graphene system is now a legitimate ‘family,’ beyond a couple of systems,” says lead author Jeong Min (Jane) Park, a graduate student in MIT’s Department of Physics. “Having this family is particularly meaningful because it provides a way to design robust superconductors.”

https://news.mit.edu/2022/superconducting-graphene-family-0708

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At the Magic Angle, a Mysterious Vibration Emerges – And It Might Explain Superconductivity

 

April 24, 2025

 

Scientists have unveiled a cutting-edge quantum microscope that allows them to observe how electrons interact with strange atomic vibrations in twisted graphene, including a newly revealed “phason.”

 

This phenomenon could help explain mysterious behaviors like superconductivity in materials rotated to the “magic angle.” The breakthrough, made possible by operating the microscope at cryogenic temperatures, marks a major leap in studying quantum materials and opens the door to future discoveries in computing and electronics.

 

https://scitechdaily.com/at-the-magic-angle-a-mysterious-vibration-emerges-and-it-might-explain-superconductivity/

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“Truly Mind-Boggling” Breakthrough: Graphene Surprise Could Help Generate Hydrogen Cheaply and Sustainably

25 August 2023

https://www.stardrive.org/index.php/sd-science-news/66646-truly-mind-boggling-breakthrough-graphene-surprise-could-help-generate-hydrogen-cheaply-and-sustainably

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Ten-Fold Enhancement of InAs Nanowire Photoluminescence Emission with an InP Passivation Layer

 

May 23, 2017

 

Abstract

 

In this Letter, we demonstrate that a significant improvement of optical performance of InAs nanowires can be achieved by capping the core InAs nanowires with a thin InP shell, which successfully passivates the surface states reducing the rate of nonradiative recombination. The improvements have been confirmed by detailed photoluminescence measurements, which showed up to a 10-fold increase in the intensity of room-temperature photoluminescence from the capped InAs/InP nanowires compared to the sample with core-only InAs nanowires. Moreover, the nanowires exhibit a high stability of total photoluminescence emission strength across temperature range from 10 to 300 K as a result of strong quantum confinement. These findings could be the key to successful implementation of InAs nanowires into optoelectronic devices. 

 
https://pubs.acs.org/doi/full/10.1021/acs.nanolett.7b00803

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Research has found that electronic bridges allow for rapid energy sharing between semiconductors

2024/8/15

 

Researchers have found that electrons play a surprising role in heat transfer between semiconductor layers, which is of great significance for the next generation of electronic devices.

 

As semiconductor devices become smaller, researchers are exploring the potential applications of two-dimensional (2D) materials in transistors and optoelectronics. Controlling the flow of electricity and heat through these materials is key to their functionality, but first we need to understand the details of these behaviors at the atomic scale.

 

Now, researchers have found that electrons play a surprising role in energy transfer between the 2D semiconductor material tungsten diselenide (WSe2) and tungsten disulfide (WS2) layers. Researchers have found that although these layers are not tightly bonded to each other, electrons provide a bridge between them, promoting rapid heat transfer.

 

Our work suggests that we need to go beyond the analogy of LEGO bricks to understand stacks of different 2D materials, even if these layers are not firmly bonded to each other, "said Archana Raja, a scientist at the Lawrence Berkeley National Laboratory (Berkeley Lab) of the US Department of Energy (DOE). In fact, seemingly different layers communicate through shared electronic paths, allowing us to access and ultimately design properties greater than the sum of the parts.

https://en.nordicabio.com/article/6.html

 

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Graphene’s New Best Friend: UV Tape That Transfers Wonder Materials Without the Hassle

 

February 9, 2024

 
Researchers create UV-sensitive tape that can transfer 2D materials like graphene in an easier, cheaper, and less damaging way.


https://scitechdaily.com/graphenes-new-best-friend-uv-tape-that-transfers-wonder-materials-without-the-hassle/

 

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Sub-molecular diagnostics of coherent energy transfer

 

14 July 2022

Sub-molecular spectroscopy enables the real-space study of incoherent and coherent electronic energy transfer in artificial molecular donor–acceptor systems and their dependence on the molecular arrangement.

https://www.nature.com/articles/s41565-022-01171-8

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Quantum Dots Rebuilt by Light in a Trillionth of a Second

April 2, 2025

 

Argonne scientists have unveiled new methods for controlling material properties.

 

The breakthrough enables researchers to design materials with customized properties, offering unprecedented control over their optical and electronic behaviors.

Imagine building a Lego tower with perfectly aligned blocks, each block representing an atom in a crystal called a quantum dot. Just as a small bump can shift the blocks and alter the tower’s structure, external forces can rearrange the atoms in a quantum dot, disrupting its symmetry and changing its physical properties.

 

Researchers have discovered that this symmetry isn’t just something to avoid—it can be controlled. Scientists can deliberately break or restore symmetry in quantum dots to engineer materials with entirely new behaviors. In a recent study, researchers at the U.S. Department of Energy’s (DOE) Argonne National Laboratory demonstrated how light can be used to rearrange atoms within these nanoscale structures.

https://advancedcarbonscouncil.org/blogpost/2151389/509470/Quantum-Dots-Rebuilt-by-Light-in-a-Trillionth-of-a-Second



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Scientists Just Unlocked a Mind-Bending Way to Control Electrons

 

March 11, 2025

 

Scientists have discovered a groundbreaking way to control electrons using twisted crystal lattices—without directly touching them. This mind-bending technique could unlock new quantum materials and even revolutionize superconductors. But how does it work?

 

Researchers at ETH Zurich have developed a groundbreaking technique to manipulate electrons within materials using artificial crystal lattices. By leveraging moiré materials, created by twisting ultra-thin atomic layers, they have found a way to influence electron behavior in a nearby semiconductor without directly altering its physical properties.  

https://dailygalaxy.com/2025/03/scientists-uncover-way-control-electrons/

 

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Quantum Dots Reinvented: How a Crystal Layer Solves Their Biggest Problem

 

March 9, 2025

 

New research from the University of Oklahoma addresses and resolves light emission challenges commonly encountered in quantum applications.

 

Quantum light sources are inherently unstable, often flickering like distant stars or dimming over time. However, new research from the University of Oklahoma demonstrates that covering a type of quantum light source, known as a colloidal quantum dot, with a specialized layer can significantly enhance its stability. This breakthrough could pave the way for more reliable and cost-effective quantum technologies.

 

Quantum dots (QDs) are incredibly small semiconductor particles. To illustrate their scale, if a single QD were enlarged to the size of a baseball, a baseball would be as large as the Moon. These nanomaterials have a wide range of applications, including computer monitors, LEDs, solar cells, biomedical devices, quantum computing, and secure communication.

 

The study, led by OU Assistant Professor Yitong Dong, reveals that applying a crystallized molecular layer to perovskite-based QDs effectively neutralizes surface defects and stabilizes their atomic structure. This prevents the common issues of blinking and fading, ensuring a consistent and reliable light output.

 
https://scitechdaily.com/quantum-dots-reinvented-how-a-crystal-layer-solves-their-biggest-problem/

 

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Electrons on Demand: Scientists Unlock the Secret of Light-Driven Charge Control

 

March 6, 2025

 

Researchers have unlocked a new way to manipulate electrons in molecules with terahertz light, paving the way for faster electronics, efficient solar cells, and next-gen materials.

 

Their work reveals a method to precisely control excitons and charge movement at an atomic level, leading to major advances in energy and chemical technologies.

https://scitechdaily.com/electrons-on-demand-scientists-unlock-the-secret-of-light-driven-charge-control/

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Scientists Develop an “Extended Landau Free Energy Model” for Advanced Materials Design

November 29, 2022

 

In a recent breakthrough, a research team succeeded in automating the interpretation of microscopic image data of nanoscale magnetic materials using an “extended Landau free energy model” that the team developed using a combination of topology, data science, and free energy. 

 

Microscopic materials analysis is essential to achieve desirable performance in next-generation nanoelectronic devices, such as low power consumption and high speeds. However, the magnetic materials involved in such devices often exhibit incredibly complex interactions between nanostructures and magnetic domains. This, in turn, makes functional design challenging.

 

Traditionally, researchers have performed a visual analysis of the microscopic image data. However, this often makes the interpretation of such data qualitative and highly subjective. What is lacking is a causal analysis of the mechanisms underlying the complex interactions in nanoscale magnetic materials.

https://scitechdaily.com/scientists-develop-an-extended-landau-free-energy-model-for-advanced-materials-design/

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New techniques for aligning nanocrystals enhance solar-cell efficiency and LED performance

February 27, 2025

https://phys.org/news/2025-02-techniques-aligning-nanocrystals-solar-cell.html


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Brave North Carolina town fights back against sun-sucking solar panels

 

December 14, 2015

Congratulations to the town of Woodland, North Carolina! They are turning back the tide of insidious solar. They have voted for a complete moratorium on solar farms, after hearing from a retired science teacher, Jane Mann. According to the Roanoke-Chowan News-Herald:

 

She is a retired Northampton science teacher and is concerned that photosynthesis, which depends upon sunlight, would not happen and would keep the plants from growing. She said she has observed areas near solar panels where the plants are brown and dead because they did not get enough sunlight. She also questioned the high number of cancer deaths in the area, saying no one could tell her that solar panels didn’t cause cancer.

http://www.treehugger.com/solar-technology/brave-north-carolina-town-fights-back-against-sun-sucking-solar-panels.html

 

 

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Magnetic Effect of Light Could Lead to New Solar Panels Technology

 

April 19, 2011


http://www.greenoptimistic.com/magnetic-effect-light-solar-energy-20110419/

 

 
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Sun-Powered Whirlwinds Spin The Solar Vortex, Results Cheaper Energy

March 7, 2013


Whirlwinds are being used to create electricity in Atlanta, at the Georgia Institute of Technology. Mark Simpson and Ari Glezer have built a device that harnesses the temperature difference between a hot metal sheet on the ground and the cooler air a meter above.


http://www.greenoptimistic.com/whirlwinds-solar-vortex-energy-20130307/

 

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Producing electrical power with cardboard, tape, and a pencil

 

January 26, 2016

A small device made from everyday materials can generate enough energy to power several diodes. This clever discovery by an EPFL postdoctoral student was presented yesterday at a global conference on micro- and nano- systems in Shanghai.



http://phys.org/news/2016-01-electrical-power-cardboard-tape-pencil.html




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Sunlight and seawater lead to low-cost green hydrogen and clean water

April 9, 2025

A Cornell-led collaboration has hit the trifecta of sustainability technology: The group developed a low-cost method to produce carbon-free "green" hydrogen via solar-powered electrolysis of seawater. A happy byproduct of the process? Potable water.

https://techxplore.com/news/2025-04-sunlight-seawater-green-hydrogen.html

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Study shows making hydrogen with soda cans and seawater is scalable and sustainable

June 3, 2025

Hydrogen has the potential to be a climate-friendly fuel since it doesn’t release carbon dioxide when used as an energy source. Currently, however, most methods for producing hydrogen involve fossil fuels, making hydrogen less of a “green” fuel over its entire life cycle.

A new process developed by MIT engineers could significantly shrink the carbon footprint associated with making hydrogen.

Last year, the team reported that they could produce hydrogen gas by combining seawater, recycled soda cans, and caffeine. The question then was whether the benchtop process could be applied at an industrial scale, and at what environmental cost.

Now, the researchers have carried out a “cradle-to-grave” life cycle assessment, taking into account every step in the process at an industrial scale. For instance, the team calculated the carbon emissions associated with acquiring and processing aluminum, reacting it with seawater to produce hydrogen, and transporting the fuel to gas stations, where drivers could tap into hydrogen tanks to power engines or fuel cell cars. They found that, from end to end, the new process could generate a fraction of the carbon emissions that is associated with conventional hydrogen production.

In a study appearing today in Cell Reports Sustainability, the team reports that for every kilogram of hydrogen produced, the process would generate 1.45 kilograms of carbon dioxide over its entire life cycle. In comparison, fossil-fuel-based processes emit 11 kilograms of carbon dioxide per kilogram of hydrogen generated.

The low-carbon footprint is on par with other proposed “green hydrogen” technologies, such as those powered by solar and wind energy.

“We’re in the ballpark of green hydrogen,” says lead author Aly Kombargi PhD ’25, who graduated this spring from MIT with a doctorate in mechanical engineering. “This work highlights aluminum’s potential as a clean energy source and offers a scalable pathway for low-emission hydrogen deployment in transportation and remote energy systems.”

https://climate.mit.edu/posts/study-shows-making-hydrogen-soda-cans-and-seawater-scalable-and-sustainable



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New efficiency record for solar hydrogen production is 14 percent

 

September 15, 2015 

 

http://phys.org/news/2015-09-efficiency-solar-hydrogen-production-percent.html

 

 An international team has succeeded in considerably increasing the efficiency for direct solar water splitting with a tandem solar cell whose surfaces have been selectively modified. The new record value is 14 percent and thus tops the previous record of 12.4 percent, broken now for the first time in 17 years. Researchers from Helmholtz-Zentrum Berlin, TU Ilmenau, Fraunhofer ISE and California Institute of Technology participated in the collaboration. The results are published in Nature Communications.

Solar energy is abundantly available globally, but unfortunately not constantly and not everywhere. One especially interesting solution for storing this energy is artificial photosynthesis. This is what every leaf can do, namely converting sunlight to chemical energy. That can take place with artificial systems based on semiconductors as well. These use the electrical power that sunlight creates in individual semiconductor components to split water into oxygen and hydrogen. Hydrogen possesses very high energy density, can be employed in many ways and could replace fossil fuels. In addition, no carbon dioxide harmful to the climate is released from hydrogen during combustion, instead only water. Until now, manufacturing of solar hydrogen at the industrial level has failed due to the costs, however. This is because the efficiency of artificial photosynthesis, i.e. the energy content of the hydrogen compared to that of sunlight, has simply been too low to produce hydrogen from the sun.

 


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Study advances hydrogen production efforts

 

December 22, 2015 

 

 NREL's scientists took a different approach to the PEC process, which uses solar energy to split water into hydrogen and oxygen. The process requires special semiconductors, the PEC materials and catalysts to split the water. Previous work used precious metals such as platinum, ruthenium and iridium as catalysts attached to the semiconductors. A large-scale commercial effort using those precious metals wouldn't be cost-effective, however.

The use of cheaper molecular catalysts instead of precious metals has been proposed, but these have encountered issues with stability, and were found to have a lifespan shorter than the metal-based catalysts.

Instead, the NREL researchers decided to examine molecular catalysts outside of the liquid solution they are normally studied in to see if they could attach the catalyst directly onto the surface of the semiconductor. They were able to put a layer of titanium dioxide (TiO2) on the surface of the semiconductor and bond the molecular catalyst to the TiO2.

Their work showed molecular catalysts can be as highly active as the precious metal-based catalysts.

Their research, "Water Reduction by a p-GaInP2 Photoelectrode Stabilized by an Amorphous TiO2 Coating and a Molecular Cobalt Catalyst," has been published in Nature Materials. Jing Gu and Yong Yan are lead authors of the paper. Contributors James Young, Nathan Neale and John Turner are all with NREL's Chemistry and Nanoscience Center. Contributor K. Xerxes Steirer is with NREL's Materials Science Center.


 http://phys.org/news/2015-12-advances-hydrogen-production-efforts.html?utm_source=menu&utm_medium=link&utm_campaign=item-menu

 

 
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First nanoscale look at a reaction that limits the efficiency of generating clean hydrogen fuel

May 5 2021

 

 An international team of researchers from Stanford and the DOE's SLAC Laboratory developed a suite of advanced tools to break through the bottleneck of oxygen evolution reaction which today is only about 75% efficient and uses precious metal catalysts. These tools improve other energy-related processes such as finding ways to make lithium-ion batteries charge faster. Researchers will use the techniques developed toward other energy-related reactions such as fast charging in battery electrodes, carbon dioxide reduction for carbon capture and oxygen reduction to use hydrogen in fuel cells.

 

https://cars.stanford.edu/news/first-nanoscale-look-reaction-limits-efficiency-generating-clean-hydrogen-fuel

 

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New nanomaterial helps obtain hydrogen from a liquid energy carrier, in a key step toward a stable and clean fuel source

 

December 22, 2020

 

Hydrogen is a sustainable source of clean energy that avoids toxic emissions and can add value to multiple sectors in the economy including transportation, power generation, metals manufacturing, among others. Technologies for storing and transporting hydrogen bridge the gap between sustainable energy production and fuel use, and therefore are an essential component of a viable hydrogen economy. But traditional means of storage and transportation are expensive and susceptible to contamination. As a result, researchers are searching for alternative techniques that are reliable, low-cost and simple. More-efficient hydrogen delivery systems would benefit many applications such as stationary power, portable power, and mobile vehicle industries.

 

Now, as reported in the journal Proceedings of the National Academy of Sciences, researchers have designed and synthesized an effective material for speeding up one of the limiting steps in extracting hydrogen from alcohols. The material, a catalyst, is made from tiny clusters of nickel metal anchored on a 2-D substrate. The team led by researchers at Lawrence Berkeley National Laboratory’s (Berkeley Lab) Molecular Foundry found that the catalyst could cleanly and efficiently accelerate the reaction that removes hydrogen atoms from a liquid chemical carrier. The material is robust and made from earth-abundant metals rather than existing options made from precious metals, and will help make hydrogen a viable energy source for a wide range of applications.

https://sciencebulletin.org/new-nanomaterial-helps-obtain-hydrogen-from-a-liquid-energy-carrier-in-a-key-step-toward-a-stable-and-clean-fuel-source/

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Solar-powered hydrogen generation using two of the most abundant elements on Earth

 

June 23, 2015

 One potential clean energy future requires an economical, efficient, and relatively simple way to generate copious amounts of hydrogen for use in fuel-cells and hydrogen-powered vehicles. Often achieved by using electricity to split water molecules into hydrogen and oxygen, the ideal method would be to mine hydrogen from water using electricity generated directly from sunlight without the addition of any external power source. Hematite – the mineral form of iron – used in conjunction with silicon has shown some promise in this area, but low conversion efficiencies have slowed research. Now scientists have discovered a way to make great improvements, giving hope to using two of the most abundant elements on earth to efficiently produce hydrogen.

 http://www.gizmag.com/hydrogen-hematite-silicon-solar/38121/?li_source=LI&li_medium=default-widget

 

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Turning tap water into hydrogen: New strategy lets PEM electrolyzers use impure water

 

June 26, 2025

https://www.lifetechnology.com/blogs/life-technology-technology-news/turning-tap-water-into-hydrogen-new-strategy-lets-pem-electrolyzers-use-impure-water

 

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New porous material promising for making renewable energy from water

 

22 March 2021

One prospective source of renewable energy is hydrogen gas produced from water with the aid of sunlight. Researchers at LiU have developed a material, nanoporous cubic silicon carbide, that exhibits promising properties to capture solar energy and split water for hydrogen gas production.  

https://liu.se/en/news-item/nytt-porost-material-for-att-gora-fornybar-energi-fran-vatten 

 

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New approach to engineering crumpled GO membranes for separating hydrogen and other gases

 

July 25, 2025

 

Scanning electron microscopy image of the crumpled graphene oxide membrane, showing the formation of nanoscale wrinkles and curved channels that enhance gas transport. 

 

The reliable separation of some gases from others could be highly advantageous for a wide range of applications. For instance, it could help to produce hydrogen (H₂) for fuel cells and chemical applications or to capture the carbon dioxide (CO₂) emitted by industrial sites. 

 

Many existing methods for separating gases rely on so-called gas separation membranes, thin films that allow specific gases to pass through them, while blocking others. One of the most promising materials for fabricating these membranes is graphene oxide (GO), a derivative of graphene that responds differently when exposed to distinct molecules.

 

Despite their potential for separating gases, conventional GO-based gas separation membranes suffer from low permeability. This essentially means that while they can separate H₂ or CO₂, gases move through them too slowly for them to be reliably deployed in real-world settings.

 

Researchers at the National University of Singapore recently introduced a new approach to creating crumpled GO membranes that exhibit both a higher H₂ permeability and selectivity (i.e., ability to distinguish between different gases). Their proposed method, outlined in a paper published in Nature Nanotechnology, could facilitate the real-world use of these membranes to produce clean H₂ and capture gases that are harmful for the environment.

 

https://phys.org/news/2025-07-approach-crumpled-membranes-hydrogen-gases.html

 

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Pt nano-catalyst with graphene pockets enhances fuel cell durability and efficiency

April 11, 2025

 

Bright-field scanning transmission electron microscopy (STEM) image highlighting the ultrafine platinum nanoparticles. Right: Electron energy loss spectroscopy (EELS) elemental mapping of carbon, illustrating the thin graphene layer encapsulating the platinum nanoparticles, corresponding to the left image location.

 

https://phys.org/news/2025-04-pt-nano-catalyst-graphene-pockets.html

 

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More Graphene Magic Starts When Flatness Ends: A Proton Permeability Puzzle Solved!

 

August 23, 2023

 

Researchers uncover graphene’s intrinsic proton permeability, offering a potential boost to the hydrogen economy and green hydrogen production.

 

Researchers from The University of Manchester and the University of Warwick have unraveled the longstanding mystery of why graphene’s permeability to protons significantly surpasses theoretical expectations.

 

A decade ago, scientists at The University of Manchester made the surprising discovery that graphene is permeable to protons, the nuclei of hydrogen atoms. This unexpected result threw the scientific community into debate, as established theory had predicted that it would take billions of years for a proton to pass through graphene’s densely packed crystalline structure. Consequently, it was theorized that the protons might be traversing through minute pinholes present in the graphene, rather than the crystal lattice.

 
https://scitechdaily.com/more-graphene-magic-starts-when-flatness-ends-a-proton-permeability-puzzle-solved/

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Researchers Use Nanoparticles to Split Water into Hydrogen and Oxygen

 

December 16, 2013

 

https://scitechdaily.com/researchers-use-nanoparticles-split-water-hydrogen-oxygen/ 

 

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Machinery of Photosynthesis Supercharges Solar Energy to Hydrogen Fuel Conversion

 

August 17, 2020

 

 

Researchers are using artificial intelligence to find compounds with high solar-to-chemical conversions. They combine plant proteins with nanoparticles to create a promising artificial system for water oxidation and increased photocurrent production. 

 

Global economic growth comes with increasing demand for energy, but stepping up energy production can be challenging. Recently, scientists have achieved record efficiency for solar-to-fuel conversion, and now they want to incorporate the machinery of photosynthesis to push it further. 

 
https://scitechdaily.com/machinery-of-photosynthesis-supercharges-solar-energy-to-hydrogen-fuel-conversion/

 

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Electrochemically Grown Ultrathin Platinum Nanosheet Electrodes with Ultralow Loadings for Energy-Saving and Industrial-Level Hydrogen Evolution

 

03 June 2023 

 

Highlights

 

• 4-nm-thick Pt nanosheets (Pt-NSs) are electrochemically grown on Ti substrates for hydrogen evolution reactions.

• Highly uniform Pt-NS surface coverage with an ultralow loading of 0.015 mg_Pt cm⁻² is achieved.

• 99.5% catalyst savings and about 237-fold higher catalyst utilization are demonstrated.

 

Abstract

Nanostructured catalyst-integrated electrodes with remarkably reduced catalyst loadings, high catalyst utilization and facile fabrication are urgently needed to enable cost-effective, green hydrogen production via proton exchange membrane electrolyzer cells (PEMECs). Herein, benefitting from a thin seeding layer, bottom-up grown ultrathin Pt nanosheets (Pt-NSs) were first deposited on thin Ti substrates for PEMECs via a fast, template- and surfactant-free electrochemical growth process at room temperature, showing highly uniform Pt surface coverage with ultralow loadings and vertically well-aligned nanosheet morphologies. Combined with an anode-only Nafion 117 catalyst-coated membrane (CCM), the Pt-NS electrode with an ultralow loading of 0.015 mg_Pt cm⁻² demonstrates superior cell performance to the commercial CCM (3.0 mg_Pt cm⁻²), achieving 99.5% catalyst savings and more than 237-fold higher catalyst utilization. The remarkable performance with high catalyst utilization is mainly due to the vertically well-aligned ultrathin nanosheets with good surface coverage exposing abundant active sites for the electrochemical reaction. Overall, this study not only paves a new way for optimizing the catalyst uniformity and surface coverage with ultralow loadings but also provides new insights into nanostructured electrode design and facile fabrication for highly efficient and low-cost PEMECs and other energy storage/conversion devices.

 

https://link.springer.com/article/10.1007/s40820-023-01117-2 

 

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Catalysis Reinvented: New Ultra-Thin Nanosheets To Drive Green Energy

 

 November 26, 2024

 

Nagoya University researchers have pioneered a surfactant-based method to create amorphous nanosheets, enabling production from previously inaccessible materials like aluminum and rhodium oxides.

Researchers at Nagoya University in Japan have addressed a significant challenge in nanosheet technology. Their innovative approach employs surfactants to produce amorphous nanosheets from various materials, including difficult-to-synthesize ultra-thin amorphous metal oxides such as aluminum and rhodium. This breakthrough, published in Nature Communications, sets the stage for future advances in the application of these nanosheets such as those used within fuel cells.

https://scitechdaily.com/catalysis-reinvented-new-ultra-thin-nanosheets-to-drive-green-energy/

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Designer silicon nanowires can produce hydrogen from water and light

February 22nd, 2023

Carolina researchers' recent findings may represent a new pathway toward efficient and potentially cheap production of hydrogen fuel from sunlight.

https://www.unc.edu/posts/2023/02/22/designer-silicon-nanowires-can-produce-hydrogen-from-water-and-light/

 

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Double-Duty: New Catalyst Generates Hydrogen Fuel While Cleaning Up Wastewater

 

April 4, 2021

 

 

 

Researchers developed a catalyst that not only removes contaminants like medications from wastewater but also produces hydrogen fuel as a valuable byproduct. 

 

Turning Wastewater into Hydrogen Fuel with Sunlight

 

Hydrogen is a pollution-free energy source when it’s extracted from water using sunlight instead of fossil fuels. But current strategies for “splitting” or breaking apart water molecules with catalysts and light require the introduction of chemical additives to expedite the process. Now, researchers reporting in ACS ES&T Engineering have developed a catalyst that destroys medications and other compounds already present in wastewater to generate hydrogen fuel, getting rid of a contaminant while producing something useful.

 
https://scitechdaily.com/double-duty-new-catalyst-generates-hydrogen-fuel-while-cleaning-up-wastewater/

 

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Researchers use biosolids to produce hydrogen from wastewater

24 Sep, 2020

 

RMIT researchers have developed and patented a new technology which uses a special material derived from biosolids to spark chemical reactions for producing hydrogen from biogas.

 

The approach means all the materials needed for hydrogen production could be sourced on-site at a wastewater treatment plant, without the need for expensive catalysts.

 

The method also traps the carbon found in biosolids and biogas, which could in the future enable a near-zero-emission wastewater sector.

 

Lead researcher Associate Professor Kalpit Shah said existing commercial methods for producing hydrogen were emission and capital-intensive, and relied heavily on natural gas.

 

The new method for producing hydrogen can also convert the carbon found in biogas and biosolids into advanced carbon nanomaterials, pictured here magnified 50,000 times.

 
https://greenreview.com.au/energy/researchers-use-biosolids-to-produce-hydrogen-from-wastewater/

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Nano-sponges of solid acid transform carbon dioxide to fuel and plastic waste to chemicals

 

03-Aug-2020


https://www.chemeurope.com/en/news/1167422/nano-sponges-of-solid-acid-transform-carbon-dioxide-to-fuel-and-plastic-waste-to-chemicals.html

 

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A device to convert plastic waste into fuel

 

2025

 

Specifically, the researchers are using a method known as pyrolysis, a process of using heat in the absence of oxygen to molecularly break materials down. In this case, it’s used to break plastics down to the components that produce fuels and other products.  

 

https://engineering.yale.edu/news-and-events/news/device-convert-plastic-waste-fuel

 

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Advances in ceramic electrochemical cells promise more reliable hydrogen production and clean energy storage

May 14, 2025

Advances in ceramic electrochemical cells promise more reliable hydrogen production and clean energy storage

Researchers from the University of Oklahoma have made significant advances in a promising technology for efficient energy conversion and chemical processing. Two recent studies involving protonic ceramic electrochemical cells, called PCECs, address significant challenges in electrochemical manufacturing and efficiency. These innovations are a crucial step toward reliable and affordable solutions for hydrogen production and clean energy storage.

The studies were led by Hanping Ding, Ph.D., an assistant professor in the School of Aerospace and Mechanical Engineering at the University of Oklahoma.

https://hydrogen-central.com/advances-in-ceramic-electrochemical-cells-promise-more-reliable-hydrogen-production-and-clean-energy-storage/

 

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This triple-layer sunlight catalyst supercharges green hydrogen by 800%

 

 June 23, 2025

 

Researchers in Sweden have developed a powerful new material that dramatically boosts the ability to create hydrogen fuel from water using sunlight, making the process eight times more effective than before. This breakthrough could be key to fueling heavy transport like ships and planes with clean, renewable energy.

https://www.sciencedaily.com/releases/2025/06/250623072757.htm

 

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Hydrogen fuel at half the cost? Scientists reveal a game-changing catalyst

 

June 20, 2025

 

Scientists developed a new tunable boron-doped cobalt phosphide catalyst with low cost and high efficiency for electrochemical water-splitting.

https://www.sciencedaily.com/releases/2025/06/250620231645.htm

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Core-shell nanocluster catalyst enables high-efficiency, low-cost and eco-friendly hydrogen production

March 21, 2025

A Korean research team has successfully developed an advanced electrochemical catalyst. This innovation is expected to lead the next generation of sustainable hydrogen production.

The newly developed catalyst features a ruthenium (Ru)-based nanocluster with a core-shell structure. Despite using only a minimal amount of precious metal, it delivers world-class performance and exceptional stability. Moreover, when applied to industrial-scale water electrolysis equipment, it demonstrated remarkable efficiency, highlighting its potential for commercial applications.

This research was published in Energy & Environmental Science.

Hydrogen is widely regarded as a clean energy source because it does not emit carbon dioxide when burned, making it a promising alternative to fossil fuels. One of the most efficient ways to produce eco-friendly hydrogen is through water electrolysis, which splits water into hydrogen and oxygen using electricity.

Among various electrolysis methods, anion exchange membrane water electrolysis (AEMWE) is gaining attention as a next-generation technology due to its ability to produce high-purity hydrogen. However, for AEMWE to be commercially viable, it requires catalysts that offer both high efficiency and long-term stability.

Currently, platinum (Pt) is the most widely used catalyst for hydrogen production, but its high cost and rapid degradation present significant challenges. While researchers have explored non-precious metal alternatives, these materials typically suffer from low efficiency and poor stability, making them unsuitable for industrial use.

https://www.ipmi.org/news/core-shell-nanocluster-catalyst-enables-high-efficiency-low-cost-and-eco-friendly-hydrogen

 

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Platinum-calcium alloy nanoparticles replace platinum, achieving both efficiency and durability in fuel cells

 

August 4, 2025 

 

https://phys.org/news/2025-08-platinum-calcium-alloy-nanoparticles-efficiency.html 

 

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Scandium superhighway paves way for low-temperature hydrogen fuel cells

  

August 8, 2025

 

https://techxplore.com/news/2025-08-scandium-superhighway-paves-temperature-hydrogen.html

 

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New Catalyst Breakthrough Slashes Platinum Use in Green Hydrogen Tech

 

July 23, 2025 

 

Researchers engineered a graphene-encased catalyst with ultra-low platinum use that delivers high-efficiency, industrial-scale hydrogen production.

 

Proton exchange membrane (PEM) water electrolysis plays a key role in the production of green hydrogen on a large scale. One of the most commonly used materials in this process is Platinum on Carbon (Pt/C), which serves as an advanced cathode catalyst. Its popularity comes from its ability to effectively bind hydrogen and its strong resistance to acidic environments. However, using high amounts of platinum makes this approach expensive and limits its broader adoption.

 

https://scitechdaily.com/new-catalyst-breakthrough-slashes-platinum-use-in-green-hydrogen-tech/ 

 

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Record efficiency for converting solar energy to hydrogen without rare metals

 

December 8, 2014

Using solar energy to split water into its component parts, thereby allowing the solar energy to be stored as hydrogen fuel, generally involves one of two methods: using photoelectrochemical cells to directly split the water, or using solar cells to produce electricity to power an electrolyzer that separates the water molecules. One problem associated with the latter method is that it currently relies on rare metals. But now scientists from Ecole Polytechnique Federale de Lausanne (EPFL) in Switzerland have managed to do so using common materials, and have achieved a record solar energy to hydrogen conversion efficiency in the process.

 http://www.gizmag.com/record-efficiency-solar-water-splitting/35044/?li_source=LI&li_medium=default-widget

 

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Scientists create water splitter that runs on a single AAA battery

 

August 25, 2014


A new emissions-free device created by scientists at Stanford University uses an ordinary 1.5-volt battery to split water into hydrogen and oxygen at room temperature, potentially providing a low-cost method to power fuel cells in zero-emissions vehicles and buildings.

http://www.gizmag.com/water-splitter-aaa-battery-hydrogen-fuel-cell/33497/?li_source=LI&li_medium=default-widget

 
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Hydrogen fuel cells may turn corner in commercial drone use

 

December 16, 2015
 

http://techxplore.com/news/2015-12-hydrogen-fuel-cells-corner-commercial.html

 
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Researchers discover way to store hydrogen using lignin jet fuel

January 27, 2025

An international team of scientists has discovered a way to store and release volatile hydrogen using lignin-based jet fuel that could open new pathways for sustainable energy production.

In a new study in the International Journal of Hydrogen Energy, Washington State University Professor Bin Yang and colleagues demonstrated that a type of lignin-based jet fuel they developed can chemically bind hydrogen in a stable liquid form. The research has many potential applications in fuels and transportation and could ultimately make it easier to harness hydrogen’s potential as a high energy and zero emissions fuel source.

https://news.wsu.edu/news/2025/01/27/researchers-discover-new-way-to-store-hydrogen-using-lignin-jet-fuel/

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SafeFlame torch turns water into fire

 

 November 5, 2013

http://www.gizmag.com/safeflame-water-flame-torch/29673/?li_source=LI&li_medium=default-widget

The pressurized acetylene and propane gas used in brazing and related tasks is highly flammable, and thus very dangerous. You know what isn't flammable, though? Water. Bearing that in mind, the European Union-funded SafeFlame consortium has developed a torch system that generates a flame using nothing but H2O and electricity.
SafeFlame utilizes an electrical current to electrolyze ordinary water, separating it into hydrogen and oxygen gas. Those gases are then mixed and ignited as they exit the torch's nozzle. By fine-tuning the proportions of the two gases, different types of flames can be produced for different applications.
Additionally, the length and heat of the flame can be adjusted by varying the amount of power delivered to the electrolyzer.


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Inexpensive catalyst for producing hydrogen under real-world conditions found

 

January 11, 2013

 Hydrogen has been hailed as the fuel of the future, but producing it cleanly using platinum as a catalyst is simply too costly to service the world's energy needs. On the flipside, producing hydrogen with fossil fuels not only releases CO2 as a byproduct, but is unsustainable, negating hydrogen's green potential. However, hydrogen may yet make good on its promise thanks to a group of scientists at the University of Cambridge.

http://www.gizmag.com/cambridge-hydrogen-cobalt-catalyst/25723/?li_source=LI&li_medium=default-widget

 

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Hydrogen Molecule Becomes Superfluid: A 50-Year-Old Prediction Confirmed

February 21, 2025

https://science.ubc.ca/news/february-21-2025/hydrogen-becomes-superfluid-nanoscale-confirming-50-year-old-prediction

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Plasma pyrolysis for a sustainable hydrogen economy

April 2022

https://www.nature.com/articles/s41578-022-00439-8

 

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Plasma technology for hydrogen production and gas conversion applications

2022

https://www.sciencedirect.com/science/article/abs/pii/B9780323899307000091

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Plasma-assisted hydrogen generation: A mechanistic review

2023

https://www.sciencedirect.com/science/article/pii/S0378382023001091

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Hydrogen cars are trying to be the next big sustainable vehicle

March 2024

https://www.msn.com/en-us/news/technology/hydrogen-cars-are-trying-to-be-the-next-big-sustainable-vehicle/ar-BB1jK664

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Will hydrogen overtake batteries in the race for zero-emission cars?

Feb 2024

https://www.theguardian.com/business/2024/feb/13/will-hydrogen-overtake-batteries-in-the-race-for-zero-emission-cars

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Is Red Hydrogen the Breakthrough Technology We've Been Waiting For?

Dec 2022

https://www.greencars.com/news/is-red-hydrogen-the-breakthrough-technology-weve-been-waiting-for

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Blue hydrogen – what is it, and should it replace natural gas?

August 13, 2021

https://theconversation.com/blue-hydrogen-what-is-it-and-should-it-replace-natural-gas-166053

 
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Water into Hydrogen - Making a Simple Hydrogen Generator from old battery - hho

Oct 12, 2023

In this video, I will show you how to use old batteries to decompose water into hydrogen and oxygen or generate HHO gas. In this video, I separate the water molecules, which are hydrogen and oxygen, by electrolyzing water, and use the produced gas.

Note that you can also use potassium hydroxide powder or drain cleaner or salt to conduct water. But if you use salt, the color of the water will turn green or brown due to the production of hydroxide ions. Also, the efficiency of the drain cleaner solution is higher.

https://www.youtube.com/watch?v=08XGs7pZSlE

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Storing electrons from hydrogen for clean chemical reactions

March 28, 2024

https://phys.org/news/2024-03-electrons-hydrogen-chemical-reactions.html


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Photon-like electrons in a four-dimensional world discovered in a real material

March 14, 2024

Dirac electrons were predicted by P. Dirac and discovered by A. Geim, both of whom were awarded the Nobel Prize in Physics in 1933 and in 2010, respectively. Dirac electrons behave like photons rather than electrons, for they are considered to have no mass, and in materials they move with light velocity.

https://phys.org/news/2024-03-photon-electrons-dimensional-world-real.html#google_vignette

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Researchers discover new yttrium-hydrogen compounds with implications for high-pressure superconductivity

March 14, 2024

https://phys.org/news/2024-03-yttrium-hydrogen-compounds-implications-high.html

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Brazilian scientists obtain a material that could be useful for hydrogen production

March 13, 2024

https://phys.org/news/2024-03-brazilian-scientists-material-hydrogen-production.html

 
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Graphene discovery could help generate cheaper and more sustainable hydrogen

23 August 2023

https://www.manchester.ac.uk/discover/news/graphene-more-magic-starts-when-flatness-ends/

 

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Research team develops catalyst that can purify municipal sewage while enhancing hydrogen generation efficiency

March 13, 2024

Researchers have devised a novel catalyst aimed at enhancing the efficiency of reactions using contaminated municipal sewage to produce hydrogen—a green energy source...

https://phys.org/news/2024-03-team-catalyst-purify-municipal-sewage.html

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Chemical etching method opens pores for fuel cells and more

March 1, 2024

A chemical etching method for widening the pores of metal-organic frameworks (MOFs) could improve various applications of MOFs, including in fuel cells and as catalysts. Researchers at Nagoya University in Japan and East China Normal University in China developed the new method with collaborators elsewhere in Japan, Australia, and China, and their work was published in the Journal of the American Chemical Society.

MOFs are porous materials composed of metal clusters or ions interconnected by carbon-based (organic) linker groups. Varying the metallic and organic components generates a variety of MOFs suitable for a wide range of applications, including catalysis, chemical separation, and gas storage.

Some MOFs have clear potential for catalyzing the chemical reactions inside fuel cells, which are being explored as the basis of renewable energy systems. Because they don't use fossil fuels, fuel cells could play a key role in the transition to a low- or zero-emissions economy to combat climate change.

https://phys.org/news/2024-03-chemical-etching-method-pores-fuel.html

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Microbial fuel cells: a comprehensive review for beginners

2021 May 1

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC8088421/

 
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Cold fusion reactor verified by third-party researchers, seems to have 1 million times the energy density of gasoline

 October 9, 2014

 

 Andrea Rossi’s E-Cat — the device that purports to use cold fusion to generate massive amounts of cheap, green energy — has been verified by third-party researchers, according to a new 54-page report. The researchers observed a small E-Cat over 32 days, where it produced net energy of 1.5 megawatt-hours, or “far more than can be obtained from any known chemical sources in the small reactor volume.” The researchers were also allowed to analyze the fuel before and after the 32-day run, noting that the isotopes in the spent fuel could only have been obtained by “nuclear reactions” — a conclusion that boggles the researchers: “… It is of course very hard to comprehend how these fusion processes can take place in the fuel compound at low energies.”

 http://www.extremetech.com/extreme/191754-cold-fusion-reactor-verified-by-third-party-researchers-seems-to-have-1-million-times-the-energy-density-of-gasoline

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Can hydrogen bring the next great improvement to lithium batteries?

 

November 8, 2015

 New research from the Lawrence Livermore National Laboratory has found that hydrogen can greatly improve both the capacity and conductivity of lithium-ion batteries. The research could also pave the way for better storage mediums for several energy options, including hydrogen itself.

 http://www.gizmag.com/hydrogen-treated-electrodes-lithium-ion-battery-performance-llnl/40278/?li_source=LI&li_medium=default-widget

 
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Energy Harvesting Device Captures Power From Liquid Molecules To Generate Electricity on the Nanoscale

 

October 21, 2023

 
https://www.sciencetimes.com/articles/46596/20231018/energy-harvesting-device-captures-power-liquid-molecules-generate-electricity-nanoscale.htm

 

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When electrons 'jump' into water: The secret behind high electrode capacities

June 25, 2025

 

In order to develop improved electrolyzers for regenerative hydrogen production, the processes on the surfaces of the metal electrodes used must be precisely understood. Researchers from the Theory Department at the Fritz Haber Institute have now been able to show that even the smallest spillover of metal electrons into the aqueous electrolyte environment is sufficient to increase the energy storage capacity more than tenfold.

https://phys.org/news/2025-06-electrons-secret-high-electrode-capacities.html

 

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Artificial photosynthesis system surpasses key efficiency benchmark for direct solar-to-hydrogen conversion

 

 June 27, 2025

https://techxplore.com/news/2025-06-artificial-photosynthesis-surpasses-key-efficiency.html

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It is debated if solar hydrogen, silicone or perovskite would make the best sustainable option for solar energy. Silicone can be made from sand or plant material, which is sustainable.

 

 

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Perovskite

Perovskite (pronunciation: /pəˈrɒvskaɪt/) is a calcium titanium oxide mineral composed of calcium titanate, with the chemical formula CaTiO. The mineral was discovered in the Ural Mountains of Russia.

https://en.wikipedia.org/wiki/Perovskite


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New solar panels are cheaper, more environmentally sustainable

 

22 July 2015


 http://www.theoptimist.com/new-solar-panels-cheaper-environmentally-sustainable/

Scientists from Northwestern University have created a new type of solar panel that is less expensive to produce, better for the environment, and could eventually be more efficient at capturing the suns rays and turning them into energy.
Perovskite solar panels, solar cells with a crystal structure similar to that of calcium titanium oxide, have been around since 2008– but only in laboratories. A key component of perovskite cells (until now) is lead, which is used to absorb light into the solar cell.
A downside of using lead is its toxicity, which can poison the environment, and waterways if introduced to nature. Humans and animals exposed to large amounts of lead can contract lead poisoning.

 
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Nanocellulose Treated with Red Onion Dye Offers Effective UV Protection for Solar Cells

March 20, 2025

The University of Turku, Finland, has conducted groundbreaking research on using bio-based materials to protect solar cells from ultraviolet (UV) radiation. The study aimed to find eco-friendly alternatives to petroleum-based plastics and discovered that nanocellulose treated with red onion dye provides exceptional UV protection. This innovative approach outperformed commercial polyethylene terephthalate (PET)-based UV filters, which are commonly used in the industry.

Researchers at the University of Turku and Aalto University in Finland, along with Wageningen University in the Netherlands, investigated four types of protective films made from cellulose nanofibers. The nanocellulose film treated with red onion extract proved to be the most efficient in blocking UV radiation, protecting 99.9% of it up to 400 nanometres.

The study’s results are significant because they highlight the importance of long-term testing for UV filters. The researchers tested the durability and performance of the filters under artificial light for 1,000 hours, which is equivalent to about a year of sunlight in the open air in central Europe. This testing period showed that the film treated with red onion dye maintained its high transmission rate in the visible light region (80% at longer wavelengths) throughout.

The findings of this study are relevant not only for solar cells but also for other applications where bio-based UV filters are paramount. The researchers envision developing biodegradable solar cell types that can be used as power sources, such as in food packaging. This innovative approach has the potential to benefit various industries and contribute to a more sustainable future.

https://www.sciencefolks.com/nanocellulose-treated-with-red-onion-dye-offers-effective-uv-protection-for-solar-cells/

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New technique could produce the ideal light-absorbing material for solar cells

 

February 3, 2015 

 http://www.gizmag.com/transition-metal-oxides-solar-cells/35895/?li_source=LI&li_medium=default-widget

Solar cell efficiency has made significant strides in recent times, but cells are still far from their maximum theoretical efficiency, and part of the reason is that the semiconductors we use to build them don’t have ideal electrical properties. Researchers at Northwestern University have now found a way to tweak an important electrical feature of transition metal oxides, compounds commonly used as semiconductors, to build the optimal light-absorbing material for solar cells, lasers and photoelectrochemical cells.
In electronics, the band gap is a crucial feature of a semiconductor, measuring the amount of energy that an electron needs to be fed before it can start conducting electricity. Its size is measured in electronvolts (eV) and dictates whether a material will behave as a conductor (~0 eV), a semiconductor (~1–9 eV) or an insulator (~9 or more eV).
Being able to tweak the band gap at will would be incredibly useful. Solar cells, for instance, produce electricity whenever a photon travels to a silicon atom and "hits" it, giving one of silicon’s electrons enough energy to jump the band gap and become conductive. Tuning the band gap would mean being able to design the ideal semiconductor that can maximize the amount of energy harvested throughout the visible spectrum. However, current methods can only change the band gap by about one eV and can only do so by modifying the material’s chemical composition, which is not ideal.

 

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Water flow battery with high-current density could store rooftop solar energy efficiently

May 21, 2025

The latest design opens the door to battery systems that are not only cheaper, but also safer to scale.

Scientists have developed a high-current density water-based battery that can be suitable for residential use.

The next-generation “flow battery” could help households store rooftop solar energy more safely, cheaply, and efficiently than ever before, according to researchers.

Developed by researchers from Monash University, the innovation’s new membrane design fixes the speed problem, making it ideal for households and a promising key player in the energy transition market.

Non-toxic, non-flammable

Researchers have highlighted that their long-term operation requires exquisite transport control of species across the cell, with movement of cations key for high current density, and anionic rejection needed for cycling stability.

“We report the tailored combination of a hydrophilic mixed-matrix membrane, SPEEK-SX, with sulphonated polydichloroxylene (Sp-DCX) as the additive and sulphonated poly(ether ether ketone) (SPEEK) as the matrix. Compared to Nafion-212, the dense aromatic backbone of SPEEK efficiently rejected the crossover of electrolytes, with sulfonate groups housed within Sp-DCX micropores increasing Na+ mobility,” said researchers in the study.

https://interestingengineering.com/energy/water-flow-battery-store-solar-energy

 

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Scientific breakthrough brings CO2 'breathing' batteries closer to reality

May 20, 2025

Scientists at the University of Surrey have made a breakthrough in eco-friendly batteries that not only store more energy but could also help tackle greenhouse gas emissions. Lithium-CO₂ 'breathing' batteries release power while capturing carbon dioxide, offering a greener alternative that may one day outperform today's lithium-ion batteries.

Until now, Lithium-CO₂ batteries have faced setbacks in efficiency -- wearing out quickly, failing to recharge and relying on expensive rare materials such as platinum. However, researchers from Surrey have found a way to overcome these issues by using a low-cost catalyst called caesium phosphomolybdate (CPM). Using computer modelling and lab experiments, tests showed this simple change allowed the battery to store significantly more energy, charge with far less power and run for over 100 cycles.

https://www.sciencedaily.com/releases/2025/05/250520122027.htm

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Can This Mineral Power The Planet?

 

August 25, 2014

In only five years, the sunlight-to-energy efficiency of solar cells made from lab-grown perovskites has almost quintupled, from 3.8 to nearly 20 percent. Compare that to sluggish gains made with silicon technology, which took three decades to reach the same threshold. Today, commercial silicon panels top out at 18 percent. Perovskite cells may best that rate, and have the added advantage of being cheap and easy to manufacture. They could reduce the cost-per-watt of solar by more than half. Plus, some prototype cells are partially translucent, so researchers like Oxford University’s Henry Snaith see potential applications as windowpanes. But for all of perovskites’s promise, scientists still need to address three big challenges.

http://www.popsci.com/article/science/can-mineral-power-planet

 

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Quantum dots and perovskite combined to create new hyper-efficient light-emitting crystal

 

July 16, 2015

http://www.gizmag.com/quantum-perovskite-light-emitting-crystal/38505/?li_source=LI&li_medium=default-widget

 Two optoelectronic materials getting a lot of press these days are perovskite and quantum dots. Both have been individually utilized by researchers to boost sunlight conversion to electrical current in solar cells, and to increase the efficacy of electrically-generated light. Now engineers at the University of Toronto (U of T) have combined both of these materials to create an ultra-efficient, super-luminescent hybrid crystal that they say will enable new records in power-to-light conversion efficiencies.


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Graphene-based solar cell hits record 15.6 percent efficiency

 

January 14, 2014

In 2012, researchers from the University of Florida reported a record efficiency of 8.6 percent for a prototype solar cell consisting of a wafer of silicon coated with a layer of graphene doped with trifluoromethanesulfonyl-amide (TFSA). Now another team is claiming a new record efficiency of 15.6 percent for a graphene-based solar cell by ditching the silicon all together.


http://www.gizmag.com/graphene-solar-cell-record-efficiency/30466/?li_source=LI&li_medium=default-widget

 
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Simplifying solar cells with a new mix of materials

 

January 27, 2016

 The new study, though, demonstrated a dopant-free silicon cell, referred to as a DASH cell (dopant free asymmetric heterocontact), with an average efficiency above 19 percent. This increased efficiency is a product of the new materials and a simple coating process for layers on the top and bottom of the device. Researchers showed it's possible to create their solar cell in just seven steps.

In this study, the research team used a crystalline silicon core (or wafer) and applied layers of dopant-free type of silicon called amorphous silicon.

Then, they applied ultrathin coatings of a material called molybdenum oxide, also known as moly oxide, at the sun-facing side of the solar cell, and lithium fluoride at the bottom surface. The two layers, having thicknesses of tens of nanometers, act as dopant-free contacts for holes and electrons, respectively.

 http://phys.org/news/2016-01-solar-cells-materials.html

 

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Mystery of Gold’s Glow: Energy Scientists Unveil the Quantum-Mechanical Effects of Photoluminescence From Crystalline Metal Films

Apr 26 2024

All metals glow to some degree, but how this occurs needs to be understood better. Until now, its microscopic origin has been intensely debated, and its potential for unraveling nanoscale carrier dynamics has been largely unexploited.

 

Luminescence From Metals

 

Luminescence from semiconductors following steady-state photoexcitation has been known since ancient times. Today, this property is widely utilized as a non-invasive probe of diverse phenomena, such as chemical reaction monitoring, assessment of solar cell efficiencies, and rock dating.

 

In 1969, scientists discovered that all metals exhibit luminescence to some degree. In recent years, photon emission from metals has received increased attention in the context of plasmonic nanostructures. These materials promise to revolutionize the energy, healthcare, and sensing industries. This can be made possible by the ability of plasmon-generated hot carriers to dramatically increase local electronic temperatures, increase solar cell absorption, and improve weak luminescence processes from molecules.

 

Despite its usefulness, there are still uncertainties surrounding the origin of emitted light, mainly whether it is due to the recombination of electrons and holes (photoluminescence) or other forms of inelastic light scattering. This mystery has been debated among theoretical and experimental studies over the last 50 years.

 

https://www.sciencetimes.com/articles/49902/20240426/mystery-gold-s-glow-energy-scientists-unveil-quantum-mechanical-effects.htm

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Who Killed the WATER Car?

https://www.youtube.com/watch?v=8CAzlW14k-w



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Miniature car runs only on the power of evaporating water

 

June 17, 2015 

http://www.gizmag.com/tiny-car-evaporating-water/38061/

 

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Hydroelectric Generator: How to Build a Small One

 

http://www.greenoptimistic.com/hydroelectric-generator/#.VSFkS-G-2zk



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HydroBee wants to be your personal hydroelectric generator

 

November 19, 2013

There are already plenty of gadgets that allow people to charge their mobile devices while off the grid. Most of those products utilize solar power, while a few have gone the thermoelectric route. The HydroBee, however, generates electricity using the power of flowing water – think of it as a portable hydroelectric station.

http://www.gizmag.com/hydrobee-portable-hydroelectric-generator/29839/?li_source=LI&li_medium=default-widget

 

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World's First NUCLEAR SALT REACTOR - Documentary Films

Jan 25, 2015



https://www.youtube.com/watch?v=xIDytUCRtTA




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"Water-in-salt" battery bodes well for greener, safer grid storage

 

December 6, 2015

Scientists at the University of Maryland and the US Army Research Laboratory have used high concentrations of salt in water to create safe, green batteries that could find use in anything from large-scale grid storage to spaceships and pacemakers.
 

http://www.gizmag.com/water-in-salt-battery/40514/?li_source=LI&li_medium=default-widget

 

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Researchers Unlock New Frontier for Quantum Dots with Molten Salt

 October 27, 2024

 

Researchers at the University of Chicago have made a groundbreaking discovery, unlocking a new frontier for quantum dots by replacing organic solvents with molten salt. This innovative technique allows for the growth of previously unimaginable nanocrystals, opening up a vast array of novel chemical materials for future exploration.

 

Led by Professor Dmitri Talapin and his team, including researchers from the University of California Berkeley, Northwestern University, the University of Colorado Boulder, and Argonne National Laboratory, this breakthrough has far-reaching implications for various industries.

 

Quantum dots are microscopic crystals used in lasers, TVs, solar cells, medical devices, and other electronics. The new technique enables the growth of III-V materials, which are used in the most efficient solar cells, brightest LEDs, and fastest electronic devices. This achievement is significant, as it was previously impossible to grow these materials in solution due to high-temperature requirements.

 

Key individuals involved in this work include Justin Ondry, a former postdoctoral researcher in Talapin’s lab, and co-authors Eran Rabani from UC Berkeley and Richard D. Schaller from Argonne National Laboratory and Northwestern University. This discovery has the potential to revolutionize various fields, enabling the creation of new building blocks for better, faster quantum and classical computers.

 

 https://quantumzeitgeist.com/researchers-unlock-new-frontier-for-quantum-dots-with-molten-salt/

 

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This breakthrough turns old tech into pure gold — No mercury, no cyanide, just light and salt

 

 June 27, 2025

 

New method published in Nature Sustainability

At Flinders University, scientists have cracked a cleaner and greener way to extract gold—not just from ore, but also from our mounting piles of e-waste. By using a compound normally found in pool disinfectants and a novel polymer that can be reused, the method avoids toxic chemicals like mercury and cyanide. It even works on trace gold in scientific waste. Tested on everything from circuit boards to mixed-metal ores, the approach offers a promising solution to both the global gold rush and the growing e-waste crisis. The technique could be a game-changer for artisanal miners and recyclers, helping recover valuable metals while protecting people and the planet.

https://www.sciencedaily.com/releases/2025/06/250626081540.htm

 

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U.S. Navy Wants to Fuel Ships Using Seawater

 April 8, 2014


 http://blogs.discovermagazine.com/d-brief/2014/04/08/u-s-navy-can-convert-seawater-fuel/#.VTnA5JO-2zk

 

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Scientists achieve perfect efficiency for water-splitting half-reaction

 

February 26, 2016 

 

Splitting water is a two-step process, and in a new study, researchers have performed one of these steps (reduction) with 100% efficiency. The results shatter the previous record of 60% for hydrogen production with visible light, and emphasize that future research should focus on the other step (oxidation) in order to realize practical overall water splitting. The main application of splitting water into its components of oxygen and hydrogen is that the hydrogen can then be used to deliver energy to fuel cells for powering vehicles and electronic devices.

http://phys.org/news/2016-02-scientists-efficiency-water-splitting-half-reaction.html#nRlv

 

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Is Spherical Solar Really The Future of Energy?

Jul 4, 2023

 

https://www.youtube.com/watch?v=alpAB1n4U7w

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Researchers say neutron stars are key to understanding elusive dark matter

April 5, 2024

https://phys.org/news/2024-04-neutron-stars-key-elusive-dark.html

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15 ENERGY EFFICIENT INVENTIONS FOR YOUR HOME

Oct 15, 2023

https://www.youtube.com/watch?v=-l-UYwfx3a0

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The Mushroom Motherboard: The Crazy Fungal Computers that Might Change Everything

Mar 4, 2024

https://www.youtube.com/watch?v=5mIWo6dgTmI

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New superconducting material discovered in transition-metal dichalcogenides materials

January 19, 2024

https://phys.org/news/2024-01-superconducting-material-transition-metal-dichalcogenides.html

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New quantum material promises up to 190% quantum efficiency in solar cells

April 10, 2024

https://techxplore.com/news/2024-04-quantum-material-efficiency-solar-cells.html

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Genius Bladeless Hydro Turbine is Cheaper Than Solar

Aug 18, 2023

https://www.youtube.com/watch?v=ArQE3SB0kyM

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Researchers build selenium–silicon tandem solar cell that could improve efficiency to 40%

April 2, 2024

https://techxplore.com/news/2024-04-seleniumsilicon-tandem-solar-cell-efficiency.html

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A solar cell you can bend and soak in water

March 27, 2024

https://techxplore.com/news/2024-03-solar-cell.html

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Chemistry researchers modify solar technology to produce a less harmful greenhouse gas

April 2, 2024

https://techxplore.com/news/2024-04-chemistry-solar-technology-greenhouse-gas.html

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Non-toxic, Eco-friendly Solar Panels

MAY 18, 2022

https://www.labroots.com/trending/technology/22775/non-toxic-eco-friendly-solar-panels

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New way to charge batteries harnesses the power of 'indefinite causal order'

December 14, 2023

https://phys.org/news/2023-12-batteries-harnesses-power-indefinite-causal.html#google_vignette

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Drawing inspiration from plants: A metal–air paper battery for wearable devices

April 3, 2024

https://techxplore.com/news/2024-04-metalair-paper-battery-wearable-devices.html

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New 'papertronics' offer biodegradable alternative to traditional circuits

March 13, 2024

https://techxplore.com/news/2024-03-papertronics-biodegradable-alternative-traditional-circuits.html

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Cobalt-free batteries could power cars of the future

January 20, 2024

https://phys.org/news/2024-01-cobalt-free-batteries-power-cars.html

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Next-generation batteries could go organic, cobalt-free for long-lasting power

January 18, 2024

https://techxplore.com/news/2024-01-generation-batteries-cobalt-free-power.html

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We rely heavily on lithium batteries – but there's a growing array of alternatives

20 March 2024

https://www.bbc.com/future/article/20240319-the-most-sustainable-alternatives-to-lithium-batteries

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New materials discovered for safe, high-performance solid-state lithium-ion batteries

April 2, 2024

https://techxplore.com/news/2024-04-materials-safe-high-solid-state.html#google_vignette

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New 'water batteries' stay cool under pressure

February 21, 2024

A global team of researchers and industry collaborators led by RMIT University has invented recyclable 'water batteries' that won't catch fire or explode.

Lithium-ion energy storage dominates the market due to its technological maturity, but its suitability for large-scale grid energy storage is limited by safety concerns with the volatile materials inside.

Lead researcher Distinguished Professor Tianyi Ma said their batteries were at the cutting edge of an emerging field of aqueous energy storage devices, with breakthroughs that significantly improve the technology's performance and lifespan.

"What we design and manufacture are called aqueous metal-ion batteries—or we can call them water batteries," said Ma, from RMIT's School of Science.

The team uses water to replace organic electrolytes—which enable the flow of electric current between the positive and negative terminals—meaning their batteries can't start a fire or blow up—unlike their lithium-ion counterparts.

"Addressing end-of-life disposal challenges that consumers, industry, and governments globally face with current energy storage technology, our batteries can be safely disassembled, and the materials can be reused or recycled," Ma said.

The simplicity of manufacturing processes for their water batteries helped make mass production feasible, he said.

"We use materials such as magnesium and zinc that are abundant in nature, inexpensive, and less toxic than alternatives used in other kinds of batteries, which helps to lower manufacturing costs and reduces risks to human health and the environment."

https://techxplore.com/news/2024-02-batteries-stay-cool-pressure.html#google_vignette

 
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Researchers develop high-energy-density aqueous battery based on halogen multi-electron transfer

April 23, 2024

https://techxplore.com/news/2024-04-high-energy-density-aqueous-battery.html

 

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How a Sand Battery Could Revolutionize Home Energy Storage

Mar 26, 2024

https://www.youtube.com/watch?v=KVqHYNE2QwE

 

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Mitigating electrode-level heterogeneity using phosphorus nanolayers on graphite for fast-charging batteries

October 5, 2023

https://techxplore.com/news/2023-10-mitigating-electrode-level-heterogeneity-phosphorus-nanolayers.html

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Enovix Has The Silicon Battery Of The Future

Mar. 24, 2023

https://seekingalpha.com/article/4589703-enovix-silicon-battery-of-future

 
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Sila introduces Titan nano-composite silicon anode material; 20% increase in vehicle range and reduced charge time

05 April 2023

https://www.greencarcongress.com/2023/04/20230405-sila.html

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Strong coupling between a photon and a hole spin in silicon

06 March 2023

https://www.nature.com/articles/s41565-023-01332-3


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Engineers 'grow' atomically thin transistors on top of computer chips

April 28, 2023

A new low-temperature growth and fabrication technology allows the integration of 2D materials directly onto a silicon circuit, which could lead to denser and more powerful chips.

https://www.sciencedaily.com/releases/2023/04/230428130757.htm

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Graphene and two-dimensional materials for silicon technology

25 September 2019

https://www.nature.com/articles/s41586-019-1573-9

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Research progress of nano-silicon-based materials and silicon-carbon composite anode materials for lithium-ion batteries

16 March 2022

https://link.springer.com/article/10.1007/s10008-022-05141-x

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Enhancing zinc–air battery performance by constructing three-dimensional N-doped carbon coating multiple valence Co and MnO heterostructures

13 January 2024

https://link.springer.com/article/10.1007/s12274-023-6404-5

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Enhanced Electron Delocalization within Coherent Nano-Heterocrystal Ensembles for Optimizing Polysulfide Conversion in High-Energy-Density Li-S Batteries

25 December 2023

https://onlinelibrary.wiley.com/doi/10.1002/adma.202310052

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Why This NASA Battery May Be The Future of Energy Storage

Jul 18, 2023

What do you do if a satellite runs out of batteries? It’s prohibitively expensive to send a team into orbit and pop in some new AAs, and as a result many satellites use very efficient, reliable and long-lived nickel-hydrogen batteries. We’re talking about batteries that last decades. That sounds like the sort of battery that could revolutionize grid-scale energy storage and really help out renewables back here on Earth, which is why EnerVenue is backing nickel hydrogen batteries as the next step forward! But if batteries rugged and powerful enough for spacecraft already exist, then why haven’t we used it back here on Earth until now?

https://www.youtube.com/watch?v=2zG-ZrC4BO0

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Why NASA is Building a Solid State Battery

Oct 21, 2023

Batteries are one of the hottest areas of research and development around the world. It's critical fo everything from grid storage, home backup, electric vehicles, and even short haul flight. But as the popularity of all these fields increase, certain questions are raised. The holy grail is supposed to be Solid state batteries, with no liquid electrolyte, and NASA thinks they might have made a breakthrough with their SABERS battery technology. So how does it work, is it legit, or just another pipedream? Let's figure this out together!

https://www.youtube.com/watch?v=tOcoGNZaUAM

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Solid State Batteries - FINALLY powering electric vehicles in 2024!

Jan 28, 2024

https://www.youtube.com/watch?v=suNUPGC2pwM

 
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This Is Why Companies Are Hiding The Truth About Batteries

Dec 18, 2023

https://www.youtube.com/watch?v=m5aHAZhuwyc

 

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Chapter 20: Green computing 
 

 

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We often hear about electronic waste that has many toxic chemicals.  One of our goals is to make electronics biodegrade, and for these electronics to be non-toxic to the environment.  


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Self-Powered Solar Circuit Could Help Computing Become Greener and Faster

 

February 5, 2010

http://www.greenoptimistic.com/self-powered-solar-circuit-could-help-computing-become-greener-and-faster-20100205/#.VSHOEOG-2zk

 

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How New Self-Healing Circuit Restores Electricity in 20 Seconds

  

January 16, 2012

 http://www.greenoptimistic.com/self-healing-electronics-circuit-20120116/#.VSHOGOG-2zk

 

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Maze-solving automatons can repair broken circuits (w/ video)

 

Apr 07, 2015

 

 

(Phys.org)—Modern electronic circuits may provide unprecedented flexibility and robustness, but even the best-made circuits are subject to open circuit faults—breaks caused by thermal, mechanical and electrical stress. In a new study, scientists have developed an intelligent self-healing mechanism that can locate open circuit faults—even when not in the line of sight—and then repair them by building bridges of tiny conductive particles to close the gap. The real-time repair mechanism could be especially useful for space technology, allowing open faults on satellites to be repaired without the need for expensive operations.

Read more at: http://phys.org/news/2015-04-maze-solving-automatons-broken-circuits-video.html#jCp

 

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Electrical circuit made of gel can repair itself

 

August 25, 2015

 

 Scientists have fabricated a flexible electrical circuit that, when cut into two pieces, can repair itself and fully restore its original conductivity. The circuit is made of a new gel that possesses a combination of properties that are not typically seen together: high conductivity, flexibility, and room-temperature self-healing. The gel could potentially offer self-healing for a variety of applications, including flexible electronics, soft robotics, artificial skins, biomimetic prostheses, and energy storage devices.

 

 http://phys.org/news/2015-08-electrical-circuit-gel.html#jCp

 

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Liquid metal could be used to create morphing electronics

 

 September 21, 2014 

 

 http://www.gizmag.com/liquid-metal-morphing-electronics/33836/

Who could forget the scene in Terminator 2: Judgement Day where the shape-shifting T-1000 reassembles itself from thousands of blobs of molten metal? Researchers from North Carolina State University (NCSU) have taken the first steps to such science fiction becoming reality by developing a way to control the surface tension of liquid metals with the application of very low voltages. This may offer opportunities in a new field of morphing electronic circuits, self-healing electronics, or – one day – maybe even self-assembling terminator-style robots.

The liquid metal used by the researchers was an alloy of gallium and indium. Gallium is liquid just above room temperature at about 29° C (84° F), while Indium has a much higher melting point at around 156° C (312° F), yet when mixed together, they form an alloy that is liquid at room temperature. In other words, a eutectic alloy – one that is composed of metals with disparate melting points that, when combined, melt as a whole at a specific temperature.

Another important aspect of this eutectic alloy, and one that the researchers sought to exploit in their experiments, is its exceptionally high surface tension of approximately 500 millinewtons per meter (mN/m). The consequence of this is that a blob of this alloy resting on a surface will tend to form an almost spherical ball and hold its shape if undisturbed...

 

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Silicon-based metamaterials could bring photonic circuits

 

January 29, 2016

 

 New transparent metamaterials under development could make possible computer chips and interconnecting circuits that use light instead of electrons to process and transmit data, representing a potential leap in performance.

 

 http://phys.org/news/2016-01-silicon-based-metamaterials-photonic-circuits.html

 

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Fine-tuning organic circuits: Monolayer terminal groups and molecular junctions

 

Apr 03, 2015

 

 (Phys.org)—Self-assembled monolayers are organic molecules that spontaneously coordinate to a metal surface. If this metal surface is an electrode, then a current can pass through the organic monolayer and interact with a second electrode on the terminal side of the molecule. This current can be controlled by changing the characteristics of the organic molecule, such as making it longer or adding polar substituents or other functional groups. This tailoring of organic circuits is part of a bigger project of creating organic-based electronics.

Read more at: http://phys.org/news/2015-04-fine-tuning-circuits-monolayer-terminal-groups.html#jCp

 

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Random nanowire configurations increase conductivity over heavily ordered configurations

May 15, 2015

http://phys.org/news/2015-05-random-nanowire-configurations-heavily.html#nRlv

 

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Automated microscope tracks directional heat flow in thermoelectric materials for green energy

May 8, 2025

Scientists have developed a new microscope that significantly improves the way heat flow in materials can be measured. This advancement could lead to better designs for electronic devices and energy systems.

Measuring how heat moves through materials is crucial for developing efficient electronics and energy devices. For example, better heat management can lead to faster and more reliable computers, as well as more efficient solar panels and batteries.

"Finding the right materials for electronics is crucial in developing the devices we need to support the green transition. For instance, when turning heat into electricity—or vice versa—we need materials that lose very little heat but at the same time are great electrical conductors," says Nini Pryds, a professor at DTU Energy.

https://techxplore.com/news/2025-05-automated-microscope-tracks-thermoelectric-materials.html

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Wearables with tunable stiffness mimic touch, adapt motion, and remember shape

May 09, 2025

The algorithm and simulations optimize flexural rod placement for reconfigurable motion and precise kinematic performance.

https://interestingengineering.com/innovation/wearables-with-tunable-stiffness-mimic-touch-adapt-motion-and-remember-shape

 

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Harnessing nature's fractals for flexible electronics: Biomimetic fabrication technique uses leaf skeletons as templates

March 24, 2025

Doctoral Researcher Amit Barua and leaf skeleton of a Bodhi tree. Credit: Timo Laukkanen 

By using leaf skeletons as templates, researchers harnessed nature's intrinsic hierarchical fractal structures to improve the performance of flexible electronic devices. Wearable sensors and electronic skins are examples of flexible electronics.

A research team at the University of Turku, Finland, has developed an innovative approach to replicating bioinspired microstructures found in plant leaf skeletons, eliminating the need for conventional cleanroom technologies. The work is published in the journal npj Flexible Electronics.

Fractal patterns are self-replicating structures in which the same shape repeats at increasingly smaller scales. They can be created mathematically and also occur in nature. For example, tree branches, leaf veins, vascular networks, and many floral patterns, such as cauliflower, follow a fractal structure.

Researchers created surfaces that mimic fractal patterns by utilizing dried tree leaf skeletons. Different manufacturing materials were sprayed onto the leaf skeletons, after which the new surfaces were separated from the leaf skeleton, and the researchers compared the structural properties and durability of the surfaces made from different materials.

This biomimetic surface, with more than 90% replication accuracy, is highly compatible with flexible electronic applications, offering enhanced stretchability, conformal attachment to skin, and superior breathability.

https://techxplore.com/news/2025-03-harnessing-nature-fractals-flexible-electronics.html

 

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Stretchable electronics: Advances in elastic conductive fibers for multifunctional applications

2024

Abstract

This review paper provides an extensive overview of elastic conductive fibers (ECFs), highlighting their evolution, design, and applications in stretchable electronics. ECFs are versatile due to their superior mechanical properties, lightweight nature, and ease of integration, making them ideal for wearable technology, health monitoring, aerospace, and bioengineering. The paper examines how ECFs combine fiber flexibility with electronic functionality, maintaining conductivity under mechanical deformation, and explores their use in wearable electronics, soft robotics, bioelectronics, and flexible energy devices. Key challenges discussed include balancing conductivity and stretchability, with a focus on innovative materials and structural designs to enhance performance and durability. ECFs are categorized by structural design (intrinsically stretchable and non-stretchable) and conductive materials (inorganic and organic), detailing advancements in micro/nano-structured conductive fillers and specialized microstructures. Applications in electrodes, strain sensors, transmitters, and actuators are showcased. The review also addresses manufacturing challenges, advocating for cost-effective, high-performance materials, scalable production methods, and a multidisciplinary approach combining empirical research, computational models, and machine learning. The future of ECFs lies in large-scale production with consistent quality, multifunctional integration, and leveraging AI-driven models for design and manufacturing. As research advances, ECFs are set to become fundamental in modern electronic applications, emphasizing the need for continued exploration and innovation.

https://www.sciencedirect.com/science/article/abs/pii/S1566119924001563

 

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Recyclable, self-healing circuit boards could tackle global e-waste crisis

June 4, 2025

A new type of circuit board material could help keep e-waste out of landfills, according to a new study by Virginia Tech researchers.

Often ending up in landfill, the toxic additives or hazardous substances within discarded electronic devices leach into soils and ecosystems. 

Data from the UN’s Global e-waste monitor report published last year found that worldwide generation of e-waste is rising five times faster  than documented e-waste recycling.

https://eandt.theiet.org/2025/06/04/recyclable-self-healing-circuit-boards-could-tackle-global-e-waste-crisis

 

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Disappearing electronics: Biodegradable fiber electronics could solve the growing e-waste and textile crisis 

 11-Jul-2025 

Every time we toss out an old T-shirt or discard a disposable medical patch, we’re contributing to a rapidly escalating environmental crisis. The world produces over 92 million tons of textile waste annually, much of it made from synthetic materials that can linger for centuries. Add to that the surge in wearable electronics — smartwatches, fitness trackers, sensor-laden garments — and the problem becomes twofold. These e-textiles don’t just include fabric, but also metal wires, plastic substrates, adhesives, and circuits that are nearly impossible to recycle. As electronics become more intimate, wearable, and disposable, the question becomes urgent: how do we design them to disappear when they’re no longer needed?

A research team at Seoul National University has taken a significant step toward answering that question. Led by Professor Seung-Kyun Kang and Dr. Jae-Young Bae, the team has developed a fully biodegradable, high-performance conductive fiber that can be seamlessly integrated into wearable electronics — and naturally decompose after use. Unlike conventional e-textiles that persist in landfills, this new fiber system maintains performance during use but vanishes in enzyme-rich or soil environments, leaving no harmful residues behind.

The team’s innovation lies in combining tungsten microparticles with a biodegradable polymer known as poly(butylene adipate-co-terephthalate) (PBAT) to form a conductive fiber. This core is coated with a flexible, water-resistant polyanhydride (PBTPA) layer that enhances mechanical stability without compromising biodegradability. The fiber achieves an impressive electrical conductivity of approximately 2,500 S/m, stretches up to 38% without failure, and endures over 20 laundry cycles and 5,000 bending events — performance metrics comparable to or better than many existing e-textile solutions.

Crucially, the fiber is compatible with dry-jet wet-spinning, a scalable process that enabled the team to produce lengths exceeding 10 meters in a continuous run. To validate its real-world applicability, the fiber was integrated into a wearable smart sleeve featuring a temperature sensor, electromyography (EMG) electrodes, and a wireless power coil. The device operated reliably under dynamic movement and environmental stress. After use, the entire system — including the embroidered eco-emblem — began to decompose when exposed to soil or enzymes, fully disintegrating within a few months.

“This is more than just a new material — it’s a platform for sustainable electronics,” said Professor Kang. “We’ve shown that you can have high-functioning wearable devices that don’t become e-waste after their useful life ends.”

https://www.eurekalert.org/news-releases/1090926

 

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High-performance memory devices can dissolve in water to address e-waste problem

June 27, 2025

 

 

 

A step-by-step demonstration showing how the device, placed on a green leaf, completely dissolves in water within 72 hours.

The use of electronics in various forms is on the rise, from wearable devices like smartwatches to implantable devices like body-implanted sensors, skin-worn smart patches, and disposable monitoring devices. These devices, which are inevitably discarded after use, contribute to the growing problem of electronic waste (e-waste), a significant environmental concern.

The Korea Institute of Science and Technology (KIST) has announced that a joint research team, led by Dr. Sangho Cho of the Center for Extreme Materials Research and Dr. Yongho Joo of the Center for Functional Composite Materials Research, has developed a polymeric material that offers high-performance data storage while completely degrading within days when immersed in water. The research is published in the journal Angewandte Chemie International Edition.

The material is biocompatible and stable enough for implantation in the human body, and the onset of degradation can be controlled by adjusting the thickness and the composition of the protective layer. Once this protective layer dissolves, the material degrades naturally in water within approximately three days, without leaving any residue.

Although electronic devices that dissolve in water have previously been developed, they have typically suffered from poor data storage capabilities, limited performance, and vulnerability to repeated mechanical deformation. To address these challenges, the KIST research team designed a new molecular structure (PCL-TEMPO), which combines TEMPO—a functional organic molecule capable of storing electrical information—with polycaprolactone (PCL), a biodegradable polymer. This novel design enables both electrical signal storage and natural degradation to be achieved within a single molecular system.

https://techxplore.com/news/2025-06-high-memory-devices-dissolve-problem.html#google_vignette

 

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Intelligent Decision Support Systems for Energy-Efficient Autonomous Systems in Consumer Electronics

29 April 2025

Abstract:

This paper proposes an AI-based decision support system for enhancing energy efficiency in autonomous systems within consumer electronics. The primary objective is to optimize energy consumption by leveraging advanced Recurrent Neural Networks (RNNs) combined with Adaptive Moment Estimation (Adam). The proposed intelligent framework incorporates real-time data processing, prediction, and adaptive decision-making to reduce energy usage across a variety of devices, such as smart thermostats, robotic vacuum cleaners, and IoT-enabled lighting systems. Key methodologies include the integration of RNNs to model temporal energy consumption patterns and the Adam optimizer for efficient model training. The results demonstrate significant energy savings with improvements in prediction accuracy compared to traditional approaches. The findings suggest that the AI-based system can provide substantial reductions in energy consumption while maintaining or improving device performance. The research has important implications for the future of energy-efficient consumer electronics, particularly as the demand for smart devices grows.

https://ieeexplore.ieee.org/document/10980011

 

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Graphene “Nano-Origami” Creates Tiniest Microchips Yet – Could Make Computers and Phones Thousands of Times Faster

 

February 18, 2021

 

 

 

The base of the 2D-material with the white lines showing the structural kinks which modify the electrical properties mechanically. 

 

Nanomaterial developments could lead to computers and phones running thousands of times faster.

 

The tiniest microchips yet can be made from graphene and other 2D-materials, using a form of ‘nano-origami’, physicists at the University of Sussex have found.

 

This is the first time any researchers have done this, and it is covered in a paper published in the ACS Nano journal.

 

By creating kinks in the structure of graphene, researchers at the University of Sussex have made the nanomaterial behave like a transistor, and have shown that when a strip of graphene is crinkled in this way, it can behave like a microchip, which is around 100 times smaller than conventional microchips.

 

Prof Alan Dalton in the School of Mathematical and Physical Sciences at the University of Sussex, said:

 

“We’re mechanically creating kinks in a layer of graphene. It’s a bit like nano-origami.

 

Straintronics: The Future of Fast, Compact Devices

 

“Using these nanomaterials will make our computer chips smaller and faster. It is absolutely critical that this happens as computer manufacturers are now at the limit of what they can do with traditional semiconducting technology. Ultimately, this will make our computers and phones thousands of times faster in the future.

 

“This kind of technology – “straintronics” using nanomaterials as opposed to electronics – allows space for more chips inside any device. Everything we want to do with computers – to speed them up – can be done by crinkling graphene like this.”

 
https://scitechdaily.com/graphene-nano-origami-creates-tiniest-microchips-yet-could-make-computers-and-phones-thousands-of-times-faster/

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Nanoscale ripples provide key to unlocking thin material properties in electronics

March 27, 2025

 

 

An electron micrograph shows nanometer-thick kirigami structures that highlight the advantages of using rippled metamaterials as structural films. The incorporation of rippled metamaterials allows for enhanced control over the final three-dimensional architecture. 

When materials are created on a nanometer scale—just a handful of atoms thick—even the thermal energy present at room temperature can cause structural ripples. How these ripples affect the mechanical properties of these thin materials can limit their use in electronics and other key systems.

New research validates theoretical models about how elasticity is scale-dependent—in other words, the elastic properties of a material are not constant, but vary with the size of the piece of material...

https://phys.org/news/2025-03-nanoscale-ripples-key-thin-material.html

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Record-Breaking Energy Storage: Nanosheet Technology Takes Dielectric Capacitors to New Heights

 July 18, 2023

 

Researchers have developed an advanced dielectric capacitor using nanosheet technology, providing unprecedented energy storage density and stability. This breakthrough could significantly enhance renewable energy usage and electric vehicle production.

 

Groundbreaking Dielectric Capacitor Development

 

A research group, led by Nagoya University in Japan, has innovatively applied nanosheet technology to create a dielectric capacitor. This development holds significant implications for advanced electronic and electrical power systems. Innovations in energy storage technology are vital for the effective use of renewable energy and the mass production of electric vehicles. The dielectric capacitor stands as a major advancement in technology, boasting the highest energy storage density ever recorded. Other beneficial features include a quick charging time, high output, longevity, and superior high temperature stability.

 

https://scitechdaily.com/record-breaking-energy-storage-nanosheet-technology-takes-dielectric-capacitors-to-new-heights/

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Researchers identify carbon contamination as key barrier in gallium oxide electronics

July 28, 2025

https://www.lifetechnology.com/blogs/life-technology-technology-news/researchers-identify-carbon-contamination-as-key-barrier-in-gallium-oxide-electronics

 

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Gold Complex Ion-Pairing Enhances Organic Conductive Materials

March 18, 2025

The breakthrough enhances solubility and charge segregation, paving the way for innovative electronics.

https://www.technologynetworks.com/applied-sciences/news/gold-complex-ion-pairing-enhances-organic-conductive-materials-397344

 

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Simple solution yields ultra-thin tin sulfide sheets for next-generation electronics

June 13, 2025

https://phys.org/news/2025-06-simple-solution-yields-ultra-thin.html

 

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 Better digital memories with the help of noble gases 

February 1, 2025

 

The electronics of the future can be made even smaller and more efficient by getting more memory cells to fit in less space. One way to achieve this is by adding the noble gas xenon when manufacturing digital memories. This has been demonstrated by researchers at Linköping University in a study published in Nature Communications. This technology enables a more even material coating even in small cavities.

 

Twenty-five years ago, a camera memory card could hold 64 megabytes of information. Today, the same physical size memory card can hold 4 terabytes – over 60,000 times more information.

 

An electronic storage space, such as a memory card, is created by alternating hundreds of thin layers of an electrically conductive and an insulating material. A multitude of very small holes are then etched through the layers. Finally, the holes are filled with a conductive material. This is done by using a technique in which vapors of various substances are used to create thin material layers...

https://www.sflorg.com/2025/02/ms02012501.html

 

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White Graphene: The One-Atom Wonder Driving Greener Energy and Faster Tech

 

13 January 2025

Researchers at the University of Surrey have made a breakthrough in understanding how Hexagonal Boron Nitride (hBN), a 2D material, grows and forms nanostructures on metal substrates. This discovery could lead to more efficient electronics, cleaner energy solutions, and environmentally friendly chemical manufacturing.

 

Known as “white graphene,” hBN is an ultra-thin material only one atom thick. It is highly durable, capable of withstanding extreme temperatures, resisting chemical damage, and blocking electrical currents. These properties make hBN an essential material in advanced electronics, where it protects sensitive microchips and supports the development of faster, more efficient transistors.

 

The researchers have also demonstrated the creation of nanoporous hBN, a novel form of the material with tiny, structured voids. This unique structure enables selective absorption and advanced catalysis, significantly enhancing its potential for environmental applications. These include detecting and filtering pollutants, improving hydrogen storage, and serving as electrochemical catalysts for fuel cells in advanced energy systems.

 

https://www.stardrive.org/index.php/sd-science-news/70827-white-graphene-the-one-atom-wonder-driving-greener-energy-and-faster-tech

 

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Germanene nanoribbons pave the way for quantum computing

March 3, 2025

If you start with a two-dimensional ribbon and make it narrower and narrower, when does it stop being a ribbon and start being a one-dimensional line? Scientists from Utrecht University and the University of Twente made one-atom-thick ultrathin nanoribbons consisting of germanium atoms.

 

 

Germanene nanoribbon structure. 

https://phys.org/news/2025-03-germanene-nanoribbons-pave-quantum.html

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Nanoscale Power Plants: Turning Heat Into Power With Graphene Ribbons

 

 27th, Jan 2024

https://statnano.com/world-news/105674/Nanoscale-Power-Plants-Turning-Heat-Into-Power-With-Graphene-Ribbons

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UC Irvine physicists discover first transformable nano-scale electronic devices

 
The finding has potential to fundamentally change the nature of these items

Irvine, Calif., April 17, 2023 — The nano-scale electronic parts in devices like smartphones are solid, static objects that once designed and built cannot transform into anything else. But University of California, Irvine physicists have reported the discovery of nano-scale devices that can transform into many different shapes and sizes even though they exist in solid states.

It’s a finding that could fundamentally change the nature of electronic devices, as well as the way scientists research atomic-scale quantum materials. The study is published recently in Science Advances.

https://news.uci.edu/2023/04/17/uc-irvine-physicists-discover-first-transformable-nano-scale-electronic-devices/ 

 

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“Intercrystals” Pave the Way for Greener Electronics and Quantum Technologies

May 22, 2025

Double-layer graphene twisted on a layer of hexagonal boron nitride gives rise to some strange new properties, scientists have discovered.

https://www.technologynetworks.com/applied-sciences/news/intercrystals-pave-the-way-for-greener-electronics-and-quantum-technologies-400029

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Scientists discover class of crystals with properties that may prove revolutionary

 

May 21, 2025

 

'Intercrystals' pave the way for greener electronics and quantum technologies

 

Researchers have discovered a new class of materials -- called intercrystals -- with unique electronic properties that could power future technologies. Intercrystals exhibit newly discovered forms of electronic properties that could pave the way for advancements in more efficient electronic components, quantum computing and environmentally friendly materials, the scientists said.

https://www.sciencedaily.com/releases/2025/05/250521161106.htm

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Unlocking the Future: How Tiny Crystals Are Powering Next-Gen Electronics

 January 9, 2025

 

By controlling the doping at the initial stages of nanocrystal growth, the team offers a promising solution to longstanding efficiency issues and opens up exciting possibilities for the next generation of optoelectronic devices.

 

Breakthrough in Semiconductor Technology

 

Professor Jiwoong Yang and his team at the Department of Energy Science and Engineering, Daegu Gyeongbuk Institute of Science & Technology (DGIST), have developed a groundbreaking method to control doping during the nucleus (seed) phase of semiconductor nanocrystal growth. This innovation enhances the performance of nanocrystals and addresses critical challenges in the field.

 

The research, conducted in collaboration with Professor Stefan Ringe’s team at the Department of Chemistry, Korea University, revealed how doping processes and locations vary based on the type of doping element (dopant) used. This advanced technology has the potential to transform modern electronics, with applications in cutting-edge devices such as displays and transistors.

 
https://scitechdaily.com/unlocking-the-future-how-tiny-crystals-are-powering-next-gen-electronics/

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New Technique May Benefit Gemstone-Based Quantum Computers

 

January 11, 2022

 

Quantum Brilliance will install a synthetic diamond-based quantum accelerator at the Pawsey Supercomputing Centre. 

 

The remarkable properties of a particular atomic defect — the nitrogen-vacancy (NV) center. Namely, its optical electron spin initialization and readout mechanism that retains high fidelity and contrast under simple off-resonance illumination. This combined with microwave control means that it can be used to initialize, manipulate and read out high-quality nuclear spin qubits in the diamond. 

 
https://science-atlas.com/science/new-technique-may-benefit-gemstone-based-quantum-computers/

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MIT turns “magic” material into versatile electronic devices

 

May 2, 2021

 

CAMBRIDGE, Mass.–In a feat worthy of a laboratory conceived by J.K. Rowling, MIT researchers and colleagues have turned a “magic” material composed of atomically thin layers of carbon into three useful electronic devices. Normally, such devices, all key to the quantum electronics industry, are created using a variety of materials that require multiple fabrication steps. The MIT approach automatically solves a variety of problems associated with those more complicated processes. 

https://physics.mit.edu/news/mit-turns-magic-material-into-versatile-electronic-devices/

 

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Unique Molecule May Lead to Smaller, More Efficient Computers

May 02, 2025 

https://chemistry.gatech.edu/news/unique-molecule-may-lead-smaller-more-efficient-computers

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Microscopic Building Blocks: New Dual-Functional Supramolecular Structures Unveiled

  

July 29, 2024

 

A recent study by Yokohama National University has introduced a groundbreaking methodology in materials science, achieving the self-assembly of dual-pore molecular crystals using advanced sorting techniques. This innovation paves the way for the development of multifunctional materials with diverse applications.

 

Versatile molecular frameworks known as discrete supramolecular structures function as customizable microscopic building blocks for numerous applications. These structures can be used in drug delivery, create unique environments for catalytic reactions, or be integrated into molecular machines.

 

In their paper published in the Journal of the American Chemical Society, researchers from Yokohama National University presented a new methodology to advance the self-assembly of dual-functional supramolecular materials.

 

Self-assembly involves the spontaneous generation of a well-defined, discrete supramolecular architecture from a given set of components under thermodynamic equilibration. Typically, a binary combination of precursors, each bearing complementary functional groups, is assembled into a stable product. Multicomponent systems, which include at least two precursors having identical functional groups, remain relatively unexplored.

https://scitechdaily.com/microscopic-building-blocks-new-dual-functional-supramolecular-structures-unveiled/

 

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Sushi-Like Rolled 2D Heterostructures May Lead To New Miniaturized Electronics

 

March 11, 2021

https://www.mri.psu.edu/news-articles/news-pr-home/sushi-rolled-2d-heterostructures-may-lead-new-miniaturized-electronics

 

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Reaching Towards 2D Memory: Is Magnetic Graphene and Spintronics the Key?

 

May 14, 2021

 

Recent research spurs the prospect of 2D layered materials having the potential to play a significant role in memory and data processing applications.

 

https://www.allaboutcircuits.com/news/reaching-2d-memory-is-graphene-and-spintronics-the-answer/


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Quantum material ‘learns’ like a living creature

 

11 Nov 2021

 

Quantum materials known as Mott insulators can “learn” to respond to external stimuli in a way that mimics animal behaviour, say researchers at Rutgers University in the US. The discovery of behaviours such as habituation and sensitization in these non-living systems could lead to new algorithms for artificial intelligence (AI).

 

Neuromorphic, or brain-inspired, computers aim to mimic the neural systems of living species at the physical level of neurons (brain nerve cells) and synapses (the connections between neurons). Each of the 100 billion neurons in the human brain, for example, receives electrical inputs from some of its neighbours and then “fires” an electrical output to others when the sum of the inputs exceeds a certain threshold. This process, also known as “spiking”, can be reproduced in nanoscale devices such as spintronic oscillators. As well as being potentially much faster and energy efficient than conventional computers, devices based on these neuromorphic principles might be able to learn how to perform new tasks without being directly programmed to accomplish them.

 
https://physicsworld.com/a/quantum-material-learns-like-a-living-creature/

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Quantum Material Exhibits “Non-Local” Behavior That Mimics Brain Function

 

August 07, 2023

 

New research shows a possible way to improve energy-efficient computing

https://today.ucsd.edu/story/quantum-material-mimics-non-local-brain-function

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Photoresponsive cages show promise for tunable supramolecular electronics

May 24, 2025

Electrical junctions built from these supramolecular cages, sandwiched between a self-assembled monolayer (SAM) and an EGaIn top electrode, exhibited distinctly different behaviors under light. While junctions containing monomeric porphyrins showed negligible current changes under 420-nm illumination, those made with supramolecular cages displayed marked photoresponsive charge transport. Notably, the inclusion of metal ions such as Zn²⁺ and Cu²⁺ in the porphyrin cores altered the magnitude of this response, highlighting the tunability of the system...

https://elnano.com/photoresponsive-cages-show-promise-for-tunable-supramolecular-electronics/

 

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Innovative Technology for Building Ultralow-Loss Integrated Photonic Circuits 

 

2021

 

Encoding information into light, and transmitting it through optical fibers lies at the core of optical communications. With an incredibly low loss of 0.2 dB/km, optical fibers made from silica have laid the foundations of today’s global telecommunication networks and our information society.

 

Such ultralow optical loss is equally essential for integrated photonics, which enable the synthesis, processing and detection of optical signals using on-chip waveguides. Today, a number of innovative technologies are based on integrated photonics, including semiconductor lasers, modulators, and photodetectors, and are used extensively in data centers, communications, sensing and computing.

 

Integrated photonic chips are usually made from silicon that is abundant and has good optical properties. But silicon can’t do everything we need in integrated photonics, so new material platforms have emerged. One of these is silicon nitride (Si3N4), whose exceptionally low optical loss (orders of magnitude lower than that of silicon), has made it the material of choice for applications for which low loss is critical, such as narrow-linewidth lasers, photonic delay lines, and nonlinear photonics.

 

Now, scientists in the group of Professor Tobias J. Kippenberg at EPFL’s School of Basic Sciences have developed a new technology for building silicon nitride integrated photonic circuits with record low optical losses and small footprints. The work is published in Nature Communications.

 

https://rfengineer.net/rfic/innovative-technology-for-building-ultralow-loss-integrated-photonic-circuits/

 

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Mechanically imprinting atoms in ceramic

 

2021/05/28

 

Electroceramics such as capacitors are essential components in electronic devices. Intervening in their crystalline structure can change specific properties. Thus, for instance, chemical methods can be used to replace individual atoms in the crystal lattice with others. A stable shape can be created by replacing a whole series of atoms rather than just a single one. An international team of researchers under the leadership of the TU Darmstadt has, for the first time, succeeded in inserting a dislocation into a ferroelectric ceramic by mechanically imprinting the atoms in the material – a procedure that hitherto has only ever been used in metals. The findings have been published in “Science”, the renowned journal.  

https://www.tu-darmstadt.de/matter-and-materials/forschungsfeld_mm/news_mm/newsdetails_318208.en.jsp

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Single Photon Switch Advance: “Rydberg States” in Solid State Materials

 

 June 15, 2021

 

City College researchers used Rydberg states in 2D semiconductors to demonstrate single-photon switching on a chip. This breakthrough could lead to scalable quantum photonic devices and energy-efficient computing.

 

The ability to turn on and off a physical process with just one photon is a fundamental building block for quantum photonic technologies. Realizing this in a chip-scale architecture is important for scalability, which amplifies a breakthrough by City College of New York researchers led by physicist Vinod Menon. They’ve demonstrated for the first time the use of “Rydberg states” in solid state materials (previously shown in cold atom gases) to enhance nonlinear optical interactions to unprecedented levels in solid state systems. This feat is a first step towards realizing chip-scale scalable single photon switches.

 

Half-Light, Half-Matter Quantum Particles

 

In solid state systems, exciton-polaritons, half-light half-matter quasiparticles, which result from the hybridization of electronic excitations (excitons) and photons, are an attractive candidate to realize nonlinearities at the quantum limit. “Here we realize these quasiparticles with Rydberg excitons (excited states of excitons) in atomically thin semiconductors (2D materials),” said Menon, chair of physics in City College’s Division of Science. “Excited states of excitons owing to their larger size, show enhanced interactions and therefore hold promise for accessing the quantum domain of single-photon nonlinearities, as demonstrated previously with Rydberg states in atomic systems.”

 

According to Menon, the demonstration of Rydberg exciton-polaritons in two-dimensional semiconductors and their enhanced nonlinear response presents the first step towards the generation of strong photon interactions in solid state systems, a necessary building block for quantum photonic technologies...

 
https://scitechdaily.com/single-photon-switch-advance-rydberg-states-in-solid-state-materials/


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A breakthrough that enables practical semiconductor spintronics

 

April 8, 2021

 

It may be possible in the future to use information technology where electron spin is used to store, process and transfer information in quantum computers. It has long been the goal of scientists to be able to use spin-based quantum information technology at room temperature. A team of researchers from Sweden, Finland and Japan have now constructed a semiconductor component in which information can be efficiently exchanged between electron spin and light at room temperature and above. The new method is described in an article published in Nature Photonics.

https://bioengineer.org/a-breakthrough-that-enables-practical-semiconductor-spintronics/

 

____________________________________

 

Spintronics Breakthrough: Unlocking the Quantum Potential of Graphene With Cobalt

 

 September 24, 2024

 

Spintronics offers the potential for devices that operate faster and use less energy by manipulating electron spins. Graphene, when layered with cobalt and heavy metals like iridium, shows enhanced quantum effects that are beneficial for spintronics, such as increased spin-orbit coupling and spin canting.

https://scitechdaily.com/spintronics-breakthrough-unlocking-the-quantum-potential-of-graphene-with-cobalt/

 

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Graphene Is Stretchable? Physicists Make “Miracle Material” Bend Like Never Before

June 2, 2025

 

https://advancedcarbonscouncil.org/blogpost/2151389/511208/Graphene-Is-Stretchable-Physicists-Make-Miracle-Material-Bend-Like-Never-Before 

____________________________________

The Edge Effect Exposed: How Graphene’s Secret Currents Could Transform Tech

 

February 13, 2025 

 

In a groundbreaking study, researchers discovered how bilayer graphene could revolutionize data processing through valleytronics, revealing how electron transport depends heavily on the state of the material’s edges and the presence of nonlocal transport mechanisms.

https://scitechdaily.com/the-edge-effect-exposed-how-graphenes-secret-currents-could-transform-tech/

 

____________________________________

 

 

This Ancient Iron Oxide Is Secretly Powering the Next Computing Revolution

 

April 29, 2025

 

Researchers at EPFL have made a breakthrough by storing and manipulating digital data using charge-free spin waves, moving toward greener, faster computing.

 

Pioneering Data Storage With Spin Waves

 

In 2023, researchers at EPFL made a major breakthrough by transmitting and storing data using spin waves, magnetic waves that carry no electrical charge, instead of traditional electron flows. The team, led by Dirk Grundler from the Lab of Nanoscale Magnetic Materials and Magnonics in the School of Engineering, used radiofrequency signals to excite spin waves strongly enough to reverse the magnetization of tiny nanomagnets. This switching between magnetic states, such as from 0 to 1, allows the nanomagnets to store digital information, a fundamental process in computer memory and broader information and communication technologies.

 

This advance marked a significant step toward more sustainable computing. By encoding data with spin waves, whose quasiparticles are known as magnons, the researchers could potentially eliminate the energy loss, or Joule heating, that plagues electron-based devices. However, at the time, the spin wave signals could only switch the nanomagnets once and could not yet be used to reset them for overwriting existing data.

 

“Hematite exhibits entirely new spin physics that can be harvested for signal processing at ultrahigh frequencies, which is essential for the development of ultrafast spintronic devices and their applications in next-generation information and communication technology.”

 

https://scitechdaily.com/this-ancient-iron-oxide-is-secretly-powering-the-next-computing-revolution/ 

 

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AI Game-Changer: Nanoelectronic Devices Uses 100x Less Energy

 

October 12, 2023

 
https://scitechdaily.com/ai-game-changer-nanoelectronic-devices-uses-100x-less-energy/

 

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New Manufacturing Method Enables Ultra-Efficient Atomic Computers That Use 100x Less Power

 

November 28, 2019

 

As computers continue to infiltrate almost every aspect of modern life, their negative impact on the environment grows. According to recent estimates, the electricity required to power today’s computers releases a total of more than 1 gigatonne of carbon emissions to the atmosphere each year. Now, researchers reporting in ACS Nano have developed a new manufacturing process that could enable ultra-efficient atomic computers that store more data and consume 100 times less power. 

 

Scientists have previously manipulated single atoms to make ultra-dense memory arrays for computers, which store more data in a much smaller space than conventional hard drives and consume much less power. In a technique known as hydrogen lithography, researchers use the tip of a scanning tunneling microscope (STM) to remove single atoms of hydrogen bonded to a silicon surface. The pattern of silicon atoms bound to or lacking a hydrogen atom forms a binary code that stores the data. However, there is a bottleneck when rewriting the data because the STM tip must pick up and deposit hydrogen atoms at precise locations. Roshan Achal, Robert Wolkow, and colleagues wanted to develop a more efficient method to rewrite atomic memory arrays.

https://scitechdaily.com/new-manufacturing-method-enables-ultra-efficient-atomic-computers-that-use-100x-less-power/

 

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Quantum Breakthrough Could Make Your Devices 1,000 Times Faster

 

10 July 2025

 

https://www.sciencealert.com/quantum-breakthrough-could-make-your-devices-1000-times-faster


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Chapter 21: Chips, Wires & Wafers

 

 
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IBM to demonstrate first on-package silicon photonics

 

March 13, 2015 

 One of the most tantalizing next-generation technologies that could dramatically reduce system power consumption and improve bandwidth is silicon photonics. This method of chip-to-chip communication uses silicon as an optical medium, and transmits data incredibly quickly with far better power consumption and thermals than traditional copper wires. Now, IBM is claiming to have advanced the technology a significant step by integrating a silicon photonic chip on the same package as a CPU.

 http://www.extremetech.com/extreme/201163-ibm-to-demonstrate-first-on-package-silicon-photonics

 

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The Last Missing Piece Of The Silicon Photonics Puzzle

December 9, 2024

 

An international research team has reached a milestone in silicon photonics: They have developed the first electrically pumped semiconductor laser for continuous operation that consists entirely of elements from the fourth main group - the "silicon group". The new laser is based on ultra-thin layers of silicon-germanium-tin and germanium-tin and can be integrated directly into silicon chips. This solves a central problem of on-chip photonics: the seamless connection of optical and electronic components on a single chip. The results of the research work were published in the journal Nature Communications .

https://www.photonicsonline.com/doc/the-last-missing-piece-silicon-photonics-puzzle-0001

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Blue-fluorescent molecular nanocapsules created by simple mixing 'green-environmentally friendly' metal ions and bent organic blocks

 

July 12, 2012

 New fluorescent molecular nanocapsules have potential applications as sensors, displays, and drug delivery systems (DDS).

 Michito Yoshizawa, Zhiou Li, and collaborators at Tokyo Institute of Technology (Tokyo Tech) synthesized ~1 nanometer-sized molecular capsules with an isolated cavity using green and inexpensive zinc and copper ions. In sharp contrast to previous molecular capsules and cages composed of precious metal ions such as palladium and platinum, these nanocapsules emit blue fluorescence with 80% efficiency.

 http://www.sciencedaily.com/releases/2012/07/120712111634.htm


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Certain groups are trying to use tiles in spacecraft,these tiles do not require certain chemicals for waterproofing.

You could even implement a 3D-printer to make items in space travel, we could even make constructions from organic chemicals found in space.

 

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Growing Computers in Space? Novel Organic and Polymeric Materials for Optical Devices

http://science.nasa.gov/science-news/science-at-nasa/1996/msad4sep96_1/


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We're One Step Closer to Blazingly Fast Computer Chips Made of Silicene

2/03/15

 

http://gizmodo.com/were-one-step-closer-to-blazingly-fast-computer-chips-o-1683541326

 

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Researchers develop technique for integrating 'III-V' materials onto silicon wafers

 

 June 8th, 2015

 

  A team of IBM researchers in Zurich, Switzerland with support from colleagues in Yorktown Heights, New York has developed a relatively simple, robust and versatile process for growing crystals made from compound semiconductor materials that will allow them be integrated onto silicon wafers—an important step toward making future computer chips that will allow integrated circuits to continue shrinking in size and cost even as they increase in performance.

 http://phys.org/news/2015-06-technique-iii-v-materials-silicon-wafers.html#jCp

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Just How Can Next-Generation Computer Chips Reduce Our Carbon Footprint?

January 5, 2022

https://science-atlas.com/technology/just-how-can-next-generation-computer-chips-reduce-our-carbon/?utm_referrer=https%3A%2F%2Fduckduckgo.com%2F

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Physicists Built a “Trampoline” Smaller Than a Human Hair – And It Could Rewrite the Rules of Microchip Design

June 18, 2025

 

https://longevityone.org/physicists-built-a-trampoline-smaller-than-a-human-hair-and-it-could-rewrite-the-rules-of-microchip-design/

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The First Plastic Computer Processor

 

 

Two recent developments—a plastic processor and printed memory—show that computing doesn’t have to rely on inflexible silicon. 

 

• By Tom Simonite on March 25, 2011

http://www.technologyreview.com/news/423410/the-first-plastic-computer-processor/

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Quantum computing breakthrough: Qubits made from standard silicon transistors

 

October 6, 2015

In what is likely a major breakthrough for quantum computing, researchers from the University of New South Wales (UNSW) in Australia have managed for the first time to build the fundamental blocks of a quantum computer in silicon. The device was created using standard manufacturing techniques, by modifying current-generation silicon transistors, and the technology could scale up to include thousands, even millions of entangled quantum bits on a single chip. Gizmag spoke to the lead researchers to find out more.

http://www.gizmag.com/silicon-quantum-computer/39711/?li_source=LI&li_medium=default-widget

 
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Qubits for Quantum Computing With Atom-Thin Materials

February 5, 2022

 

For quantum computers to surpass their classical counterparts in speed and capacity, their qubits—which are superconducting circuits that can exist in an infinite combination of binary states—need to be on the same wavelength. Achieving this, however, has come at the cost of size. Whereas the transistors used in classical computers have been shrunk down to nanometer scales, superconducting qubits these days are still measured in millimeters—one millimeter is one million nanometers. Combine qubits together into larger and larger circuit chips, and you end up with, relatively speaking, a big physical footprint, which means quantum computers take up a lot of physical space (Qubits for Quantum Computing With Atom-Thin Materials). These are not yet devices we can carry in our backpacks or wear on our wrists.

https://nanodigest.in/shrinking-superconducting-qubits-for-quantum-computing-with-atom-thin-materials/

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Smart amplifier cuts power consumption, paving way for more qubits and less decoherence

 

June 25, 2025

https://phys.org/news/2025-06-smart-amplifier-power-consumption-paving.html

 

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Trapped-ion advances break new ground in quantum computing

 

June 12, 2025

https://phys.org/news/2025-06-ion-advances-ground-quantum.html

 

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 “Fundamental Discovery” Used To Turn Nanotube Into Tiny Transistor – 25,000x Smaller Than Width of a Human Hair

26th, Dec 2021

https://statnano.com/world-news/89925/%E2%80%9CFundamental-Discovery%E2%80%9D-Used-To-Turn-Nanotube-Into-Tiny-Transistor-%E2%80%93-25-000x-Smaller-Than-Width-of-a-Human-Hair

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Research Suggests Semiconductor Nanowires Can Unlock Ultrafast Transistors

February 16, 2022

 

A collaborative team of researchers with the Helmholtz-Zentrum Dresden-Rossendorf (HZDR), the TU Dresden, and NaMLab has demonstrated significantly enhanced electron mobility in nanowires when these are put under tensile strain. An important metric for transistor performance, the increased electron mobility is expected to provide significant performance, thermal and power efficiency improvements that could unlock even faster transistors for future chips. 

 

https://www.tomshardware.com/news/nanowires-research-suggests-ultrafast-transistors 



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The Dawn of a New Era: A New Type of Quantum Bit Achieved in Semiconductor Nanostructures

 

2023

https://scitechpost.com/the-dawn-of-a-new-era-a-new-type-of-quantum-bit-achieved-in-semiconductor-nanostructures/

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Mind the band gap! -- researchers create new nanoscale forms of elementary semiconductor with tunable electronic properties

 

May 22, 2025

 

Researchers have demonstrated that by using a semiconductor with flexible bonds, the material can be moulded into various structures using nano containers, without altering its composition, the discovery could lead to the design of a variety of customised electronic devices using only a single element.

https://www.sciencedaily.com/releases/2025/05/250521124123.htm

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New transistor could cut 5% from world’s digital energy budget

 

 April 11, 2022

 

Design also poised to save space, retain memory in event of power loss

 

https://news.unl.edu/article/new-transistor-could-cut-5-from-world-s-digital-energy-budget 

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High-temperature superconductivity

http://en.wikipedia.org/wiki/High-temperature_superconductivity



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Two spin liquids square off in an iron-based superconductor

August 5, 2015 

 

 Despite a quarter-century of research since the discovery of the first high-temperature superconductors, scientists still don't have a clear picture of how these materials are able to conduct electricity with no energy loss. Studies to date have focused on finding long-range electronic and magnetic order in the materials, such as patterns of electron spins, based on the belief that this order underlies superconductivity. But a new study published online the week of August 3, 2015, in the Proceedings of the National Academy of Sciences is challenging this notion.

http://phys.org/news/2015-08-liquids-square-iron-based-superconductor.html#jCp

 

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 Superconducting secrets solved after 30 years

 15 Jun 2014

 See more at: http://www.cam.ac.uk/research/news/superconducting-secrets-solved-after-30-years#sthash.urBkHuLs.dpuf


Researchers from the University of Cambridge have found that ripples of electrons, known as charge density waves or charge order, create twisted ‘pockets’ of electrons in these materials, from which superconductivity emerges. The results are published in the June 15th issue of the journal Nature.

Low-temperature, or conventional, superconductors were first identified in the early 20th century, but they need to be cooled close to absolute zero (zero degrees on the Kelvin scale, or -273 degrees Celsius) before they start to display superconductivity. So-called high-temperature superconductors however, can display the same properties at temperatures up to 138 Kelvin (-135 degrees Celsius), making them much more suitable for practical applications.

Since they were first identified in the mid-1980s, the process of discovering new high-temperature superconductors could be best described as random. While researchers have identified the ingredients that make for a good low-temperature superconductor, high-temperature superconductors have been more reluctant to give up their secrets.

In a superconductor, as in any electronic device, current is carried via the charge on an electron. What is different about superconductors is that the electrons travel in tightly bound pairs. When traveling on their own, electrons tend to bump into each other, resulting in a loss of energy. But when paired up, the electrons move smoothly through a superconductor’s structure, which is why superconductors can carry current with no resistance. As long as the temperature is kept sufficiently low, the electron pairs will keep moving through the superconductor indefinitely.

Key to conventional superconductors are the interactions of electrons with the lattice structure of the material. These interactions generate a type of ‘glue’ which holds the electrons together. The strength of the glue is directly related to the strength of the superconductor, and when the superconductor is exposed to an increase in temperature or magnetic field strength, the glue is weakened, the electron pairs break apart and superconductivity is lost.  -


- Working with extremely strong magnetic fields, the researchers were able to kill the superconducting effect in cuprates - thin sheets of copper and oxygen separated by more complex types of atoms.

Previous attempts to determine the origins of superconductivity by determining the normal state have used temperature instead of magnetic field to break the electron pairs apart, which has led to inconclusive results.

As cuprates are such good superconductors, it took the strongest magnetic fields in the world – 100 Tesla, or roughly one million times stronger than the Earth’s magnetic field – in order to suppress their superconducting properties.

These experiments were finally able to solve the mystery surrounding the origin of pockets of electrons in the normal state that pair to create superconductivity. It was previously widely held that electron pockets were located in the region of strongest superconductivity. Instead, the present experiments using strong magnetic fields revealed a peculiar undulating twisted pocket geometry -similar to Jenga bricks where each layer goes in a different direction to the one above or beneath it.

These results pinpointed the pocket locations to be where superconductivity is weakest, and their origin to be ripples of electrons known as charge density waves, or charge order. It is this normal state that is overridden to yield superconductivity in the family of cuprate superconductors studied.


____________________________________

 


Physicists discover new properties of superconductivity

 

February 4, 2016 

 

 

New findings from an international collaboration led by Canadian scientists may eventually lead to a theory of how superconductivity initiates at the atomic level, a key step in understanding how to harness the potential of materials that could provide lossless energy storage, levitating trains and ultra-fast supercomputers.
 

http://phys.org/news/2016-02-physicists-properties-superconductivity.html

 

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Hole-y Superconductor: Entirely New State of Matter Discovered

 

 November 14, 2019

 

 

Tiny holes punched into a high-temperature superconducting material revealed that Cooper pairs, electron duos that enable superconductivity, can also conduct electricity the way metals do. 

 

In a finding that reveals an entirely new state of matter, research published in the journal Science shows that Cooper pairs, electron duos that enable superconductivity, can also conduct electricity like normal metals do.

 

For years, physicists have assumed that Cooper pairs, the electron duos that enable superconductors to conduct electricity without resistance, were two-trick ponies. The pairs either glide freely, creating a superconducting state, or create an insulating state by jamming up within a material, unable to move at all.

 

But in a new paper published today (November 14, 2019) in Science, a team of researchers has shown that Cooper pairs can also conduct electricity with some amount of resistance, as regular metals do. The findings describe an entirely new state of matter, the researchers say, that will require a new theoretical explanation.

 

“There had been evidence that this metallic state would arise in thin-film superconductors as they were cooled down toward their superconducting temperature, but whether or not that state involved Cooper pairs was an open question,” said Jim Valles, a professor of physics at Brown University and the study’s corresponding author. “We’ve developed a technique that enables us to test that question and we showed that, indeed, Cooper pairs are responsible for transporting charge in this metallic state. What’s interesting is that no one is quite sure at a fundamental level how they do that, so this finding will require some more theoretical and experimental work to understand exactly what’s happening.”

 
https://scitechdaily.com/hole-y-superconductor-entirely-new-state-of-matter-discovered/

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Phosphorene nanoribbons shown to exhibit magnetic and semiconductor properties at room temperature

March 12, 2025

https://phys.org/news/2025-03-phosphorene-nanoribbons-shown-magnetic-semiconductor.html

 

____________________________________

 

 

Quantum Properties in Atom-thick Semiconductors Offer New Way to Detect Electrical Signals in Cells

March 03, 2025

For decades, scientists have relied on electrodes and dyes to track the electrical activity of living cells. Now, engineers at the University of California San Diego have discovered that quantum materials just a single atom thick can do the job—using only light.

A new study, published on Mar. 3 in Nature Photonics, shows that these ultra-thin semiconductors, which trap electrons in two dimensions, can be used to sense the biological electrical activity of living cells with high speed and resolution.

https://today.ucsd.edu/story/quantum-properties-in-atom-thick-semiconductors-offer-new-way-to-detect-electrical-signals-in-cells

 

____________________________________

 

The Strange Secret Behind These Semiconductors That Seemingly Defy Physics

 

May 5, 2025

 

The mechanism that stabilizes new ferroelectric semiconductors also creates a conductive pathway, which could make them suitable for use in high-power transistors. 

 

A new type of semiconductor that can store information using electric fields may lead to more energy-efficient computers, ultra-precise sensors, and technologies that convert signals between electrical, optical, and acoustic forms. However, scientists had long been puzzled by how these materials could sustain two opposing electric polarizations without breaking apart.

 

A team of engineers at the University of Michigan has now uncovered why the materials, known as wurtzite ferroelectric nitrides, don’t tear themselves apart.

 

“The wurtzite ferroelectric nitrides were recently discovered and have a broad range of applications in memory electronics, RF (radio frequency) electronics, acousto-electronics, microelectromechanical systems, and quantum photonics, to name just a few. But the underlying mechanism of ferroelectric switching and charge compensation has remained elusive,” said Zetian Mi, the Pallab K. Bhattacharya Collegiate Professor of Engineering and co-corresponding author of the study published in Nature.

https://scitechdaily.com/the-strange-secret-behind-these-semiconductors-that-seemingly-defy-physics/

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Scientists Unlock New Flexible Semiconductor Using Atomic “Vacancy Engineering”

 

April 26, 2025

 

Researchers have created a flexible semiconductor that efficiently converts body heat into electricity through atomic vacancy engineering. This innovation opens new possibilities for wearable devices, combining flexibility and high thermoelectric performance.

 

Researchers at Queensland University of Technology (QUT) have discovered a new material that could serve as a flexible semiconductor for wearable devices. Their approach centers on manipulating the spaces between atoms, known as “vacancies,” within a crystal structure.

 

In a study published in the prestigious journal Nature Communications, the team demonstrated how “vacancy engineering” significantly improves the performance of an AgCu(Te,Se,S) semiconductor, an alloy composed of silver, copper, tellurium, selenium, and sulfur. By carefully controlling atomic vacancies, they enhanced the material’s ability to convert body heat into electricity, a key function for powering wearable technologies.

 
https://scitechdaily.com/scientists-unlock-new-flexible-semiconductor-using-atomic-vacancy-engineering/

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Add a twist to π-molecules: A new design strategy for organic semiconductor materials

June 25, 2025

A research team has synthesized three-dimensionally shaped molecules containing an internal twist and shown that they possess the properties of organic semiconductors. By introducing methyl groups into a planar molecule containing several thiophene units and forcing it into a twisted conformation, the team created a solid-state structure in which electricity can flow three-dimensionally.

The molecule was verified to act as an organic semiconductor in an organic field-effect transistor, paving the way for next-generation electronic devices...

https://phys.org/news/2025-06-molecules-strategy-semiconductor-materials.html

 

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Meet MEGA2D: The Tiny Machine Twisting Material Science into the Future

January 7, 2025

A novel device now enables scientists to easily adjust the twist between layers of ultra-thin materials, promising significant advances in electronics and optics. This could lead to better transistors and solar cells, and enhance research in quantum computing. Six years ago, a groundbreaking discovery revolutionized condensed-matter physics: ultra-thin carbon layers, stacked at a slight angle..

https://mycbh.com/Games/blog/2025/01/07/meet-mega2d-the-tiny-machine-twisting-material-science-into-the-future/

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Physicists at Lancaster University have shown that the recently reported “electrostatic field effect” in superconductors is not a groundbreaking discovery but rather a result of hot electron injection.

  

May 12, 2021

 

Lancaster scientists have demonstrated that other physicists’ recent “discovery” of the field effect in superconductors is nothing but hot electrons after all.

 

Superconductivity and Electric Fields

 

When certain metals are cooled to a few degrees above absolute zero, their electrical resistance vanishes — a striking physical phenomenon known as superconductivity. Many metals, including vanadium, which was used in the experiment, are known to exhibit superconductivity at sufficiently low temperatures.

 

For decades it was thought that the exceptionally low electrical resistance of superconductors should make them practically impervious to static electric fields, owing to the way the charge carriers can easily arrange themselves to compensate for any external field.

 

It therefore came as a shock to the physics community when a number of recent publications claimed that sufficiently strong electrostatic fields could affect superconductors in nanoscale structures — and attempted to explain this new effect with corresponding new physics. A related effect is well known in semiconductors and underpins the entire semiconductor industry.

https://scitechdaily.com/brand-new-physics-of-superconducting-metals-busted/

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Crystal clear design for high-performance flexible thermoelectric semiconductor

04/23/2025


QUT researchers have identified a new material which could be used as a flexible semiconductor in wearable devices by using a technique that focuses on the manipulation of spaces between atoms in crystals.

In a study published in the prestigious journal Nature Communication, the researchers used "vacancy engineering" to enhance the ability of an AgCu(Te, Se, S) semiconductor, which is an alloy made up of silver, copper, tellurium, selenium and sulphur, to convert body heat into electricity.

Vacancy engineering is the study and manipulation of empty spaces, or "vacancies," in a crystal where atoms are missing, to influence the material's properties, such as improving its mechanical properties or optimising its electrical conductivity, or thermal properties...

https://www.publicnow.com/view/BA2FA91AF7DF8D72D374D6E39D0216FB5EAA1E41?1745365546

 

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New invention revolutionizes heat transport

 

February 1, 2016

 

 Scientists at Aalto University, Finland, have made a breakthrough in physics. They succeeded in transporting heat maximally effectively ten thousand times further than ever before. The discovery may lead to a giant leap in the development of quantum computers.

 

 http://phys.org/news/2016-02-revolutionizes.html



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Heavy fermions get nuclear boost on way to superconductivity

January 28, 2016

 In a surprising find, physicists from the United States, Germany and China have discovered that nuclear effects help bring about superconductivity in ytterbium dirhodium disilicide (YRS), one of the most-studied materials in a class of quantum critical compounds known as "heavy fermions."

The discovery, which is described in this week's issue of Science, marks the first time that superconductivity has been observed in YRS, a composite material that physicists have studied for more than a decade in an effort to probe the quantum effects believed to underlie high-temperature superconductivity.

Rice University physicist and study co-author Qimiao Si said the research provides further evidence that unconventional superconductivity arises from "quantum criticality."

 http://phys.org/news/2016-01-heavy-fermions-nuclear-boost-superconductivity.html



____________________________________ 

Quantum Faraday and Kerr rotations in graphene

 

Published  14 May 2013

 

Graphene, a monolayer sheet of carbon atoms, exhibits intriguing electronic properties that arise from its massless Dirac dispersion of electrons. A striking example is the half-integer quantum Hall effect, which endorses the presence of Dirac cones or, equivalently, a non-zero (π) Berry’s (topological) phase. It is curious how these anomalous features of Dirac electrons would affect optical properties. Here we observe the quantum magneto-optical Faraday and Kerr effects in graphene in the terahertz frequency range. Our results detect the quantum plateaus in the Faraday and Kerr rotations at precisely the quantum Hall steps that hallmark the Dirac electrons, with the rotation angle defined by the fine-structure constant. The robust quantum Hall plateaus in the optical regime, besides being conceptually interesting, may open avenues for new graphene-based optoelectronic applications.

http://www.nature.com/ncomms/journal/v4/n5/full/ncomms2866.html


____________________________________

Nano-Sized Gold Electricity Generators Moving a Step Ahead

 

May 29, 2009

http://www.greenoptimistic.com/nano-gold-electricity-generator-20090529/#.VSF32OG-2zk

 

____________________________________

Handbook of Renewable Energy Technology

 

https://books.google.com/books?id=jWtYPbnJQVcC&pg=PA190&lpg=PA190&dq=harvesting+energy+from+the+earth%27s+rotation&source=bl&ots=Xs7SYcg6Vk&sig=7u5DQVq5V9T25dQL_sRkuai7oYc&hl=en&sa=X&ei=i98hVfPHE871oASxq4H4DA&ved=0CEUQ6AEwCDgU#v=onepage&q=harvesting%20energy%20from%20the%20earth%27s%20rotation&f=false


____________________________________

 

Calcium-Aluminum High Voltage Power Cables Could be Lighter and More Durable

 

April 3, 2013

http://www.greenoptimistic.com/calcium-aluminum-power-cable-20130403/

 

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A chain of copper and carbon atoms may be the thinnest metallic wire

Jun 12, 2024

 

Researchers from the Laboratory for Theory and Simulation of Materials at EPFL have used computational methods to identify what could be the thinnest possible metallic wire, as well as several other unidimensional materials with properties that could prove interesting for many applications.

Unidimensional (or 1-D) materials are one of the most intriguing products of nanotechnology and are made of atoms aligned in the form of wires or tubes. Their electrical, magnetic, and optical properties make them excellent candidates for applications ranging from microelectronics to biosensors to catalysis. While carbon nanotubes are the materials that have received most of the attention so far, they have proved very difficult to manufacture and control, so scientists are eager to find other compounds that could be used to create nanowires and nanotubes with equally interesting properties, but easier to handle.

https://www.nanotechnologyworld.org/post/a-chain-of-copper-and-carbon-atoms-may-be-the-thinnest-metallic-wire

 

____________________________________

 

Quantum Well Nanowire Array Micro-LEDs: The Future of On-chip Optical Communication

	17th, Sep 2023

 

https://statnano.com/world-news/102374/Quantum-Well-Nanowire-Array-Micro-LEDs-The-Future-of-On-chip-Optical-Communication

 

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Nanowire Innovation: Revolutionizing Fuel Cells With Enhanced Durability

 

August 28, 2023

 
https://scitechdaily.com/nanowire-innovation-revolutionizing-fuel-cells-with-enhanced-durability/

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Atomic-scale nanowires can now be produced at scale

 

24-Dec-2020 

 

Scalable synthesis of transition metal chalcogenide nanowires for next-gen electronics 

 

Tokyo, Japan - Researchers from Tokyo Metropolitan University have discovered a way to make self-assembled nanowires of transition metal chalcogenides at scale using chemical vapor deposition. By changing the substrate where the wires form, they can tune how these wires are arranged, from aligned configurations of atomically thin sheets to random networks of bundles. This paves the way to industrial deployment in next-gen industrial electronics, including energy harvesting, and transparent, efficient, even flexible devices.

 

Electronics is all about making things smaller. Smaller features on a chip, for example, means more computing power in the same amount of space and better efficiency, essential to feeding the increasingly heavy demands of a modern IT infrastructure powered by machine learning and artificial intelligence. And as devices get smaller, the same demands are made of the intricate wiring that ties everything together. The ultimate goal would be a wire that is only an atom or two in thickness. Such nanowires would begin to leverage completely different physics as the electrons that travel through them behave more and more as if they live in a one-dimensional world, not a 3D one.

 

In fact, scientists already have materials like carbon nanotubes and transition metal chalcogenides (TMCs), mixtures of transition metals and group 16 elements which can self-assemble into atomic-scale nanowires. The trouble is making them long enough, and at scale. A way to mass produce nanowires would be a game changer.

 

https://www.eurekalert.org/news-releases/800891 

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Creating Indestructible Self-Healing Circuits

 

 March 11, 2013

 

 

 

Some of the damage Caltech engineers intentionally inflicted on their self-healing power amplifier using a high-power laser. The chip was able to recover from complete transistor destruction. This image was captured with a scanning electron microscope.

 

PASADENA, Calif.—Imagine that the chips in your smart phone or computer could repair and defend themselves on the fly, recovering in microseconds from problems ranging from less-than-ideal battery power to total transistor failure. It might sound like the stuff of science fiction, but a team of engineers at the California Institute of Technology (Caltech), for the first time ever, has developed just such self-healing integrated chips.

 

The team, made up of members of the High-Speed Integrated Circuits laboratory in Caltech's Division of Engineering and Applied Science, has demonstrated this self-healing capability in tiny power amplifiers. The amplifiers are so small, in fact, that 76 of the chips—including everything they need to self-heal—could fit on a single penny. In perhaps the most dramatic of their experiments, the team destroyed various parts of their chips by zapping them multiple times with a high-power laser, and then observed as the chips automatically developed a work-around in less than a second.

 
https://www.caltech.edu/about/news/creating-indestructible-self-healing-circuits-38815

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Physicists Build Circuit That Generates Clean, Limitless Power From Graphene

 

 Oct. 02, 2020

https://news.uark.edu/articles/54830/physicists-build-circuit-that-generates-clean-limitless-power-from-graphene


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Skyrmion ‘whirls’ show promise for low-energy computer circuitry

March 31, 2020

 

UNSW material scientists have shed new light on a promising new way to store and process information in computers and electronic devices that could significantly cut down the energy required to maintain our digital lifestyles.

 

Skyrmions, which can be described as ‘whirl’ shaped magnetic textures at the nano-level, have in recent years been flagged as contenders for a more efficient way to store and process information. One of their advantages is that they possess a kind of built-in enhanced stability over time, making stored information non-volatile and ‘live’ longer. Up until now, information in computers is processed through dynamic memory, which is less stable and therefore requires more energy to maintain.

 

According to researchers from UNSW Science, who also collaborated with researchers from Brookhaven National Laboratory in the US and the University of Auckland, the potential of what they call “skyrmion lattice manipulation” to lower energy consumption in electronics is an attractive alternative.

https://sciencebulletin.org/skyrmion-whirls-show-promise-for-low-energy-computer-circuitry/

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This Computer Is About to Change The World


Jul 22, 2020

https://www.youtube.com/watch?v=AZP9CU-RPpw



____________________________________

 

PLANET-SIZED Computers - Technological Endpoints of Civilization


Apr 29, 2020

https://www.youtube.com/watch?v=Rmb1tNEGwmo


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Fast-Charging Supercapacitor is an Energy Storage Breakthrough

March 11, 2020

 

A new bendable supercapacitor made from graphene, which charges quickly and safely stores a record-high level of energy for use over a long period, has been developed and demonstrated by UCL and Chinese Academy of Sciences researchers.

 

While still at the proof-of-concept stage, it shows enormous potential as a portable power supply in practical applications including electric vehicles, smart phones and smart wearable technology. The discovery overcomes the issue faced by high-powered, fast-charging supercapacitors — that they usually cannot hold a large amount of energy in a small space.

 

Dr. Zhuangnan Li (UCL Chemistry) said: “Our new supercapacitor is extremely promising for next-generation energy storage technology as either a replacement for current battery technology, or for use alongside it, to provide the user with more power. We designed materials that would give our supercapacitor a high power-density — which is how fast it can charge or discharge; and a high energy-density — which will determine how long it can run. Normally, you can only have one of these characteristics, but our supercapacitor provides both.”

 

The supercapacitor can bend to 180 degrees without affecting performance and doesn’t use a liquid electrolyte, which minimizes the risk of explosion. This makes it ideal for integrating into bendy smart phones or wearable electronics.

 

https://www.techbriefs.com/component/content/article/36298-fast-charging-supercapacitor-is-an-energy-storage-breakthrough

 

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Ultralow-Temperature Supercapacitors Using Porous Carbon Aerogel – Could Power Mars & Polar Missions

  

Mar 11, 2021

 

Researchers wanted to develop an energy storage system that could operate at very low temperatures without heating units

 

NASA’s Perseverance Rover recently made a successful landing on Mars, embarking on a two-year mission to seek signs of ancient life and collect samples. Because Mars is extremely cold — nighttime temperatures can drop below -112 F  (-80 C) — heaters are required to keep the rover’s battery system from freezing. Now, researchers reporting in ACS’ Nano Letters have 3D printed porous carbon aerogels for electrodes in ultralow-temperature supercapacitors, reducing heating needs for future space and polar missions.

https://scitechdaily.com/ultralow-temperature-supercapacitors-using-porous-carbon-aerogel-could-power-mars-polar-missions/

 

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Nitrogen and argon plasma boosts performance of carbon-based supercapacitor electrodes

April 3, 2025

 

 

A colored micrograph showing unmodified carbon nanowalls as seen with a scanning electron microscope.

Scientists from Skoltech, the Institute of Nanotechnology of Microelectronics, RAS, and other research centers have refined the understanding of how plasma treatment of carbon-based electrodes affects the key characteristics of supercapacitors. These are energy storage devices that complement batteries in electric cars, trains, port cranes, and elsewhere.

https://phys.org/news/2025-04-nitrogen-argon-plasma-boosts-carbon.html

 

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Emergence of 2.5D Materials for Futuristic Applications

June 29, 2022

 

In recent years, 2-dimensional (2D) Cheap and energy-efficient electronics materials such as graphene are making waves in scientific world due to their unique physical, chemical, and electronic properties and high potential applicability in flexible electronics, strain sensors, nanogenerators, innovative nanoelectromechanical systems (NEMS) and so on. Graphene is not the only candidate of a whole family of 2D materials. Now we have 2.5D materials (Emergence of 2.5D Materials for Futuristic Applications) that are likely to have huge impact on futuristic applications. 

 

The other cousins such as MXenes, oxides, boron nitride, transition metal chalcogenides, metal-organic frameworks, clays, polymers also belong to the same family of 2D materials. 2D materials, like graphene, are made of a single layer of atoms and are used in applications for next generation flexible electronic evolution, including electromechanical sensors, biomedical devices, energy storage, field effect transistors, supercapacitors and so on.

 

The next generation materials, so called 2.5D materials offers a novel approach to synthesizing materials with unique properties by controlling their weak out-of-plane van der Waals (vdW) interactions. Researchers from Global Innovation Center, Kyushu University, Fukuoka and other universities from Japan are intensively pursuing research to find new strategies to artificially stack two-dimensional (2D) materials, introducing 2.5D materials with unique physical properties. These researchers have reviewed the latest advances and applications of 2.5D materials in the journal Science and Technology of Advanced Materials(Science of 2.5 dimensional materials: paradigm shift of materials science toward future social innovation).

 

In a new concept,different 2D materials are artificially stacked together either in a vertical plane or at twisted angles by using advanced transfer technique (1,2), irrespective of their, lattice constants or composition. This is feasible because our ability to control weak plane van der Waals (vdW) electrical interactions between atoms and molecules and since the stacks are not limited by rigid chemical bonds. In addition, there is a possibility to integrate 2D materials with other dimensional materials – molecules and ions (zero-dimensional (0D)), nanotubes and nanowires (one-dimensional (1D)), and bulk crystals (three-dimensional (3D)).

 

As illustrated in Figure 1, there is a symbiotic relationship between bulk 3D materials and 2D materials. We call these new materials and architectures ‘2.5D materials,’ where the 0.5D signifies the new dimension created by combining 2D materials through artificial manipulations, such as stacking, twisting, and connecting as well as through the 2D nano- space within 2D material stacks.

 

https://nanodigest.in/emergence-of-2-5d-materials-for-futuristic-applications/

 

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Breakthrough in Electron Microscopy Captures Individual Nanoparticles with Unprecedented Precision

June 20, 2025

 

Electron Microscopy Captures Individual Nanoparticles: Imagine being able to see the tiniest building blocks of our world—nanoparticles—as clearly as you see the pages of a book. Thanks to a recent breakthrough in electron microscopy, scientists can now capture and study individual nanoparticles with a level of detail and precision never before possible. This remarkable advancement is not just a technical feat; it’s opening doors to new discoveries in medicine, electronics, energy, and beyond. 

https://stc-mditr.org/electron-microscopy-captures-individual-nanoparticles/

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Chaining Atoms Together Yields Quantum Storage

 

February 16, 2022

 

New technique could make quantum networking possible

 

Engineers at Caltech have developed an approach for quantum storage that could help pave the way for the development of large-scale optical quantum networks.

 

The new system relies on nuclear spins—the angular momentum of an atom's nucleus—oscillating collectively as a spin wave. This collective oscillation effectively chains up several atoms to store information.

https://www.caltech.edu/about/news/chaining-atoms-together-yields-quantum-storage

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Ionic channels in carbon electrodes for efficient electrochemical energy storage

 

24-Oct-2019

 

The rapid development of electronic devices and power equipment, such as new-energy vehicles and robots, has sparked extensive demand for portable power sources. Electrochemical energy storage, mainly based on ionic intercalation/motion or adsorption/diffusion in electrodes, has been utilized in last two centuries. Ionic transport is slower yet complicated in electrodes when compared to electronic transport. Indeed, charging/discharging processes in batteries typically take several hours for the efficient use of internal space or pores; supercapacitors can be fully charged/discharged within few seconds if the ionic transport is fast enough. Obviously, high ionic conductivity and optimized ion kinetics in electrodes are desirable for the better electrochemical energy storage.

https://www.chemeurope.com/en/news/1163375/ionic-channels-in-carbon-electrodes-for-efficient-electrochemical-energy-storage.html


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MIT engineers grow “perfect” atom-thin materials on industrial silicon wafers

 

 January 18, 2023

 

Their technique could allow chip manufacturers to produce next-generation transistors based on materials other than silicon.

 

True to Moore’s Law, the number of transistors on a microchip has doubled every year since the 1960s. But this trajectory is predicted to soon plateau because silicon — the backbone of modern transistors — loses its electrical properties once devices made from this material dip below a certain size.

 

Enter 2D materials — delicate, two-dimensional sheets of perfect crystals that are as thin as a single atom. At the scale of nanometers, 2D materials can conduct electrons far more efficiently than silicon. The search for next-generation transistor materials therefore has focused on 2D materials as potential successors to silicon.

 

But before the electronics industry can transition to 2D materials, scientists have to first find a way to engineer the materials on industry-standard silicon wafers while preserving their perfect crystalline form. And MIT engineers may now have a solution.

 

https://news.mit.edu/2023/2d-atom-thin-industrial-silicon-wafers-0118

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A New Layer of Innovation: Next-Gen Nanostructures Unlock Ultra-Low Power Electronics

 

April 22, 2023

 

Tokyo Metropolitan University scientists engineered multi-layered in-plane TMDC junctions with potential use in ultra-low power consumption TFETs, a scalable breakthrough for energy-efficient electronic devices.

 

Scientists from Tokyo Metropolitan University have successfully engineered multi-layered nanostructures of transition metal dichalcogenides that meet in-plane to form junctions. They grew out layers of multi-layered structures of molybdenum disulfide from the edge of niobium-doped molybdenum disulfide shards, creating a thick, bonded, planar heterostructure. They demonstrated that these may be used to make new tunnel field-effect transistors (TFET), components in integrated circuits with ultra-low power consumption.

https://scitechdaily.com/a-new-layer-of-innovation-next-gen-nanostructures-unlock-ultra-low-power-electronics/

 

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Chapter 22: Nature & energy

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Pictures: Nature Yields New Ideas for Energy and Efficiency

 

2012

 

http://news.nationalgeographic.com/news/energy/2012/04/pictures/120419-biomimicry-for-energy/

 
____________________________________

Pictures: Immense, Elusive Energy in the Forces of Nature

 

2012 

 

Lightning
Volcanoes
Earthquakes
Hurricanes
Tsunami
Ocean waves
Wildfire

 http://news.nationalgeographic.com/news/energy/2012/03/pictures/120308-energy-in-forces-of-nature/

 

____________________________________

  

Oyster – World's Largest Hydro-Electric Wave Energy Device Goes Online

 

December 9, 2009

 http://www.greenoptimistic.com/oyster-worlds-largest-hydro-electric-wave-energy-device-goes-online-20091209/#.VSIcBuG-2zk

 

____________________________________

 

Scotland to deploy largest hydro-electric wave energy farm to date (w/ video)

 

May 23, 2013 

 

 http://phys.org/news/2013-05-scotland-deploy-largest-hydro-electric-energy.html

 

____________________________________ 

First osmosis power plant goes on stream in Norway

 

November 2009

 http://www.newscientist.com/article/dn18204-first-osmosis-power-plant-goes-on-stream-in-norway.html#.VSIRJuG-2zk

 

____________________________________ 

Statkraft osmotic power prototype in Hurum

http://en.wikipedia.org/wiki/Statkraft_osmotic_power_prototype_in_Hurum

 
____________________________________

Osmotic power

http://en.wikipedia.org/wiki/Osmotic_power

____________________________________

Tidal power

 

(Environmental concerns)

http://en.wikipedia.org/wiki/Tidal_power

____________________________________

Are tidal power plants slowing down Earth's rotation?

 http://physics.stackexchange.com/questions/6400/are-tidal-power-plants-slowing-down-earths-rotation

____________________________________


Many are concerned that mass-produced tidal energy harvesting technology could be a concern for the environment. We must take into consideration how the currents of the ocean water and wind  could be redirected by this technology.

____________________________________

 

Tiny Swimming Robots Inspired by Water Striders: A Breakthrough in Robotics

01/30/2025

Scientists Create Innovative Robots Controlled by Light

In a remarkable advancement in robotics, a team of researchers at the University of Waterloo has designed tiny swimming robots that mimic the movement of water striders—an insect known for its ability to glide gracefully on the surface of water. These robots, controlled by light, hold exciting potential for applications in both environmental cleanup and biomedical procedures. Their findings have been published in the prestigious journal, Advanced Functional Materials.

https://ainewsera.com/inspired-by-nature-tiny-water/artificial-intelligence-news/ai-and-robotics/

____________________________________

 

SNU-Harvard researchers jointly build next-gen swarm robots using simple linked particles

9-May-2025

https://www.eurekalert.org/news-releases/1083258

____________________________________

Scientists uncover how microswimmers move faster in groups, paving way for tiny drug-delivering robots

March 28, 2025

https://phys.org/news/2025-03-scientists-uncover-microswimmers-faster-groups.html

____________________________________

Magnetic microalgae on a mission to become robots microbiologystudy

March 18, 2025

https://microbiologystudy.com/magnetic-microalgae-on-a-mission-to-become-robots-microbiologystudy/

____________________________________
 

 

 

 

 

____________________________________
____________________________________



Chapter 23: Wind energy


____________________________________
____________________________________

 

 

 



____________________________________





Some people question if it would be sustainable or a possible hazard  to harness energy from ions near the surface of the ocean. This includes different wind currents and ocean currents around the globe for a source of energy. 

 

____________________________________

 

Ocean waves may hold secret to efficient renewable energy

 

September 8, 2015

 

 UC's Thomas Beck explains that every time a wave breaks, droplets of water containing ions go up in the air, but how those ions arrange near the surface of the droplets can affect the chemistry of what happens in the atmosphere around them.

 As the demand for renewable wind and solar energy steadily increases, the need to reduce the cost and extend the life of renewable energy storage batteries becomes even greater.

 By getting back to the basics, a University of Cincinnati quantum chemistry researcher looks at how water and other molecules align and influence ionic distribution on the surface where air and the liquid meet. These findings have received respect from top physicists around the globe and show promise for enhancing the efficiency of renewable energy devices.


http://phys.org/news/2015-09-ocean-secret-efficient-renewable-energy.html#jCp

 

____________________________________

 

Oceanic Temperature Difference to Power 120 Hawaiian Homes in 2015

 

August 31, 2015

 A small power plant that can convert the temperature difference between deep ocean and surface ocean waters into electricity was unveiled in Hawaii last week, the first of its kind to be connected to the grid.


 http://www.greenoptimistic.com/oceanic-temperature-difference-power-hawaii/#.Ve-2o5e-2zk

 

____________________________________

Evaporation as New Source of Renewable Energy

 

June 29, 2015

 Evaporation is now becoming a source of renewable energy with the help of bacteria and the two new devices, Evaporation engine, and Moisture mill, invented by the Columbia University scientists.
While solar, wind, hydro, geothermal, tidal, bio-energies are widely known, there are also other sources which are, now, less reliable as both research and technology in those fields are still in their initial stages. Evaporation is one such source and scientists are saying that it could become the world’s largest renewable energy source.
Though it is theoretically a known fact that during every energy transformation, it is possible to capture and store energy, in practical, with our today’s technology, we succeeded with only a few sources. Now, evaporation has also lost the game.

 http://www.greenoptimistic.com/evaporation-bacteria-energy/#.Ve-vFJe-2zk



____________________________________

 

Giant kites to tap power of the high wind

 

Aug, 2008

 

Experiments show that the power generated could provide electricity for 100,000 homes

http://www.theguardian.com/environment/2008/aug/03/renewableenergy.energy

 

____________________________________

Airborne wind turbine

 

http://en.wikipedia.org/wiki/Airborne_wind_turbine

 

____________________________________

Directory:High Altitude Wind Power

 

Airborne Wind Solutions

http://peswiki.com/index.php/Directory:High_Altitude_Wind_Power



____________________________________

Engineers study the benefits of adding a second, smaller rotor to wind turbines

 

Mar 10, 2015 

 

http://phys.org/news/2015-03-benefits-adding-smaller-rotor-turbines.html#ajTabs

 

____________________________________

 

Invelox wind turbine claims 600% advantage in energy output

May 10, 2013

SheerWind, a wind power company from Minnesota, USA, has announced the results of tests it has carried out with its new Invelox wind power generation technology. The company says that during tests its turbine could generate six times more energy than the amount produced by traditional turbines mounted on towers. Besides, the costs of producing wind energy with Invelox are lower, delivering electricity with prices that can compete with natural gas and hydropower.

Invelox takes a novel approach to wind power generation as it doesn’t rely on high wind speeds. Instead, it captures wind at any speed, even a breeze, from a portal located above ground. The wind captured is then funneled through a duct where it will pick up speed. The resulting kinetic energy will drive the generator on the ground level. By bringing the airflow from the top of the tower, it’s possible to generate more power with smaller turbine blades, SheerWind says.

As to the sixfold output claim, as with many new technologies promising a performance breakthrough, it needs to be viewed with caution. SheerWind makes the claim based on its own comparative tests, the precise methodology of which is not entirely clear.


http://www.gizmag.com/invelox-wind-generator/27377/?li_source=LI&li_medium=default-widget




____________________________________

Solar Wind Energy's Downdraft Tower generates its own wind all year round

 

June 18, 2014

 When we think of wind power, we generally think of huge wind turbines sitting high atop towers where they can take advantage of the higher wind speeds. But Maryland-based Solar Wind Energy, Inc. is looking to turn wind power on its head with the Solar Wind Downdraft Tower, which places turbines at the base of a tower and generates its own wind to turn them.

 http://www.gizmag.com/solar-wind-energy-downdraft-tower/32607/?li_source=LI&li_medium=default-widget

 

____________________________________

Atmospheric Vortex Engine creates tornadoes to generate electricity

  

December 20, 2012

 Tornadoes generally evoke the destructive force of nature at its most awesome. However, what if all that power could be harnessed to produce cheaper and more efficient electricity? This is just what Canadian engineer Louis Michaud proposes to achieve, with an invention dubbed the “Atmospheric Vortex Engine” (or AVE).

AVE works by introducing warm air into a circular station, whereupon the difference in temperature between this heated air and the atmosphere above creates a vortex – or controlled tornado, which in turn drives multiple wind turbines in order to create electricity. The vortex could be shut down by simply turning off the source of warm air.

http://www.gizmag.com/vortex-engine-tornadoes-electricity/25508/?li_source=LI&li_medium=default-widget

 

____________________________________

  

Smart wind turbines can predict the wind 

 

Date:

January 5, 2010

Researchers in Denmark have recently completed the world's first successful test on a wind turbine with a laser-based anemometer built into the spinner in order to increase electricity generation. The results show that this system can predict wind direction, gusts of wind and turbulence.

http://www.sciencedaily.com/releases/2010/01/100104092454.htm


____________________________________

DualWingGenerator mimics flapping wings to harvest energy

April 2, 2014

Back in 2011, Festo created a natural-flight mimicking bionic seagull with flapping wings dubbed SmartBird. The company is now looking to apply similar principles in order to convert wind power into electricity with its DualWingGenerator system.

http://www.gizmag.com/festo-dualwinggenerator-turbine-energy-wind/31478/?li_source=LI&li_medium=default-widget

 

____________________________________

Probing the limits of wind power generation

 

September 2, 2015

 Wind turbines remove kinetic energy from the atmospheric flow, which reduces wind speeds and limits generation rates of large wind farms. These interactions can be approximated using a vertical kinetic energy (VKE) flux method, which predicts that the maximum power generation potential is 26% of the instantaneous downward transport of kinetic energy using the preturbine climatology. We compare the energy flux method to the Weather Research and Forecasting (WRF) regional atmospheric model equipped with a wind turbine parameterization over a 105 km2 region in the central United States. The WRF simulations yield a maximum generation of 1.1 We⋅m−2, whereas the VKE method predicts the time series while underestimating the maximum generation rate by about 50%. Because VKE derives the generation limit from the preturbine climatology, potential changes in the vertical kinetic energy flux from the free atmosphere are not considered. Such changes are important at night when WRF estimates are about twice the VKE value because wind turbines interact with the decoupled nocturnal low-level jet in this region. Daytime estimates agree better to 20% because the wind turbines induce comparatively small changes to the downward kinetic energy flux. This combination of downward transport limits and wind speed reductions explains why large-scale wind power generation in windy regions is limited to about 1 We⋅m−2, with VKE capturing this combination in a comparatively simple way.

Read more at: http://phys.org/news/2015-09-probing-limits-power.html#jCp

____________________________________

Will Newer Wind Turbines Mean Fewer Bird Deaths?

 

April 28, 2014

http://news.nationalgeographic.com/news/energy/2014/04/140427-altamont-pass-will-newer-wind-turbines-mean-fewer-bird-deaths/

 
____________________________________

 Recognizing health concerns in wind energy development a key recommendation in new study

January 26, 2016

As wind energy development blossoms in Canada and around the world, opposition at the community level is challenging the viability of the industry. A new study with research from the University of Waterloo, published in Nature Energy, identifies four major factors leading to disputes over wind farms, and offers recommendations on avoiding disagreements.

Read more at: http://phys.org/news/2016-01-health-energy-key.html#jCp

 As wind energy development blossoms in Canada and around the world, opposition at the community level is challenging the viability of the industry. A new study with research from the University of Waterloo, published in Nature Energy, identifies four major factors leading to disputes over wind farms, and offers recommendations on avoiding disagreements.

 

http://phys.org/news/2016-01-health-energy-key.html

____________________________________ 

EWICON bladeless wind turbine generates electricity using charged water droplets

 

April 3, 2013

Wind energy may be one of the more sustainable sources of power available, but the spinning blades of conventional wind turbines require regular maintenance and have attracted criticism from bird lovers. That might explain why we've seen wind turbine prototypes that enclose the blades in a chamber or replace them entirely with a disc-like system. But researchers in the Netherlands set out to eliminate the need for a mechanical component entirely and created the EWICON, a bladeless wind turbine with no moving parts that produces electricity using charged water droplets.

 http://www.gizmag.com/ewicon-bladeless-wind-turbine/26907/?li_source=LI&li_medium=default-widget
 

____________________________________

This giant straw is actually a vertical bladeless wind turbine

 

May 6, 2015

The Vortex wind generator represents a fairly radical break with conventional wind turbine design, in that it has no spinning blades (or any moving parts to wear out at all), and looks like nothing more than a giant straw that oscillates in the wind. It works not by spinning in the wind, but by taking advantage of a phenomenon called vorticity, or the Kármán vortex street, which is a "repeating pattern of swirling vortices."

http://www.treehugger.com/wind-technology/vortex-vertical-bladeless-wind-turbine.html

____________________________________

 

Scientists develop pneumatic propellers that could replace diesel engines in ferry boats

April 21, 2025

Scientists say they have created a methodology that could replace two diesel engines powering a ferry boat with pneumatic propellers.

https://techxplore.com/news/2025-04-scientists-pneumatic-propellers-diesel-ferry.html

____________________________________

 

Fred Rash's electric circle plane

Sep 19, 2022

https://www.youtube.com/watch?v=r3BNV9p36uE

 

____________________________________ 


Designing A Self Propelling Ionic Thrust Wing

Oct 28, 2023 

 

https://www.youtube.com/watch?v=5lDSSgHG4q0

 

____________________________________


Super Capacitor Plane

Dec 21, 2023

https://www.youtube.com/watch?v=zEahoJZgfys


____________________________________


A Plane Without Wings: The Story of The C.450 Coléoptère

Dec 21, 2020

https://www.youtube.com/watch?v=unz6mfjS4ws

____________________________________


JET ENGINE with NO MOVING PARTS

Sep 30, 2023

https://www.youtube.com/watch?v=I7hsUvZmZ2k

____________________________________


RC Solar Plane Flight Duration Test

Aug 22, 2020

https://www.youtube.com/watch?v=1OGrDvInUAY

 
____________________________________

 

DARPA Launches Falcon HTV-2 Glider, the World's Fastest Plane

August 11, 2011

At 7:45 a.m. PDT, an unmanned glider was launched from Vandenberg Air Force Base in California aboard a Minotaur 4 rocket. Overseen by DARPA, the Defense Advanced Research Projects Agency, the glider, named HTV-4, is expected to reach suborbital space before reentering Earth's atmosphere at Mach 20 with the help of rocket thrusters to stay on course. If the hypersonic glider is able to reach Mach 20, or about 13,000 mph, it will become the fastest plane ever. At that speed, the HTV-2 could travel from New York City to Los Angeles in about 12 minutes...

https://www.theatlantic.com/technology/archive/2011/08/darpa-launches-falcon-htv-2-glider-the-worlds-fastest-plane/243467/

 

____________________________________


Someone actually made a REAL Flying car!

Nov 17, 2023

https://www.youtube.com/watch?v=P75s6M7kCrA

____________________________________


Optimal elastic wing for flapping-wing robots through passive morphing

Nov 7, 2022

 

https://www.youtube.com/watch?v=kwuW8cfy-MI

____________________________________


How Bionic Wings Are Reinventing Drones

Nov 3, 2023

 

https://www.youtube.com/watch?v=vr0z2huKaCI


____________________________________


Building a rocket bird (ornithopter)

Nov 11, 2023

 

https://www.youtube.com/watch?v=angnUj0-yhQ

____________________________________


Ornithopter with morphing-coupled wingbeat pattern

Aug 6, 2022

https://www.youtube.com/watch?v=TXg-qoRN0co

____________________________________


Are Drones That Flap Their Wings Better?

Feb 2, 2024

https://www.youtube.com/watch?v=sCpTIY6gJVE

______________


How insects evolved to ultrafast flight

October 4, 2023

https://phys.org/news/2023-10-insects-evolved-ultrafast-flight.html

____________________________________

 

Forbidden Technologies and The Silencing of Their Inventors

Mar 1, 2024

https://www.youtube.com/watch?v=lpFgvGeEQlA

______________


The Real Life Dune Ornithopter... it was French!

Mar 15, 2024

 

 

https://www.youtube.com/watch?v=kz5GcOEcjyk

____________________________________

 

A review on piezoelectric energy harvesting

23 June 2022

https://link.springer.com/article/10.1007/s00542-022-05334-4

____________________________________


Nature-inspired interfacial engineering for energy harvesting

18 March 2024

https://www.nature.com/articles/s44287-024-00029-6
 

____________________________________

 

Energy harvesting

https://en.wikipedia.org/wiki/Energy_harvesting

 

____________________________________


Is This Accidental Discovery The Future Of Energy?

Oct 10, 2023

Imagine getting the energy needed to power our phones, light up our homes, or drive our cars, from thin air. And no, we’re not talking about Nikola Tesla’s dream of wireless power a century ago, but a new and accidental discovery along those lines from the University of Massachusetts Amherst. Researchers have found a way to turn humidity into electricity. It’s called hygroelectrical power, and believe it or not, a company named CascataChuva is already trying to commercialize a variant of the technology. So, what is it and how does it work?

https://www.youtube.com/watch?v=ZyY1PLTlmT0

 
____________________________________

 

Gravity Energy Storage. Who's right and who's wrong?

Jul 10, 2022

 

https://www.youtube.com/watch?v=lz6ZB23tfg0
 

____________________________________


This Is Not a Crane, It's an Insane New Gravity Battery

Nov 26, 2021

 

https://www.youtube.com/watch?v=WCawtiU4o1o

 
____________________________________

 

Mechanical circuits: electronics without electricity

Oct 27, 2022

 

 

https://www.youtube.com/watch?v=QrkiJZKJfpY

 

____________________________________


What If Swings Had Springs Instead Of Ropes: Autoparametric Resonance

Feb 18, 2022

 

 

https://www.youtube.com/watch?v=MUJmKl7QfDU

____________________________________


The Mystery of Spinors

Mar 20, 2024

 

https://www.youtube.com/watch?v=b7OIbMCIfs4

____________________________________


Major Evidence of a New Particle Called Glueball: Here's Why It Matters

May 14, 2024

https://www.youtube.com/watch?v=sVS2sVBQYO8

____________________________________


How Levers, Pulleys and Gears Work

Jul 26, 2022

https://www.youtube.com/watch?v=JnYVz1TSmBQ

____________________________________


Why Snatch Blocks are AWESOME (How Pulleys Work) - Smarter Every Day 228

Dec 5, 2019

https://www.youtube.com/watch?v=M2w3NZzPwOM

____________________________________


Leonardo da Vinci inventions tested

Dec 23, 2019

https://www.youtube.com/watch?v=IxOagUqdibw

 
____________________________________

 

Leonardo Davinci Design

https://www.pinterest.com/pin/560205641128538001/

 

____________________________________


The Mechanical Battery Explained - A Flywheel Comeback?

Jan 5, 2021

https://www.youtube.com/watch?v=8X2U7bDNcPM

____________________________________


Flywheel Battery

Jul 21, 2021

 

 

https://www.youtube.com/watch?v=yhu3s1ut3wM

____________________________________


 7 Types of Wheels - 4 Hard Trials - Experiments with Lego Technic #lego #experiment #vehicles

Apr 13, 2024

https://www.youtube.com/watch?v=jaadwO6QzUA

____________________________________


Gear Types, Design Basics, Applications and More - Basics of Gears

Aug 17, 2022

https://www.youtube.com/watch?v=ZhDO16FDmxA


____________________________________


We should use this amazing mechanism that's inside a grasshopper leg

Apr 30, 2024

 

 

https://www.youtube.com/watch?v=xUUW6SYl_ak

 
____________________________________

 

This bug produces a g-force of 500 g!

July 7, 2024

https://www.youtube.com/shorts/XvSZYDsM_T4

 

____________________________________



What makes planetary gearboxes so amazing?

Jan 5, 2022

 

https://www.youtube.com/watch?v=TzJkD87eQNI

____________________________________


I Built Real ODM Gear! - Attack On Titan

Aug 19, 2023

https://www.youtube.com/watch?v=8ouS7G6k04A

____________________________________


The Most Incredible Attempts at Perpetual Motion Machines

Sep 11, 2022

https://www.youtube.com/watch?v=JPw58clq9EQ


____________________________________


Adam Savage vs The "Perpetual Motion" Machine!

Jan 3, 2023

https://www.youtube.com/watch?v=QdEdYfxMx-0

____________________________________


Turn a ceiling fan into a wind turbine generator?!

Dec 7, 2018

https://www.youtube.com/watch?v=ApKFeaJ6xYE


____________________________________


NEW French Jetpack SHOCKED Chinese and US Engineers

May 25, 2023

https://www.youtube.com/watch?v=LnD6AUikRkQ

 
____________________________________

 

Real Hoverboard Using Ground Effect! - Floats On Anything!!

Oct 28, 2023

https://www.youtube.com/watch?v=5UXL6oPP8sA
 

____________________________________

 

VBSS with JPEM & Stiletto

Apr 7, 2023

https://www.youtube.com/watch?v=DkZPI5m9SIE

____________________________________


This Car Travels Farther Than You Push It

Mar 15, 2024

https://www.youtube.com/watch?v=eoVUdwOgjiA

____________________________________


20 INVENTIONS RESHAPING REALITY

Apr 23, 2024

https://www.youtube.com/watch?v=SKoKse7qiI4

____________________________________


Transforming Sailing and Power Generation with The Ocean Kite Engine

Mar 8, 2024

 

https://www.youtube.com/watch?v=aolYqwVBScs

____________________________________


Incredible Inventions That Generate Free Energy

Jan 25, 2024

https://www.youtube.com/watch?v=v8WfAeuHOcE

 
____________________________________

 

 Kite Risers on a Paraglider

These Kite risers are a different way to change the angle of attack of your glider, just as you do with trimmers or speedbar, but the difference is that you adjust it instantly with your arms and without being able to pull the brakes-only when the angle of attack is low.

https://www.littlecloud.fr/en/kiterisers-en/

 
____________________________________

Kite Risers on a Paraglider - Vertical Takeoff

2023

 

 

https://www.youtube.com/shorts/GobgmTKC6RM

 

____________________________________


THIS WING IS INSANE - Flare Moustache First Impressions

Jun 8, 2022

https://www.youtube.com/watch?v=Wf_msigfgsQ

 
____________________________________

Flap your wings #flare #moustache #parakite

2023

https://www.youtube.com/shorts/vRPj6wd32sY

____________________________________



Flirting with the stall point

2023

Our beloved places to play: Soaring, Speedflying and -riding, Snowkiting and Proximityflying.

 

• Be aware: The MOUSTACHE is NOT built for thermal flying, nor being used in strong turbulences since a reflex profile is powerful and behaves completely different in collapses!
• With great power comes great responsibility. So make sure to watch all the FLARE Nation Academy tutorials!

https://www.youtube.com/shorts/m1nb1Gk2jEA

 

____________________________________


Top landing on a handrail

2023

https://www.youtube.com/shorts/PwzMwrPoqCM

____________________________________


Flare MOUSTACHE. Full Power

2023

https://www.youtube.com/shorts/ut90XVDln3c

____________________________________


6 minutes with the REVOLUTIONARY FLARE MUSTACHE.

Oct 8, 2022

https://www.youtube.com/watch?v=6uqiJpBA_eY

____________________________________


WE FINALLY MOTORED THE MOUSTACHE... and Its INSANE.

Oct 25, 2022

https://www.youtube.com/watch?v=5L-N7VBei-o

____________________________________


FLARE Moustache - The sand stair

April 2024

https://www.youtube.com/watch?v=NDalT6u5SsE

____________________________________


Faster than a car? 🚗 - FLARE Moustache at Kronplatz

Feb 27, 2022

https://www.youtube.com/watch?v=MN-iUp_lOKE

______________

 

Kite Riser Types (Review)

https://www.youtube.com/watch?v=Nw--2G1hjFw

 

____________________________________



Launching A Paramotor With A Bike!!!

Aug 3, 2023

https://www.youtube.com/watch?v=yLi1VKE3Btc

____________________________________


Paragliding Accuracy World Cup

https://pgawc.org/

____________________________________


When Your Carabiner Fails...

Aug 24, 2023

https://www.youtube.com/watch?v=E9eqsiKPpFg

____________________________________


Flying with 50 drone motors (homemade flying machine)

Nov 2, 2021

 

 
https://www.youtube.com/watch?v=pXcVTsuXxOA

 

____________________________________

 

Flying with four giant drone motors (ducted propeller paramotor)

 

2022

https://www.youtube.com/watch?v=NkJ9LF_8hIQ 

____________________________________

 

Paraglider Thrusters

 
2012

https://www.youtube.com/watch?v=zFHzWofHrwo

 

____________________________________


The Unexpected Genius of Bionic Propellers

Dec 7, 2023

https://www.youtube.com/watch?v=WezeLNC32sA

____________________________________


Uncovering The Genius of Fibonnaci Turbines

Jan 31, 2024

https://www.youtube.com/watch?v=i4TEMZ5dyPo

____________________________________


The Genius of Cycloidal Propellers: Future of Flight?

Mar 20, 2024

https://www.youtube.com/watch?v=Lqy_7lr6wuE

____________________________________


Why This 17-Year Old's Electric Motor Is Important

Jan 17, 2023

https://www.youtube.com/watch?v=35JuW3bcp04

____________________________________


How can gliders fly without propulsion | The most complete explanation

Aug 22, 2019

https://www.youtube.com/watch?v=b4YrpmhgNGs

 
____________________________________

 

Egyptian Hieroglyphics Reveal Ancient Flying Machine? Ancient Discoveries (S1, E2) | Full Episode
 
Apr 11, 2023
 
https://www.youtube.com/watch?v=lPR9o2YRxc8

 

____________________________________ 

 

Impossible Stone Found Atop Cholas Temple?

 

Jun 2, 2023

 

 

 

 

 

https://www.youtube.com/watch?v=IhEG8kLCiQ0

 

 

____________________________________

 

 

Many scientists believe that floating cranes could be used in future technology and on other planets.

 

____________________________________ 

 

 

Floating cranes: SkyLifter’s plans for the construction industry

1 March 2024

 

 

 

Airships and balloons were around long before anyone saw a plane flying.

The French Army flew an airship named La France in 1884, and the first hot air balloon flew in 1783. But a series of high profile crashes like the Hindenburg and R101, and the considerably faster evolution of aircraft saw airships fall out of favour (except for a subsection of the marketing industry).

Hot air balloons aren’t known for their ease of navigation or speed, and airships, whilst easier to control and faster, are still too slow to have a meaningful impact on the markets they have been targeting up to now.

All that being said, UK-based startup SkyLifter thinks it has a found a new use case. Deciding there was no aerospace use case that could be improved versus what is currently available today for passengers, cargo and earth observation, the firm identified a niche in the construction industry it thinks can only be exploited by the capabilities of airship technology.

The startup is building a “commercial hook-in-the-sky system” made up of a gas-filled omni-directional lenticular-shaped aerostat (aka lighter-than-air aircraft) with an underslung pod housing the propulsion system, winch and hook. The pod, which also serves to aid the craft’s stability by increasing the vertical distance between the centre of buoyancy and the centre of gravity, houses the main aircraft systems for power, control and communication.

SkyLifter’s omni-directional propellers enable thrust in all directions and allow it to achieve an airspeed of about 45 knots (51mph). There is also the option to float “endlessly” without power, according to founder and CEO Jeremy Fitton, “at least in theory”.

https://www.revolution.aero/deep_dive/floating-cranes-skylifters-plans-for-the-construction-industry/

 

____________________________________

 

 

The Skycrane: How NASA's Perseverance rover will land on Mars

February 18, 2021

 

 

 

The "Skycrane" maneuver that will soon place Perseverance on Mars' surface was once considered a crazy idea - even within NASA.

https://www.astronomy.com/space-exploration/the-skycrane-how-nasas-perseverance-rover-will-land-on-mars/

 

 

____________________________________ 

 

 

The Surprising Truth Behind the Construction of the Great Pyramids

Were the stone blocks carved from natural limestone or cast with an early version of concrete? A materials science research team provides evidence to answer this age-old mystery.

May 18, 2007

https://new.nsf.gov/news/surprising-truth-behind-construction-great

 

____________________________________

What Materials Were Used To Build The Pyramids Of Giza?

2018

Limestone

Limestone was one of the materials used to build the Pyramids of Giza. It formed the bulk of the materials used in the construction of the pyramids and rough limestone was utilized in the core of the pyramid. White limestone, which is finer, was used to coat the interior walls and as the main material for the outer casing. The low-grade limestone that was used in the core of the pyramids is found huge quantities in Egypt, and it was found near the building sites during the pyramid construction era. Workers extracted the stone in blocks by marking out crevices with just enough room for them to be cut into blocks and transported to the sites. Tools used in this case included chisels, pickaxes, and hammers made from granite.

The fine white limestone for the interior décor and the mortuary temples was slightly hard to extract and had to be sourced further away from the building sites. This type of limestone was found deeper beneath the soil surface in regions including the West bank of the Nile in the hills of Muqattam in the present day regions of Maasara and Tura. The workmen would excavate the soil and dig tunnels to reach the deposits which would be as deep as 160 feet below the surface. Huge pieces of stone were then dug up to be divided into blocks which were then transported on wooden sledges towed by oxen on a path paved with mud from the Nile to make movement easier to the construction site.

Pink Granite

The granite was used in conjunction with limestone to cover the interior walls of the pyramids though much more sparingly since it was distributed in several parts of South of Egypt and was not as close as the limestone quarries were to the building sites. Pink granite is thought to have been mined in Aswan which had some quarries.
Basalt

Basalt is also known as alabaster and it was often used to cover the floor of the pyramid. It was extracted from open pits or underground deposits, particularly from an Oligocene flow where there was once a lake that connected to the Nile. During this time the basalt was transported on the lake and into the Nile to its shores where it was moved to the construction site of the pyramids.

Mud Bricks

Mud bricks were perhaps the most common building material in all of Egypt. In the pyramids it was used to build the walls, these were fired in an oven as a measure to make them last longer.

Significance

Like the Eiffel Tower of France and the Colosseum in Rome, the Pyramids of Giza are a defining landmark in Egypt and an important part of the culture of the people of Egypt. The impressive architecture that began years ago is proof of the heights of human achievement of the past.

https://www.worldatlas.com/articles/what-materials-were-used-to-build-the-pyramids-of-giza.html

 

____________________________________

 

 

Image Gallery: Walking Easter Island Statues

 

 June 7, 2013

 

https://www.livescience.com/37260-image-gallery-mysterious-easter-island-statues.html 

 

____________________________________

 

Easter Island's 'Walking' Stone Heads Stir Debate

 

 June 7, 2013

 

https://www.livescience.com/37277-easter-island-statues-walked-there.html 

 

____________________________________ 

 

 

Scientists Make Easter Island Statue Walk | National Geographic

 

Jun 21, 2012

 

https://www.youtube.com/watch?v=YpNuh-J5IgE  

 

 

____________________________________ 

 

 

Walking with Giants: How the Easter Island Moai Moved | Nat Geo Live

  

Aug 13, 2012

 

https://www.youtube.com/watch?v=J5YR0uqPAI8 

 

 

____________________________________

 

King Solomon's Temple Investigation Marathon - Legend (Author: Michael Ross)

 

 7/21/2019

 

https://solomonstempleinvestigation.blogspot.com

 

____________________________________

 

Impossible Ancient Stone Work In Peru That Proves They Melted, Shaped and Fitted Huge Blocks Perfect - Solomon's Temple Investigation Marathon 184

https://archive.org/details/solomonstemple184

____________________________________

Molten Granite outside the Second Pyramid! - Solomon's Temple Investigation Marathon 185

https://archive.org/details/solomonstemple185

____________________________________

1970s SECRET-CHAMBER SEARCH TECHNIQUE IN KHAFRE PYRAMID! - Solomon's Temple investigation Marathon 186

https://archive.org/details/solomonstemple186

____________________________________

Did Ancient People Use Acid to Shape Stone? - Solomon's Temple Investigation Marathon 187

https://archive.org/details/solomonstemple187

____________________________________

The Story of the Enigmatic and Mysterious Tube Drills of Ancient Egypt - Solomon's Temple Investigation Marathon 188

https://archive.org/details/solomonstemple188

____________________________________

Mysterious Tube Drills of Ancient Egypt - Solomon's Temple Investigation Marathon 189

https://archive.org/details/solomonstemple189

____________________________________

Advanced Ancient Machining That Is Absurdly Difficult To Replicate Even With Today's Technology - Solomon's Temple Investigation Marathon 190

https://archive.org/details/solomonstemple190

 
____________________________________

 

 
Ancient Tube Drills & Cores (Even Some Examples from Peru) - Solomon's Temple Investigation Marathon 202

https://archive.org/details/solomonstemple202

____________________________________

Megalithic Softening of Stone? - Solomon's Temple Investigation Marathon 203

https://archive.org/details/solomonstemple203

____________________________________

Ancient Engineering at the Temple of Bastet - Solomon's Temple Investigation Marathon 204

https://archive.org/details/solomonstemple204

 
____________________________________

 

 
Advanced Ancient Stone Cutting - Solomon's Temple Investigation Marathon 205

https://archive.org/details/solomonstemple205

_________________________________________

Melted Stonework in Peru, Sulfur Balls, Metallurgy, Alchemy & Meteorites - Solomon's Temple Investigation Marathon 206

https://archive.org/details/solomonstemple206

 
____________________________________

 
They cut rocks like butter. Inca 'Quarry' is mindblowing! - Solomon's Temple Investigation Marathon 209

https://archive.org/details/solomonstemple209

____________________________________

The Magnetic River - The Strongest Magnet - Magnets & Copper Tubes - Solomon's Temple Investigation Marathon 210

https://archive.org/details/solomonstemple210

____________________________________

Ancient High Tech/ Melt Stone With Light And Sound - Solomon's Temple Investigation Marathon 211

https://archive.org/details/solomonstemple211

 
____________________________________

 

 
Melting Rocks Into Molten Lava & Turning Dirt Into Iron - Solomon's Temple Investigation Marathon 212

https://archive.org/details/solomonstemple212

____________________________________

The Coral Castle Mystery Solved, Melting Stone, Magnets, Electricity, Dissolving Rocks, Liquid Mercury & The Pyramids - Solomon's Temple Investigation 213

https://archive.org/details/solomonstemple213_201911

____________________________________

The Coral Castle Mystery Solved Continued, Melted Limestone, Cutting Stone, Melting Granite & Glass - Solomon's Temple Investigation Marathon 214

https://archive.org/details/solomonstemple214

____________________________________

Blaze of Steel: Explosive Chemistry - Sulfur, Iron Oxide, Nitrates, Cyanide, Hydroxide & the Oxidation State - Solomon's Temple Investigation Marathon 215

https://archive.org/details/solomonstemple215

 
____________________________________

 

 
Blaze of Steel: Explosive Chemistry Continued: Alchemical Arts, Medicine, Life & Death (Transmutating agents for Stones, Noble Metals and Gold) - Solomon's Temple Investigation 216

https://archive.org/details/solomonstemple216

____________________________________

Evidence of Advanced Ancient Machining Technology from Around the World - Solomon's Temple 118

https://archive.org/details/solomonstemple118

____________________________________

The First Pyramid? - Solomon's Temple Investigation Marathon 119

https://archive.org/details/solomonstemple119

____________________________________

 
Electricity, Stone & the Pyramids - Solomon's Temple Investigation 120

https://archive.org/details/solomonstemple120

____________________________________

Pyramids & Electricity? - Solomon's Temple Investigation 121

https://archive.org/details/solomonstemple121

____________________________________

Manna, Gold, Alchemy & The Pyramids? - Solomon's Temple 122

https://archive.org/details/solomonstemple122

____________________________________

Ancient Egyptian Pyramid Technolgy, Ramps & Tunnels - Solomon's Temple Investigation 123

https://archive.org/details/solomonstemple123

 
____________________________________

 

 

Scientists may have solved mystery behind Egypt's pyramids

16 May 2024

https://www.bbc.com/news/articles/c99zwkzzrxvo

 

 

____________________________________

 

The First Flying Machines - Failures and Mishaps

Feb 9, 2018

 

 

The Saqqara bird (popularly known as the Saqqara glider) is an object carved from sycamore wood and was found in the tomb of Pa-di-Amun in the ancient Egyptian necropolis of Saqqara in 1891. It resembles a streamlined miniature airplane.

https://www.youtube.com/watch?v=M9Yww9LG3gw

 
____________________________________

 

How to Fall : An Early History of the Parachute

2021

 

 

A sketch by Leonardo da Vinci, circa 1485, from his Codex Atlanticus showing a rough design for a parachute.

 

 

 

Illustration of André-Jacques Garnerin’s frameless parachute design. The design was made of silk, and it made the world’s first frameless parachute descent on 22 October 1797 in Paris.

https://www.onverticality.com/blog/early-history-of-the-parachute

 

____________________________________

Flying Failures | Stock Footage

Sep 24, 2019

https://www.youtube.com/watch?v=Je8wxnoEkug

____________________________________


African Airplane Compilation | African Aviation

May 4, 2018

https://www.youtube.com/watch?v=0h_cqTCT5g0


____________________________________


Bike Powered Airplanes

2022

https://www.youtube.com/shorts/gnNSOho2Eeg

____________________________________

Could You Power Your Home With A Bike?

December 8, 2016

https://www.npr.org/sections/13.7/2016/12/08/504790589/could-you-power-your-home-with-a-bike

____________________________________


How Much Electricity Can a Bike Generate?

https://paylesspower.com/blog/how-much-electricity-can-a-bike-generate/

____________________________________


Let’s Generate Electricity by Walking!

2008

https://ourworld.unu.edu/en/lets_generate_electricity_by_walking

____________________________________


I Built Shoes To Make Me Run Fast! (World Record)

Jul 27, 2022

https://www.youtube.com/watch?v=k2wwIIFxYfc

____________________________________


History of Parachuting: From da Vinci to Ram-air Parachutes

Oct 11, 2022

https://www.youtube.com/watch?v=wLikKdK8uDo

____________________________________


Can You Use Umbrellas Instead of a Parachute?

Sep 3, 2019

https://www.youtube.com/watch?v=zm_7txMrG5U

____________________________________


Amazing Gadgets That Have Reached a Next Level 5

 May 6, 2023

https://www.youtube.com/watch?v=GWlCwnJuqoI

____________________________________


What are the disadvantages of parachute+airbag for atmospheric landing, versus rocket-based?

2013

https://space.stackexchange.com/questions/705/what-are-the-disadvantages-of-parachuteairbag-for-atmospheric-landing-versus-r


____________________________________

 

Parachutes in Space: A Crucial Technology for Space Exploration

Dec 4, 2023

https://agnirva.medium.com/parachutes-in-space-a-crucial-technology-for-space-exploration-8e315f4860d8

____________________________________


How Parachutes Went Square

Jul 15, 2022

https://www.youtube.com/watch?v=QLuNXVfHtPQ

____________________________________


My LOWEST Base Jump Ever!!! - SKETCHY

Nov 8, 2022

https://www.youtube.com/watch?v=6p8IXyDTjgk


____________________________________

 

 

Some people question why Rogallo Reserve steerable parachutes are not as reliable as a standard square Reserve Canopy. Could there be a way to improve steerable reserve parachutes.

____________________________________

 


Why aren't Rogallo wings or parafoils used in aircraft with fuselages?

2016

Ultralights and paragliders: Only categories with Rogallo wings

The advantages provided by flexible wings (easy storage, light weight, low cost) is a significant choice criteria for use in ultralights and paragliders, and of course for parachutes. These advantages overcome their limited aerodynamic performances, which is of lesser consideration for vehicles that are not specially aerodynamically designed.

To summarize: The flexible wings are more appropriate for smaller and slower aircraft, in particular those not requiring wing tanks, wing control surfaces, or wing landing gears. Namely ultralights.

Controls- The wings house the controls, which would not be possible in case of flexible wings (future combat aircraft are expected to have wing morphing, but is still a bit far away). The control of flexible wings are by using cables, which are suitable only for small aircraft. Another issue is redundancy, which would be quite difficult with these exposed cables.

Safety- The flexible wings do not offer the same level of safety as the rigid (elastic) ones. What if they fail to deploy properly or start to retract in flight? NASA carried out research on the usage of flexible wings for the spacecraft landing programs which brought out a number of issues related to structural safety and deployment:

    The wing’s structural problems persisted. Further drop tests saw more sails fall apart ...

    Wing deployment tests were also proving problematic. The sail wasn’t deploying consistently, at times not opening fully and failing to inflate with enough time...

Even though most of these problems were fixed, it would have been difficult to convince regulatory authorities and paying public for their use.

It should be noted that most of the advantages of the flexible wings are precisely because of their limitations- it is collapsible for reduced storage and weigh less because it doesn't carry fuel or have control surfaces and doesn't have mountings for various things (like navigation lights etc).

It should noted that the people involved were quite conscious of the restrictions of this type of wing- For example, Francis M. Rogallo, the inventor of rogallo wing was quite cautious when he noted,

    ... if we could discover how to make flexible wings that could be packaged and deployed somewhat like a parachute, such wings would have many new applications as well as replacing some parachutes and rigid wings.

https://aviation.stackexchange.com/questions/32622/why-arent-rogallo-wings-or-parafoils-used-in-aircraft-with-fuselages

____________________________________


Why NASA Abandoned the Gemini Rogallo Wing

Oct 7, 2020

https://medium.com/the-vintage-space/why-nasa-abandoned-the-gemini-rogallo-wing-84537fc3f825

____________________________________


Rogallo wing

https://en.wikipedia.org/wiki/Rogallo_wing

The Rogallo wing is a flexible type of wing. In 1948, Francis Rogallo, a NASA engineer, and his wife Gertrude Rogallo, invented a self-inflating flexible wing they called the Parawing, also known after them as the "Rogallo Wing" and flexible wing. NASA considered Rogallo's flexible wing as an alternative recovery system for the Mercury and Gemini space capsules, and for possible use in other spacecraft landings, but the idea was dropped from Gemini in 1964 in favor of conventional parachutes.

 
____________________________________

 

NASA Para Wing (NPW9b) Construction

 2011

 

https://www.pointsunknown.com/blog/2011/02/nasa-para-wing-npw9b-construction/ 

____________________________________


How could laser-driven lightsails remain stable?

February 5, 2024

https://phys.org/news/2024-02-laser-driven-lightsails-stable.html


____________________________________


From Paper to Bionics: Origami's Incredible Impact on Science | FD Engineering

Aug 13, 2023

https://www.youtube.com/watch?v=uFyJykl1O0k

____________________________________


STRANDBEEST EVOLUTION 2021

Apr 3, 2022

https://www.youtube.com/watch?v=C97kMKwZ2-g

____________________________________

What Goes Up, Must Come Down

 

09.09.08

 

https://www.nasa.gov/mission_pages/shuttle/behindscenes/parachutes.html

 

____________________________________

 

 

The ABC of Parachute Fabric and Materials

 

https://thrillspire.com/parachute-materials-fabric

 

____________________________________

 

 

When Did Nylon Replace Silk In Parachutes

2022

https://www.answerfoundry.com/when/when-did-nylon-replace-silk-in-parachutes/

____________________________________

 

The Silk Enigma: Britain’s Enigmatic Parachute Production

March 8, 2024

https://blog.imodstyle.com/the-silk-enigma-britains-enigmatic-parachute-production/ 

 

____________________________________

 

Spiders can fly by weaving 10-foot-long silk parachutes to float through the air

 

2018

 

https://www.usatoday.com/story/news/nation-now/2018/06/15/spiders-can-fly-using-long-silk-parachutes-study/704421002/

 

 

____________________________________

 

 

Art, Armor, and Airbags: Spider Silk As A Miracle Material

 

May 12, 2015

https://www.atlasobscura.com/articles/art-armor-and-airbags-spider-silk-as-a-miracle-material

 

____________________________________

 

 

New Artificial Spider Silk: Stronger Than Steel and 98 Percent Water

 

July 26, 2017

 

Researchers at Cambridge University have developed a process for making strong, stretchy threads in an environmentally friendly way

 

https://www.smithsonianmag.com/innovation/new-artificial-spider-silk-stronger-steel-and-98-percent-water-180964176/

 

____________________________________

 

 

Military researchers think spider silk may keep US troops lighter and cooler in combat

 

Aug 8, 2018

 

https://www.businessinsider.com/military-scientists-want-to-use-spider-silk-for-body-armor-parachutes-2018-8?op=1

 

 

____________________________________ 

 

 

High-strength and ultra-tough whole spider silk fibers spun from transgenic silkworms

September 20, 2023

https://www.cell.com/matter/abstract/S2590-2385(23)00421-6

 

____________________________________

 

 

NASA’s New Material Built to Withstand Extreme Conditions

2022

This turbine engine combustor (fuel-air mixer) was 3D-printed at NASA Glenn and is one example of a challenging component that can benefit from applying the new GRX-810 alloys.

https://www.nasa.gov/aeronautics/nasas-new-material-built-to-withstand-extreme-conditions/

____________________________________


Aluminium alloy could boost spacecraft radiation shielding 100-fold

20 October 2022

A new metal alloy keeps its flexibility and strength after high doses of radiation, making it potentially useful for building spacecraft or Mars colonies

https://www.newscientist.com/article/2343246-aluminium-alloy-could-boost-spacecraft-radiation-shielding-100-fold/


____________________________________


UF Engineers Develop Lightweight Metal for NASA

2017

https://mse.ufl.edu/lightweight_metal_reduce_radiation/


____________________________________

New high precision foil resistors for space projects, with zero temperature coefficient very low power coefficient and high reliability

2002

https://ui.adsabs.harvard.edu/abs/2002ESASP.507...49F/abstract

 

____________________________________ 

 

Extreme Metamaterial Solar Sails for Breakthrough Space Exploration

 

Apr 7, 2020

 

https://www.nasa.gov/directorates/spacetech/niac/2020_Phase_I_Phase_II/Extreme_Metamaterial_Solar_Sails/

 

____________________________________

Solar sail

 

https://en.wikipedia.org/wiki/Solar_sail

 

____________________________________

Solar Sail: Materials and Space Environmental Effects

 

https://arxiv.org/ftp/arxiv/papers/1307/1307.7327.pdf

 

____________________________________

 

Textile Material Lessons Learned During the Design and Qualification of the NASA Orion Capsule Parachute Assembly System

 

https://ntrs.nasa.gov/api/citations/20190026519/downloads/20190026519.pdf

 

____________________________________

 

Supersonic parachutes, a step forward for the journeys of the future

 

24 November 2020

 

https://www.thepatent.news/2020/11/24/supersonic-parachutes-a-step-forward-for-the-journeys-of-the-future/

 

____________________________________

 

 

Shape-changing "robotic fabric" switches between soft and strong

 

September 29, 2020

 

https://newatlas.com/materials/robotic-fabric-shape-change-soft-hard-heated-cooled/

 

____________________________________

 

Shape-shifting materials with infinite possibilities

 

October 21, 2021

 

Totimorphic structural materials can achieve any shape

 

https://seas.harvard.edu/news/2021/10/shape-shifting-materials-infinite-possibilities

 

____________________________________

 

Advanced morphing material able to take on any shape

 

October 22, 2021

 

https://eandt.theiet.org/content/articles/2021/10/morphing-material-takes-on-any-shape/

 

____________________________________

 

New shape-shifting material can move like a robot

 

July 13, 2022

 

https://techxplore.com/news/2022-07-shape-shifting-material-robot.html

 

____________________________________

 

This Shape-Shifting Robot Can Liquefy Itself and Reform

 

January 27, 2023

 

The technology could one day assemble and repair hard-to-reach circuits, act as a universal screw or retrieve foreign objects from a body, researchers say

 

https://www.smithsonianmag.com/smart-news/this-shape-shifting-robot-can-liquefy-itself-and-reform-180981515/

 

____________________________________

 

MIT and NASA engineers demonstrate a new kind of airplane wing

 

March 31, 2019

 

Assembled from tiny identical pieces, the wing could enable lighter, more energy-efficient aircraft designs.

 

https://news.mit.edu/2019/engineers-demonstrate-lighter-flexible-airplane-wing-0401

 

____________________________________

How the Pentagon Could Make Magnet-Powered Subs Like ‘Red October’ a Reality

 

Jun 2, 2023

 

Warships, both on and under the sea, could someday sail without moving parts.

The Pentagon is looking to develop so-called magnetohydrodynamic (MHD) technology to propel future ships and submarines.

MHDs would use magnetic fields instead of propellers, creating quieter, more maneuverable ships.

 

https://www.popularmechanics.com/military/navy-ships/a44067238/mhd-drive-technology-submarines/

 

____________________________________

 

Propellers make a comeback on a new type of aircraft engine

 

Jul 28th 2021

 

Propfans will be cleaner and more fuel-efficient

 

https://www.economist.com/science-and-technology/2021/07/28/propellers-make-a-comeback-on-a-new-type-of-aircraft-engine

 

____________________________________

 

MIT's latest drone propellers are very quiet and efficient

 

They consist of two blades looping together so that the tip of one blade curves back into the other.

 

Jan 27, 2023

 

https://interestingengineering.com/innovation/mits-latest-drone-propellers

 

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Toroidal Propeller Technology Could Mean Near-Silent Drones in the Future

 

January 30, 2023

 

https://www.techeblog.com/toroidal-propeller-technology-silent-drone/

 

____________________________________

 

The Future Of Aeronautical Propulsion & Aviation Technology

 

April 21, 2019

 

https://techreader.com/tech/trends/the-future-of-aeronautical-propulsion-aviation-technology/

 

____________________________________

 

 

Stolt Tankers utilize new graphene propeller coatings on 25 vessels

 

April 12, 2023

 

https://shipnerdnews.com/stolt-tankers-graphene-propeller-coatings/

 

____________________________________

 

Use of Graphene-Based Coatings and Composites in Sports Equipment

 

Dec 30 2021

 

https://www.azom.com/article.aspx?ArticleID=21102

 

 

____________________________________

 

Graphene on the pilot line
 
28 April 2021
 
https://www.nature.com/articles/s41563-021-00999-0

 

____________________________________

 

Physicists discover important new property for graphene

 

2021

 

Unconventional form of ferroelectricity could impact next-generation computing.

 

https://news.mit.edu/2021/physicists-discover-important-new-property-graphene-0208

 

____________________________________

Twisted physics: Magic angle graphene produces switchable patterns of superconductivity

 

October 30, 2019

 

https://phys.org/news/2019-10-physics-magic-angle-graphene-switchable.html

 

____________________________________

 

Spacecraft built from graphene could run on nothing but sunlight

 

2015

 

https://www.newscientist.com/article/mg22630235-400-spacecraft-built-from-graphene-could-run-on-nothing-but-sunlight/

____________________________________

 

 

New research on self-locking light sources presents opportunities for quantum technologies

June 19, 2023

https://sciligent.com/2023/06/new-research-on-self-locking-light-sources-presents-opportunities-for-quantum-technologies/

 
____________________________________

Asynchronous locking in metamaterials of fluids of light and sound

19 June 2023

Abstract

Lattices of exciton-polariton condensates represent an attractive platform for the study and implementation of non-Hermitian bosonic quantum systems with strong non-linear interactions. The possibility to actuate on them with a time dependent drive could provide for example the means to induce resonant inter-level transitions, or to perform Floquet engineering or Landau-Zener-Stückelberg state preparation. Here, we introduce polaromechanical metamaterials, two-dimensional arrays of μm-sized traps confining zero-dimensional light-matter polariton fluids and GHz phonons. A strong exciton-mediated polariton-phonon interaction induces a time-dependent inter-site polariton coupling J(t) with remarkable consequences for the dynamics. When locally perturbed by continuous wave optical excitation, a mechanical self-oscillation sets-in and polaritons respond by locking the energy detuning between neighbor sites at integer multiples of the phonon energy, evidencing asynchronous locking involving the polariton and phonon fields. These results open the path for the coherent control of dissipative quantum light fluids with hypersound in a scalable platform.

https://www.nature.com/articles/s41467-023-38788-9

 

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Shear Ultrasound Shaking Lowers Friction between Solids
 

Ultrasound shaking will lower the friction between two objects and can induce sudden, large jerky motions

Feb 21, 2023

https://www.labmanager.com/shear-ultrasound-shaking-lowers-friction-between-solids-29826

 

____________________________________ 

 

Ion Propulsion: Farther, Faster, Cheaper

 

12.07.04

 

https://www.nasa.gov/centers/glenn/technology/Ion_Propulsion1.html

 

____________________________________

 

 

A New Electric Jet Engine Actually Works Inside the Atmosphere

 

2021

 

And it's based on a kind of plasma.

 

https://interestingengineering.com/innovation/new-electric-jet-engine-actually-works-inside-the-atmosphere

 

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Silent and Simple Ion Engine Powers a Plane with No Moving Parts

 

November 21, 2018

 

Researchers fly the first atmospheric aircraft to use space-proven ionic thrust technology

 

https://www.scientificamerican.com/article/silent-and-simple-ion-engine-powers-a-plane-with-no-moving-parts/

 

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Flying with ionic wind

21 November 2018

Aeroplanes use propellers and turbines, and are typically powered by fossil-fuel combustion. An alternative method of propelling planes has been demonstrated that does not require moving parts or combustion.

Small, lightweight devices called lifters can propel themselves into the air without combustion or moving parts, and have become a popular topic of discussion with technology buffs on social media in the past few years. And yet the physical mechanism behind lifters has been known for more than a century. When charged molecules in the air are subjected to an electric field, they are accelerated.

https://www.nature.com/articles/d41586-018-07411-z

 

 

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REVOLUTIONARY PROPELLER TECHNOLOGY: A Game-Changer for TRANSPORTATION!

 

May 20, 2023

 

https://www.youtube.com/watch?v=F9_QCr6K5ZI

 

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New sodium, aluminum battery aims to integrate renewables for grid resiliency

 

Low-cost, Earth-abundant raw materials power a new grid energy storage solution

 

February 7, 2023

 

https://www.sciencedaily.com/releases/2023/02/230207081251.htm

 

____________________________________

 

New high-volume joining process expands use of aluminum in autos

 

May 12, 2015

 

 Researchers have demonstrated a new process for the expanded use of lightweight aluminum in cars and trucks at the speed, scale, quality and consistency required by the auto industry. The process reduces production time and costs while yielding strong and lightweight parts, for example delivering a car door that is 62 percent lighter and 25 percent cheaper than that produced with today's manufacturing methods.

http://phys.org/news/2015-05-high-volume-aluminum-autos.html#jCp

 

 

____________________________________

 

 

Tiny Space Probes Using “Laser Sails” Could Speed to Outer Planets and Beyond

 

February 23, 2022

 

https://scitechdaily.com/tiny-space-probes-using-laser-sails-could-speed-to-outer-planets-and-beyond/

 

____________________________________

 

From Solar Sails to Laser Sails

 

December 15, 2017

 

https://ntrs.nasa.gov/api/citations/20170012350/downloads/20170012350.pdf

 

____________________________________

 

Plant-based nylon: Now it’s fact, not fantasy

 

2022

 

https://www.voguebusiness.com/sustainability/plant-based-nylon-now-its-fact-not-fantasy

 

____________________________________

 

 

Plant-based nylon: Now it’s fact, not fantasy

 

2022

 

https://www.voguebusiness.com/sustainability/plant-based-nylon-now-its-fact-not-fantasy

 

____________________________________

 

Bio-Nylon Is The New Green: How One Company Is Fermenting A $10 Billion Market

 

Feb 11, 2020

 

https://www.forbes.com/sites/johncumbers/2020/02/11/bio-nylon-is-the-new-green-how-one-company-is-fermenting-your-future-materials/?sh=6bd9f5694030

 

____________________________________

 

Next-Gen ‘Bio-Based’ Synthetics Are Here, But When Will They Replace Polluting Polyester?

 

Mar 11, 2022

 

https://www.forbes.com/sites/brookerobertsislam/2022/03/11/next-gen-bio-based-synthetics-are-here-but-when-will-they-replace-polluting-polyester/?sh=19a979fc5f6d

 

 

____________________________________

Scientists spin naturalistic silk from artificial spider gland

January 22, 2024

https://phys.org/news/2024-01-scientists-naturalistic-silk-artificial-spider.html

____________________________________


New ways to strengthen biomimetic spider-silk

March 4, 2024

https://phys.org/news/2024-03-ways-biomimetic-spider-silk.html

 
____________________________________

 

Smart Material: Spider Silk 

 

 Mar 5, 2011

 https://www.youtube.com/watch?v=nYlkJyG1Oik&list=PLQoTHqAEU9OSjWhEvxWS5PIka1lSQrEZ8&index=8

 
____________________________________

 

Spiders sprayed with carbon nanotubes spin superstrong webs

 A team of researchers working in Italy has found that simply spraying a spider with a carbon nanotube solution can cause the spider to spin stronger webs. In their paper they have uploaded to the preprint server arXiv, the team describes their experiments with both graphene and nanotube solutions and what happened when they sprayed it on ordinary spiders.

 http://phys.org/news/2015-05-spiders-carbon-nanotubes-superstrong-webs.html?utm_source=menu&utm_medium=link&utm_campaign=item-menu

____________________________________

Add Graphene To Spider Silk To Create The Strongest Fiber Yet

 

Web slingers get a high-tech upgrade

Posted May 7, 2015

 
http://www.popsci.com/spiders-add-graphene-silk-creating-strongest-fiber-yet

 

____________________________________ 

 
 Researchers explore mechanics of silk to design materials with high strength and low density

May 15, 2015

 Scientists at MIT have developed a systematic approach to research the structure of spider silk, blending computational modeling and mechanical analysis to 3D-print synthetic spider webs.


 http://phys.org/news/2015-05-explore-mechanics-silk-materials-high.html#jCp


____________________________________ 

Spider signal threads reveal remote sensing design secrets

 

December 16, 2015

When you look at a spider web in the garden, one thing is often noticeably absent: the spider. This may be because it is lurking away from the web in a 'retreat', where it can monitor web vibrations through a proxy known as a signal thread.

A new Oxford study published in Journal of the Royal Society Interface looks in more detail at the composition and structure of these signal threads, which spiders can use to tell whether they've caught new prey.

Dr Beth Mortimer from the Oxford Silk Group, based in the Department of Zoology, spoke to Science Blog about the research.

http://phys.org/news/2015-12-spider-threads-reveal-remote-secrets.html

 
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Chapter 24: Air power

____________________________________
____________________________________

 

 

 

 



____________________________________



Top five air powered vehicles

 http://inhabitat.com/top-five-air-powered-vehicles-coming-soon-to-the-us/aircar/

____________________________________

Air Force scientists are working on hypersonic air vehicle

 

Jun 07, 2015

 Engineers said the US Air Force is getting closer to testing a hypersonic weapon. They are developing a hypersonic weapon based on an experimental scramjet program. What is a scramjet? NASA said in a "scramjet," or Supersonic Combustion Ramjet, the oxygen needed by the engine to combust is taken from the atmosphere passing through the vehicle rather than from an onboard tank. "Researchers predict scramjet speeds could reach 15 times the speed of sound. An 18-hour trip to Tokyo from New York City becomes a 2-hour flight," said NASA.

http://phys.org/news/2015-06-air-scientists-hypersonic-vehicle.html#jCp


____________________________________ 

Non-rocket spacelaunch

 

http://en.wikipedia.org/wiki/Non-rocket_spacelaunch



____________________________________

Jet pack

 http://en.wikipedia.org/wiki/Jet_pack

____________________________________

 

Watch world's first electric wingsuit flight

Jan 27, 2022

https://www.youtube.com/watch?v=zmRQKZZ_wXc

-


UK’s Royal Navy Showcases Flying Jet Pack Suits

2022 Oct 5

https://www.youtube.com/shorts/qWHYKLYmOJM

____________________________________


Water JetPack Flyboard. Can Anyone Learn How To Do It?

Jul 25, 2019

https://www.youtube.com/watch?v=xIeXwFhqdFk

____________________________________

Flyboard - Coolest Water Jet Pack EVER!!!

Feb 18, 2013

https://www.youtube.com/watch?v=m4Bm3cs9TFo

____________________________________

Flyride - The new flying water jet bike from Zapata

Dec 12, 2017

https://www.youtube.com/watch?v=5LhHEmbyzjo

____________________________________

Best Electric Surfboards in 2025

Sep 18, 2024

https://www.youtube.com/watch?v=i1FVwSCNpVc

____________________________________

Electric Surfboards 

https://www.youtube.com/results?search_query=Electric+surfboards+

____________________________________

CudaJet: The World’s First Underwater Jetpack!

Jun 5, 2025

https://www.youtube.com/watch?v=i6i7DxZL5lc

____________________________________

 

____________________________________
____________________________________




Chapter 25: Transportation



____________________________________
____________________________________

 

 

 



____________________________________


If we could make a sustainable type of plastic, from materials such as kelp, foods and silicone. We could also make many plastic parts for appliances and vehicles.

 
____________________________________

 

Plastic parts for internal combustion engines

 

Apr 2015 

 

http://phys.org/news/2015-04-plastic-internal-combustion.html#nRlv

____________________________________ 

GE fires up fully 3D-printed jet engine

May 13, 2015

http://www.gizmag.com/ge-fires-up-all-3d-printed-jet-einge/37448/


____________________________________

18 of the coolest, weirdest, and most important electric cars of all time

http://www.networkworld.com/article/2912371/software/18-of-the-coolest-weirdest-and-most-important-electric-cars-of-all-time.html#slide1

____________________________________

Who killed The Electric Car

https://www.youtube.com/watch?v=r75lqbA0uMM

____________________________________

 

 

Imagine the applications of being able to make 3d printed engines and motors. We even have exoskeleton technology to make paralyzed people walk once again.

 

____________________________________

Completely paralyzed man steps out in robotic exoskeleton

 

September 2, 2015
 

http://www.gizmag.com/ucla-robotic-exoskeleton-non-invasive-spinal-cord-stimulation/39216/


____________________________________

Quadriplegic successfully uses mind-controlled robotic arm

 

December 18, 2014


http://www.gizmag.com/quadriplegic-mind-controlled-robotic-arm/35275/?li_source=LI&li_medium=default-widget

____________________________________

Pulley mechanism implant to better restore hand function

• September 26, 2014

 

http://www.gizmag.com/pulley-implant-hand-function/33992/

____________________________________

Paralyzed man uses own brainwaves to walk again – no exoskeleton required

 

September 23, 2015



 http://www.gizmag.com/paralyzed-man-brainswaves-walk/39550/?li_source=LI&li_medium=default-widget

____________________________________

Spinal implant could one day let paralyzed people walk again

 

January 9, 2015

Three years ago, scientists at the Swiss Federal Institute of Technology (EPFL) reported success in getting rats with severed spinal cords to walk again. They did so by suspending the animals in a harness, then using implants to electrically stimulate neurons in their lower spinal cord. Although this ultimately resulted in the rats being able to run on their previously-paralyzed hind legs, the technology still wasn't practical for long-term use in humans. Thanks to new research conducted at EPFL, however, that may no longer be the case.

  http://www.gizmag.com/epfl-e-dura-spinal-cord-implant/35545/?li_source=LI&li_medium=default-widget

 
____________________________________

Future Transportation Technology Will Blow Your Mind

 

https://www.youtube.com/watch?v=oYOmZlTjsQ0

____________________________________

Radical railways: Top 10 transportation systems of the future

 http://www.gizmag.com/future-transport/22959/



____________________________________ 

Elon Musk's high-speed Hyperloop train makes more sense for Mars than California

 

July 13, 2015

 

http://phys.org/news/2015-07-elon-musk-high-speed-hyperloop-mars.html

Ever wanted to ride to work in a screaming roller-coaster gun? If your answer was yes: good news!

Elon Musk – of SpaceX and Tesla Motors fame – recently proposed the "Hyperloop," a high-speed floating train that's accelerated by magnets and coasts between destinations. Hailed as the train of the future, the concept is indeed pretty fancy. Described by Musk himself as "the fifth mode of transport," it's intended to provide fast and safe transit, largely self-powered with electricity generated by its own solar panels.


How would Hyperloop work?

The Hyperloop train concept is based on the idea of a "vactrain." That's a high-speed train run in a tube that has had all the air removed, making it a vacuum – hence the name. Having no air in the tube means (almost) no drag, the aerodynamic force that pushes in the opposite direction from which a train is traveling. So a vactrain could potentially travel really fast – think thousands of miles an hour.

 

____________________________________

The future of rail travel, and why it doesn't look like Hyperloop

 

August 5, 2015

 

 http://phys.org/news/2015-08-future-rail-doesnt-hyperloop.html?utm_source=menu&utm_medium=link&utm_campaign=item-menu

____________________________________ 

Japan's maglev train breaks world speed record with 600km/h test run

 

2015

 

 

Seven-car ‘magnetic levitation’ train hits top speed of 603km/h less than a week after breaking the 2003 record of 581km/h

 

 http://www.theguardian.com/world/2015/apr/21/japans-maglev-train-notches-up-new-world-speed-record-in-test-run

____________________________________

Fastest Car in the World: Worlds Top 5

 https://www.youtube.com/watch?v=MXCYu_ROyhk


____________________________________

Bloodhound SSC

Bloodhound SSC is a supersonic land vehicle currently in development. Its goal is to match or exceed 1,000 miles per hour (1,609 km/h) achieving a new world land speed record. The pencil-shaped car, powered by a jet engine and a rocket engine is designed to reach 1,050 miles per hour (1,690 km/h). It is being developed and built with the intention of breaking the land speed record by 33%, the largest ever margin.

http://en.wikipedia.org/wiki/Bloodhound_SSC

____________________________________

ThrustSSC

ThrustSSC, Thrust SSC, or Thrust supersonic car, is a British jet-propelled car developed by Richard Noble, Glynne Bowsher, Ron Ayers and Jeremy Bliss.
Thrust SSC holds the World Land Speed Record, set on 15 October 1997, when it achieved a speed of 1,228 km/h (763 mph) and became the first car to officially break the sound barrier.

 http://en.wikipedia.org/wiki/ThrustSSC

____________________________________ 

Unstoppable! Airless tire will never go flat

 

http://www.zdnet.com/article/unstoppable-airless-tire-will-never-go-flat/

____________________________________ 

Students design the tire of the future

December 29, 2014

 http://www.gizmag.com/hankook-tyre-design-challenge-2014/35380/

____________________________________

New nanogenerator harvests power from rolling tires

 

June 29, 2015

http://phys.org/news/2015-06-nanogenerator-harvests-power.html?utm_source=menu&utm_medium=link&utm_campaign=item-menu

____________________________________

The Magnetic Air Car: a Step Towards Free Energy Devices?

 

September 30, 2008

 http://www.greenoptimistic.com/magnetic-air-car-20080930/#.VSFjlOG-2zk




____________________________________

Meet the electric motorcycle that's now the fastest production bike in the world

  

May 20th 2014 

 The Lightning LS-218 boasts a model number that actually means something. Back in 2012, a prototype of the electric bike clocked in a wholly unnecessary (yet much appreciated) 218mph, helping it to win at Pikes Peak and setting it up to become the world's fastest production motorcycle. The finished version is now ready to make good on that promise, having just been revealed at the Quail Motorsport Gathering in California, prior to a scheduled launch in the summer -- at which point it'll likely cost upwards of $38,000.

 http://www.engadget.com/2014/05/20/lightning-ls-218-electric-motorbike-revealed/

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Chapter 26: Alternative fuel



____________________________________
____________________________________

 

 

 

 

 


____________________________________

 

Exotic “Blinking” Crystals May Convert CO2 Into Fuels, Power Quantum Computers

 

22nd, Jul 2020

 

Unusual nanoparticles could benefit the quest to build a quantum computer. Imagine tiny crystals that “blink” like fireflies and can convert carbon dioxide, a key... The post Exotic “Blinking” Crystals May Convert CO2 Into Fuels, Power Quantum Computers appeared first on SciTechDaily.

https://statnano.com/world-news/81470/Exotic-%E2%80%9CBlinking%E2%80%9D-Crystals-May-Convert-CO2-Into-Fuels-Power-Quantum-Computers

 ____________________________________

 

 

Enzymes from fungi can help extract plant components for biofuels and bioplastics

 

18 June 2025

https://www.the-microbiologist.com/news/enzymes-from-fungi-can-help-extract-plant-components-for-biofuels-and-bioplastics/6132.article

____________________________________ 

Researchers produce new fuel from coal dust and algae

 

December 22, 2015

 Researchers at the Nelson Mandela Metropolitan University (NMMU) in South Africa have developed a new fuel, known as Coalgae. Made from a combination of algae and coal dust, the latter of which is a waste product, the fuel could have a significant positive impact on the environment.

http://www.gizmag.com/nmmu-new-fuel-coalgae/41030/?li_source=LI&li_medium=default-widget 

____________________________________

Audi just created diesel fuel from air and water

April 26, 2015

 Audi is making a new fuel for internal combustion engines that has the potential to make a big dent when it comes to climate change – that's because the synthetic diesel is made from just water and carbon dioxide.

 http://www.gizmag.com/audi-creates-e-diesel-from-co2/37130/

____________________________________

 

Researchers Found An Enzyme That Could Get Gasoline From Thin Air

 

August 8, 2010

 Scientists at the University of California found a new way to get gasoline from thin air. According to them, an enzyme (located in the roots of soybeans) that normally produces ammonia from nitrogen gas, is able to convert carbon monoxide into propane (a common industrial byproduct used in kitchens across America). This could be the key to vehicles that run on air.

“This organism is a very common soil bacteria that is very well understood and has been studied for a long time. But while we were studying it, we realized that the enzyme has some unusual behavior”, said Markus Ribbe, a scientist at the University of California.

The research group has also isolated one particular enzyme to convert nitrogen into ammonia. Without nitrogen oxygen, the enzyme began to turn the carbon monoxide (CO) into short chains of carbon two and three atoms long generating propane. They hope to modify the enzyme so it can produce gasoline.

http://www.greenoptimistic.com/enzyme-gasoline-thin-air-20100808/#.VSX0nZO-2zk


____________________________________

Catalyst that converts carbon dioxide to carbon monoxide in water

 

Jun 03, 2015

http://phys.org/news/2015-06-catalyst-carbon-dioxide-monoxide.html?utm_source=menu&utm_medium=link&utm_campaign=item-menu

 

____________________________________

New process produces hydrogen from methane, without emitting CO2

 

November 30, 2015

Natural gas accounts for over 28 percent of US energy consumption. Its main component, methane, is a widely-used fossil fuel but also a major contributor to rising CO₂ levels, and thus climate change. To address this issue, researchers from the Institute of Advanced Sustainability Studies (IASS) and Karlsruhe Institute of Technology (KIT) have developed a process that extracts the energy content of methane, in the form hydrogen, without producing carbon dioxide...

http://www.gizmag.com/hydrogen-production-methane-without-co2/40502/?li_source=LI&li_medium=default-widget

 
____________________________________

Simpler, cheaper way to make liquid methanol fuel using CO2 and sunlight

 

April 7, 2013

http://www.gizmag.com/photochemical-photosynthesis-uta-co2-methanol/26766/


____________________________________

Carbon dioxide from the air converted into methanol

 

• February 6, 2016

 

http://www.gizmag.com/air-co2-methanol-conversion-usc/41669/?li_source=LI&li_medium=default-widget

 
____________________________________

Scientists develop diesel that emits far less CO2

 

December 10, 2015 

 

Researchers from KU Leuven and Utrecht University have discovered a new approach to the production of fuels. Their new method can be used to produce much cleaner diesel. It can quickly be scaled up for industrial use. In 5 to 10 years, we may see the first cars driven by this new clean diesel. The production of fuel involves the use of catalysts. These substances trigger the chemical reactions that convert raw material into fuel. In the case of diesel, small catalyst granules are added to the raw material to sufficiently change the molecules of the raw material to produce useable fuel.

http://phys.org/news/2015-12-scientists-diesel-emits-co2.html

 
____________________________________

 

New family of chemical structures can effectively remove CO2 from gas mixtures

 

July 16, 2015 

 

A newly discovered family of chemical structures, published in Nature today, could increase the value of biogas and natural gas that contains carbon dioxide.


The new chemical structures, known as zeolites, have been created by an international team of researchers including Professor Xiaodong Zou and co-workers from the Department of Materials and Environmental Chemistry at Stockholm University.

The zeolites—crystalline aluminosilicates with frameworks that contain windows and cavities the size of small molecules—can separate out carbon dioxide more effectively from fuel gases than those previously known.

http://phys.org/news/2015-07-family-chemical-effectively-co2-gas.html#jCp

____________________________________

Solar cell sucks up CO2 and spits burnable fuel out the other side

 

July 29, 2016


http://newatlas.com/solar-cell-co2-burnable-fuel/44645/


____________________________________ 

 

Engineered surface holds promise for tech to convert CO₂ into liquid fuel

March 24, 2025 

Researchers have developed a novel combination of materials that have organic and inorganic properties, with the goal of using them in technologies that convert carbon dioxide from the atmosphere into a liquid fuel. The paper, "Mild-Annealed Molecular Layer Deposition (MLD) Tincone Thin Film as Photoelectrochemically Stable and Efficient Electron Transport Layer for Si Photocathodes," is published in ACS Applied Energy Materials.

https://techxplore.com/news/2025-03-surface-tech-liquid-fuel.html

____________________________________

 

Biodiesel wastewater treatment: Capturing carbon and valuable chemicals

March 21, 2025

While biodiesel provides a cleaner-burning alternative to petroleum diesel, it produces ​​CO2 and hazardous wastewater during manufacturing, requiring extra steps to achieve sustainability. A diagnostic study led by University of Michigan researchers works to improve a process that captures CO2 while treating biodiesel wastewater and produces valuable co-products like fuels and green chemicals.

During biodiesel production, fats—like vegetable oils, animal fats or recycled restaurant grease—are transformed into fuel through a process called transesterification. With the help of a catalyst, an alcohol (typically methanol) breaks the bonds in the fat molecules to create glycerol and long, chain-like molecules called fatty acid esters. 

The fatty acid esters, which resemble petroleum diesel’s molecular structure, become biodiesel while the glycerol goes into the wastewater as a byproduct. If left untreated, glycerol can pollute natural water resources by depleting oxygen levels, suffocating fish and other organisms.

https://cee.engin.umich.edu/2025/03/21/biodiesel-wastewater-treatment-capturing-carbon-and-valuable-chemicals/

____________________________________

 

Posted: Mar 05, 2015

Breakthrough in energy harvesting could power 'life on Mars'     http://www.nanowerk.com/news2/space/newsid=39285.php

(Nanowerk News) Martian colonists could use an innovative new technique to harvest energy from carbon dioxide thanks to research pioneered at Northumbria University, Newcastle.

The technique, which has been proven for the first time by researchers at Northumbria, has been published in the prestigious journal Nature Communications ("A sublimation heat engine").

The research proposes a new kind of engine for producing energy based on the Leidenfrost effect – a phenomenon which happens when a liquid comes into near contact with a surface much hotter than its boiling point. This effect is commonly seen in the way water appears to skitter across the surface of a hot pan, but it also applies to solid carbon dioxide, commonly known as dry ice. Blocks of dry ice are able to levitate above hot surfaces protected by a barrier of evaporated gas vapour. Northumbria’s research proposes using the vapour created by this effect to power an engine. This is the first time the Leidenfrost effect has been adapted as a way of harvesting energy.

The technique has exciting implications for working in extreme and alien environments, such as outer space, where it could be used to make long-term exploration and colonisation sustainable by using naturally occurring solid carbon dioxide as a resource rather than a waste product. If this could be realised, then future missions to Mars, such as those in the news recently, may not need to be ‘one-way’ after all.

Dry ice may not be abundant on Earth, but increasing evidence from NASA’s Mars Reconnaissance Orbiter (MRO) suggests it may be a naturally occurring resource on Mars as suggested by the seasonal appearance of gullies on the surface of the red planet. If utilised in a Leidenfrost-based engine dry-ice deposits could provide the means to create future power stations on the surface of Mars.

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Chapter 27: Biofuel



____________________________________
____________________________________

 

 

 

 



____________________________________




We have already seen the problems with genetically modified corn and soy. We must now question if genetically modified tobacco plants have been tested thoroughly. Different groups think that we still need better options for energy, other than biofuel. Many question the excess amount of chemicals and carbon emissions from biofuel.  Some think that hydrogen energy, magnetic energy and electrical energy may be cleaner than certain types of biofuel. We have still not explored all of the possibilities yet, in the sustainable production of different types of biofuel. Biofuel can be made from many different plants, such as coffee grounds, sugarcane, hemp, corn, used cooking oil and many other types of plants. With laws such as H.R. 1599, many are concerned that the government now has the authority to genetically modify any plant, and approve GMO plants for human consumption. 



____________________________________

 

Microalgae biofuel yields boosted with nanotechnology

 

 July 24, 2025

 

https://phys.org/news/2025-07-microalgae-biofuel-yields-boosted-nanotechnology.html 

 

____________________________________

 

The Plan to Turn the Caribbean’s Glut of Sargassum Into Biofuel

Aug 18, 2025

With record-breaking quantities of the seaweed set to hit Mexico’s beaches, experts propose converting it into biogas and construction materials, as well as using it to underwrite carbon credits.

https://www.wired.com/story/there-is-more-sargassum-than-ever-in-the-caribbean-and-they-want-to-turn-it-into-energy/#intcid=_wired-nativearticle-bottom-recirc_f86fd5b9-2212-40e4-b4a5-b1cf8a15f1ca_entity-topic-similarity-v2_fallback_popular4-2

____________________________________ 

 

Making biodiesel from dirty old cooking oil just got way easier

 

 26-Oct-2020 

 

 

Sponge-like catalysts could transform biodiesel production and chemical manufacturing. Image shows the porous ceramic sponge fabricated in the study (magnified 20,000 times).

 

New ultra-efficient catalyst can recycle old cooking oil into biodiesel and turn food scraps into high-value complex molecules 

 

https://www.eurekalert.org/news-releases/825841


____________________________________

 

New catalyst can turn smelly hydrogen sulfide into a cash cow

 

Light-powered catalyst makes hydrogen energy from pungent gas in one-step process

 

HOUSTON – (Oct. 31, 2022) – Rice University engineers and scientists have created a sweet way for petrochemical refineries to turn a smelly byproduct into cash.

 

Hydrogen sulfide gas has the unmistakable aroma of rotten eggs. It often emanates from sewers, stockyards and landfills, but it is particularly problematic for refineries, petrochemical plants and other industries, which make thousands of tons of the noxious gas each year as a byproduct of processes that remove sulfur from petroleum, natural gas, coal and other products. 

https://news.rice.edu/news/2022/new-catalyst-can-turn-smelly-hydrogen-sulfide-cash-cow

 ____________________________________

 

 

3D-printed ‘nano-skyscrapers’ help bacteria convert sunlight into electricity

March 24, 2022

 

Current technologies for renewable energy such as biofuels or silicon-based solar cells are superior to fossil fuels in CO2 emissions. But they also have limitations like reliance on mining, recycling difficulties, and dependencies on farming and land use, resulting in biodiversity loss. 

 

Researchers from the University of Cambridge, UK, have developed 3D-printed nano-skyscrapers that could help bacteria convert sunlight into energy. The novel method has the potential to increase sustainable fuel and bio-electricity in the future.

 

The team used 3D printing to create high-rise “building” grids where sun-loving cyanobacteria can grow and multiply quickly. Afterwards, they extracted the bacteria’s waste electrons – left over from photosynthesis – that could be used to power electronic devices.

https://viable.earth/sustainable-energy-transport/these-3d-printed-nano-skyscrapers-help-bacteria-convert-sunlight-into-electricity/

____________________________________ 

 

H.R.1599 - Safe and Accurate Food Labeling Act of 2015

 This bill amends the Federal Food, Drug, and Cosmetic Act to require the developer of a bioengineered organism intended as food to submit a premarket biotechnology notification to the Food and Drug Administration (FDA). A “bioengineered organism” (commonly called a “genetically modified organism” or “GMO”) is a plant or part of a plant that has been modified through recombinant DNA techniques in a way that could not be obtained using conventional breeding techniques.


A food can be labeled as non-GMO even if it is produced with a GMO processing aid or enzyme or derived from animals fed GMO feed or given GMO drugs. The FDA must allow, but not require, GMO food to be labeled as GMO...



The FDA must allow, but not require, GMO food to be labeled as GMO...


https://www.congress.gov/bill/114th-congress/house-bill/1599


____________________________________

Scientists Hack Tobacco Plants to Grow Synthetic Photovoltaic Cells

 

January 27, 2010

 http://www.greenoptimistic.com/scientists-hack-tobacco-plants-to-grow-synthetic-photovoltaic-cells-20100127/#.VX_4FEa-2zk

 
____________________________________

Genetically Modified Tobacco Leaves Make Biofuel Efficiently

  January 2, 2010

 

 http://www.greenoptimistic.com/tobacco-leaves-biofuel/#.VX__cEa-2zk

____________________________________

 

'Nano-raspberries' could bear fruit in fuel cells

 

Jun 09, 2015 

 

 

 Researchers at the National Institute of Standards and Technology have developed a fast, simple process for making platinum 'nano-raspberries'—microscopic clusters of nanoscale particles of the precious metal. The berry-like shape is significant because it has a high surface area, which is helpful in the design of catalysts. Even better news for industrial chemists: the researchers figured out when and why the berry clusters clump into larger bunches of 'nano-grapes.' The research could help make fuel cells more practical.

http://phys.org/news/2015-06-nano-raspberries-fruit-fuel-cells.html#jCp



____________________________________

Researchers develop fermentation process to produce biofuels from waste biomass

 

December 25, 2015

 

 Imagine a world where vehicles run on beer. Some might think of this as a devastating waste of good hops, but a University of Maryland (UMD) team sees a lot of promise for the idea. The team has been awarded a patent for a process that uses natural microorganisms to ferment biomass or gases into hydrocarbons. In short, they've figured out how to brew gasoline naturally...

 http://www.gizmag.com/umd-ferment-gasoline/41066/?li_source=LI&li_medium=default-widget

 
____________________________________

New technique uses most abundant gas on Earth to help create bioethanol

 

February 3, 2015

 http://www.gizmag.com/bacterium-nitrogen-gas-bioethanol/35883/?li_source=LI&li_medium=default-widget

Zymomonas mobilis bacterium might be tricky to say, but this bioethanol-producing microbe could become a household name if Indiana University (IU) biologists have their way. The biologists claim to have found a quicker, cheaper, cleaner way to increase bioethanol production in this microorganism by using the most abundant element in the Earth’s atmosphere: nitrogen gas (N₂). By replacing chemical fertilizers with N₂, production costs could be slashed and cellulose ethanol derived from wood pulp made much more economically viable – so much so that the researchers believe it may compete with corn ethanol and gasoline on price.

Cellulose found in woody plants such as trees, grasses, and other inedible plant substances – like olive stones – is generally low in nitrogen, which makes cellulose all that much more difficult to convert given that nitrogen is a staple requirement for feeding ethanol-producing microbes. As a result, cellulosic ethanol makers spend many millions of dollars a year on nitrogen-rich fertilizers such as diammonium phosphate or corn-steep liquor.

 

____________________________________

 

Cool science: Researchers craft tiny biological tools using frozen ethanol

 

May 20, 2025

 

Imagine drawing on something as delicate as a living cell -- without damaging it. Researchers have made this groundbreaking discovery using an unexpected combination of tools: frozen ethanol, electron beams and purple-tinted microbes. By advancing a method called ice lithography, the team was able to etch incredibly small, detailed patterns directly onto fragile biological surfaces.

https://www.sciencedaily.com/releases/2025/05/250520121257.htm

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Cats in a Cage: Novel Hybrid Nanocages for Improved Catalytic Efficiency

 

January 24, 2022

 

A novel hybrid ferritin nanocage with histidine residues shows 1.5 times higher metal ion uptake and improved catalytic efficiency for alcohol production, find researchers from Tokyo Tech in a new study. Their findings suggest that hybrid bio-nanocages could effectively catalyze reactions to yield industrially important products. 

 
https://scitechdaily.com/cats-in-a-cage-novel-hybrid-nanocages-for-improved-catalytic-efficiency/

 

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Serendipitous discovery could lead to more efficient catalysts

April 9, 2025

 

Preparing catalysts by sending hot, steamy car exhaust over them could improve their efficiency and reduce the amount of rare and expensive metals required in vehicle catalytic converters and many other emission control and industrial processes.  

https://www.sciencedaily.com/releases/2025/04/250407172923.htm

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Revolution in Nanotech: A Motor That’s 1/10,000th of a Millimeter 

 

27th, Oct 2023 

https://statnano.com/world-news/103486/Revolution-in-Nanotech-A-Motor-That%E2%80%99s-110-000th-of-a-Millimeter

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DNA Origami Nanoturbine: Pioneering the Nanomotor Revolution

 

October 30, 2023

 

Researchers have introduced a pioneering breakthrough in the world of nanomotors – the DNA origami nanoturbine. This nanoscale device could represent a paradigm shift, harnessing power from ion gradients or electrical potential across a solid-state nanopore to drive the turbine into mechanical rotations. The core of this pioneering discovery is the design, construction, and driven motion of a ’DNA origami’ turbine, which features three chiral blades, all within a minuscule 25-nanometer frame, operating in a solid-state nanopore. By ingeniously designing two chiral turbines, researchers now have the capability to dictate the direction of rotation, clockwise or anticlockwise. 

 
https://scitechdaily.com/dna-origami-nanoturbine-pioneering-the-nanomotor-revolution/

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New Membrane by Chinese Scientist Can Make Fuel Cells Cheaper

  

December 17, 2008

 Fuel cells are said to be the next big thing in the auto industry. In fact, they already are the next big thing. Fuel cells take advantage of the joining force between the oxygen and the hydrogen, and create electricity, used to drive anything (a car, more commonly). Price is a prohibitive variable in fuel cells market, and that’s what’s keeping them from becoming mainstream. Current versions of fuel cells use platinum as a catalyst for their operation, and, as most of the people know, platinum is an expensive metal.
Lin Zhuang, from the Wuhan University in Hubei, China, has studied and designed a new fuel cell membrane that can make the usage of platinum in fuel cells history. It is much more cheap and can also become more efficient than the membranes that require the use of the expensive metal. His newly developed membrane is alkaline, not acidic, and makes it possible to use nickel instead of platinum.
The new membrane can also be mixed with the catalyst itself (nickel), making the whole assembly more efficient, because the contact surface between them is increased.

http://www.greenoptimistic.com/lin-zhuang-fuel-cell-membrane-20081217/

 

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Researchers discover a royal flush in powering fuel cells with wastewater
 

February 23, 2016 

 

https://phys.org/news/2016-02-royal-flush-powering-fuel-cells.html

 

 As renewable energy sources goes, solar rays have historically hogged the limelight.
But two Virginia Tech researchers have stolen the spotlight from the sun by discovering a way to maximize the amount of electricity that can be generated from the wastewater we flush down the toilet.

An article recently published in Scientific Reports detailing their findings speaks to a growing sustainability movement to capture energy from existing waste to potentially make treatment facilities more energy-efficient.

Xueyang Feng and Jason He traced bacteria, which led them to discover that the working relationship between two specific substrates produced more energy than either did separately. This work will help take the mystery out of how electrochemically-active bacteria create energy. It could help in the development of new treatment system called a microbial fuel cell.


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Added DNA could be used to authenticate premium olive oil

 

April 25, 2014

When most people think of counterfeit goods, they probably picture things like handbags or watches. In fact, there's also a huge market for knock-off high-end food products, such as extra-virgin olive oil. Scientists from Switzerland's ETH Zurich research group, however, have come up with a possible method of thwarting the makers of that bogus oil – just add synthetic DNA particles to the real thing. And yes, consumers would proceed to swallow those particles.
Because DNA can be damaged by exposure to chemicals, light, and fluctuations in temperature when outside of a living organism, the particles are first encased in a protective silica coating. Iron oxide nanoparticles are also added, which come into the picture later.
The DNA particles can then be added to olive oil, with quite a small amount of them being sufficient for the task at hand – according to ETH, "Just a few grams of the new substance are enough to tag the entire olive oil production of Italy."
When stores subsequently wanted to verify the authenticity of tagged oil, they could use a magnet to retrieve some of the DNA particles from a sample of the liquid. This is where the attached iron oxide comes in, as it's drawn to magnets.
The DNA is then freed from its silica shell using a fluoride-based solution, and analyzed via an inexpensive process known as polymerase chain reaction (PCR). If the code of the sampled DNA matched the code that was recorded when the DNA was added by the manufacturer, then the oil would be the genuine article.
Although it would be extremely difficult for counterfeiters to create DNA with that same code, they might be tempted to instead just add a bit of the authentic tagged oil to their own product, thereby mixing in some of its DNA. That wouldn't work, either, however, as it's also possible to measure the concentration of DNA particles in a sample – again, that amount would have to match the value that was recorded by the original manufacturer.
The particles reportedly don't alter the appearance or taste of the oil, and are said to be harmless to ingest. Silica and iron oxide are essentially sand and rust, and are already present in some commonly-consumed foods. As for DNA, we eat it every time we eat plant or animal products. That said, lead scientist Robert Grass thinks that the technology might go over better with consumers if the synthetic DNA were replaced with natural DNA, such as that of fruits or vegetables.
Application of the DNA particles would reportedly cost about 0.02 cents per liter of oil. The tagging system could also be used on a wide variety of other liquids, and has already been successfully tested on Bergamot essential oil, which is used in perfumes. Scientists at Portugal's University of Aveiro are working on a similar system, in which DNA "barcodes" can be added to both liquids and dry goods.

http://www.gizmag.com/olive-oil-dna-counterfeiting/31798/?li_source=LI&li_medium=default-widget

 

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Boeing opens cooking-oil-to-biofuel plant in China

 

October 23, 2014 

 

http://www.gizmag.com/boeing-comac-cooking-oil-biofuel-plant/34388/?li_source=LI&li_medium=default-widget

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Boeing may convert forestry waste into biofuel

 

December 3, 2015 

 

 http://www.gizmag.com/boeing-forestry-waste-biofuel/40711/?li_source=LI&li_medium=default-widget

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22 Jan 2015:

 

Wood Pellets: Green Energy or
New Source of CO2 Emissions?

 http://e360.yale.edu/feature/wood_pellets_green_energy_or_new_source_of_co2_emissions/2840/

 

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Are Biofuel Crops Actually Increasing Carbon Emissions?

 

April 6, 2015

 
- Graduate student Tyler Lark took a look at what happens when biofuel crops replace former wetlands or grasslands, and their findings were quite shocking. The issue arises when you consider that undisturbed forest, wetlands, and grasslands are already doing a fine job of carbon sequestration, all on their own.

Replacing those areas to biofuel crops actually results in a net increase in carbon emissions, according to the UW-Madison study. For example, between 2008 and 2012, the study determined that some seven million acres, about 11,000 square miles, of former grasslands and wetlands. About half of that, or an area the size of the state of Connecticut, was converted land for planting biofuel crops, such as soybeans and corn.

According to their calculations, the destruction of these natural carbon sequestering zones could possibly be responsible for as much carbon dioxide emissions as adding another 28 million cars to the road. In other terms, the UW-Madison study says that this is about as much carbon emissions as putting another 34 coal power plants in service.

Aside from other environmental impacts, such as natural habitat destruction, increased erosion, and increased irrigation, do we need to take another look at land use with regards to net carbon dioxide emissions related to biofuel crops?

http://www.greenoptimistic.com/biofuel-crops-carbon-emissions/#.VX_8cka-2zk


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06 Apr 2015: Millions of Acres of Grasslands
Cleared For Biofuel Crops, Study Finds

 

http://e360.yale.edu/digest/millions_of_acres_of_grasslands_cleared_for_biofuel_crops_study_finds/4404/

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List of forests cleared for biofuel 

https://www.google.com/search?q=10mm+motivational+poster&biw=1600&bih=799&source=lnms&sa=X&sqi=2&pjf=1&ved=0CAoQ_AUoAGoVChMIyuj-0IXwxgIVx6SICh2IegMN&dpr=1#q=list+of+forests+cleared+for+biofuel


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Metal makes for a promising alternative to fossil fuels

• December 12, 2015

Clean fuels come in many forms, but burning iron or aluminum seems to be stretching the definition – unless you ask a team of scientists led by McGill University, who see a low-carbon future that runs on metal. The team is studying the combustion characteristics of metal powders to determine whether such powders could provide a cleaner, more viable alternative to fossil fuels than hydrogen, biofuels, or electric batteries.

http://www.gizmag.com/mcgill-metal-powder-fuel/40869/?li_source=LI&li_medium=default-widg

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New process recycles rare earth elements from wastewater

 

October 31, 2013

Rare earth elements are an integral part of many of today's electronic devices, serving as magnets, catalysts and superconductors. Unfortunately, these minerals are also ... well, rare, and thus very pricey. Recently, however, scientists discovered that some of them can be reclaimed from industrial wastewater, instead of being mined from the earth.
The researchers, from the Chinese Academy of Sciences, already knew that a nanomaterial known as nano-magnesium hydroxide (nano-Mg(OH)2) could remove some metals and dyes from wastewater. It was also known that the rare earth elements in wastewater tend to be very diluted, and thus quite difficult to remove in a practical, inexpensive fashion.

http://www.gizmag.com/rare-earth-element-wastewater/29630/?li_source=LI&li_medium=default-widget

 

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Gold and other valuable metals may be harvested from sewage

 

 March 24, 2015

Mining operations tend not be very good for the environment, nor does the disposal of treated solid waste that still contains potentially-toxic metals. Now, however, scientists are looking into taking that waste and harvesting its trace amounts of metals such as gold, silver and platinum. Doing so could ultimately reduce the need for mining and decrease the amount of metals entering the environment, while also turning sewage into a source of revenue.

http://www.gizmag.com/metals-from-biosolids/36695/?li_source=LI&li_medium=default-widget


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Rare earths in bacteria: Methane-decomposing bacteria from hot springs need the valuable metals to produce energy

 

Date:

October 30, 2013

Source:

Max-Planck-Gesellschaft

Summary:

Rare earths are among the most precious raw materials of all. These metals are used in mobile telephones, display screens and computers. And they are apparently indispensable for some organisms as well. Scientists have discovered a bacterium which needs rare earths to grow -- in a hot spring.

 http://www.sciencedaily.com/releases/2013/10/131030125433.htm



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Engines of change: Scientists recover rare earths from electric and hybrid vehicle motors

 

Date:

September 30, 2015

Source:

Worcester Polytechnic Institute

Summary:

In an effort to help develop a domestic supply of rare earth elements, researchers at Worcester Polytechnic Institute have developed a novel method of chemically separating these materials -- specifically neodymium, dysprosium, and praseodymium -- from the drive units and motors of discarded electric and hybrid cars. The goal is to recycle rare earths that would otherwise be lost in a sustainable and efficient manner.

http://www.sciencedaily.com/releases/2015/09/150930140345.htm




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 Team creates the world's first formic acid-based fuel cell


March 20, 2018

https://phys.org/news/2018-03-team-world-formic-acid-based-fuel.html


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 Top Strongest Acids Ever


Aug 27, 2019

https://www.youtube.com/watch?v=h7-MzBAF4gY


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Chapter 28: Sustainable Lubricants

  
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Humidity may be the key to super-lubricity 'switch'

 

January 9, 2023

 

UNIVERSITY PARK, Pa. — Sometimes friction is good, such as the friction between a road and a car’s tires to prevent the vehicle from skidding. But sometimes friction is bad — if you did not put oil in that very same car, there would be so much friction in the bearings of the engine that the car could not operate. 

 

A material state known as super-lubricity, where friction between two contacting surfaces nearly vanishes, is a phenomenon that materials researchers have studied for years due to the potential for reducing the energy cost and wear and tear on devices, two major drawbacks of friction. However, there are times when friction is needed within the same device, and the ability to turn super-lubricity on and off would be a boon for multiple practical engineering applications.    

 

Seong Kim, distinguished professor of chemical engineering and associate head of the Department of Chemical Engineering at Penn State, and Zhe Chen, a researcher with the State Key Laboratory of Fluid Power and Mechatronic Systems and the Department of Mechanical Engineering at Zhejiang University, proposed in a study in Applied Materials Today that this super-lubricity switch may be found in humidity. Specifically, water vapor and vapor in phenol, which is a family of organic compounds.   

 

Super-lubricity is a key characteristic of certain two-dimensional (2D) materials, which consist of a single layer of atoms, especially graphene and molybdenum disulfide. Graphene is often used as a solid lubricant, in the form of a coating on various materials such as metals and plastics. With graphene, the atoms are oriented in a hexagonal manner, which forms this mountain-and-valley landscape, much like a supermarket egg crate.

https://www.psu.edu/news/materials-research-institute/story/humidity-may-be-key-super-lubricity-switch

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How Fluid Electrons: in Graphene Could Supercharge Future

October 28, 2024

 

New research into quantum materials like graphene shows that electrons can behave like viscous fluids, opening up possibilities for faster and more efficient electronic devices. This breakthrough has led to the development of devices such as the viscous electron bolometer, which could improve technologies from internet speeds to non-invasive medical scans. In high school science, we learned that connecting a cable to an electrical circuit starts a flow of electrons, providing power to everything from lights to phones.

 

Traditionally, we’ve understood electron behavior in metals and semiconductors using a simple model. In this view, electrons are like tiny, independent particles — similar to cars moving freely on an open highway, rarely interacting with each other. This straightforward model has long been the foundation of electronics, shaping how we design the devices that power modern life.

 

However, this traditional view doesn’t fully explain the behavior of electrons in certain emerging quantum materials, such as graphene — a highly conductive, ultrathin material. In graphene, electrons don’t move independently but instead flow collectively, resembling the movement of a viscous fluid, like oil.

 

This finding is more than just a quirky observation. It could be transformative for the future development of a broad range of technologies.

 
https://thenetizensreport.com/fluid-electrons-graphene/

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LiquiGlide poised to market superhydrophobic coating for wide range of products

 

Mar 25, 2015

http://phys.org/news/2015-03-liquiglide-poised-superhydrophobic-coating-wide.html

 
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Some question if there could be a way to make hydrophobic and superhydrophobic chemicals biodegrade naturally. 

 

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 Bacteria used to create superfluids
 
July 13, 2015

 A team of researchers with Université Paris-Sud and Université P.M. Curie/Université Paris-Diderot, both in France, has discovered that putting certain types of bacteria into an ordinary fluid, can cause it to become a superfluid. In their paper published in the journal Physical Review Letters, the team describes how they modified an old rheometer to conduct the tests, their readings and their ideas on why the bacteria caused a change in viscosity.


A fluid's viscosity is its state of thickness as can be demonstrated when it is poured out—water will run out much faster than oil, for example. Viscosity comes about due to friction among the ingredients that make up the fluid. Scientists have suspected for a number of years that bacteria in a fluid can cause a change in its viscosity, but until now, it has not been proven. To do so, the researchers pulled out a rheometer (a device used to measure viscosity) that was built several decades ago—they modified it to allow for connecting to a computer.

http://phys.org/news/2015-07-bacteria-superfluids.html

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Many tests still need to be done, to see how certain types of synthesized bacteria to create superfluids and how these superfluids will react and biodegrade in the wild.

Many people also want self lubricating devices that are non-toxic to the environment. Such as the properties of the wood called lignum vitae.

 

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Lignum vitae

 https://en.wikipedia.org/?title=Lignum_vitae

The wood is obtained chiefly from Guaiacum officinale and Guaiacum sanctum, both small, slow growing trees. All species of the genus Guaiacum are now listed in Appendix II of CITES (the Convention on International Trade in Endangered Species of Wild Fauna and Flora) as potentially endangered species. Demand for the wood has been reduced by modern materials science, which has led to polymer, alloys and composite materials that can take lignum vitae's place...


- "Lignum vitae" is Latin for "wood of life", and derives its name from its medicinal uses; lignum vitae resin has been used to treat a variety of medical conditions from coughs to arthritis, and chips of the wood can also be used to brew a tea.

Master clockmaker John Harrison used lignum vitae in the bearings and gears of his pendulum clocks and his first three marine chronometers (all of which were large clocks rather than watches), since the wood is self-lubricating. The use of lignum vitae eliminates the need for horological lubricating oil; 18th-century horological oil would get gummy and reduce the accuracy of a timepiece under unfavourable conditions (including those that prevail at sea).
For the same reason it was widely used in water-lubricated shaft bearings for ships and hydro-electric power plants, and in the stern-tube bearings of ship propellers until the 1960s saw the introduction of sealed white metal bearings. According to the San Francisco Maritime National Park Association website, the shaft bearings on the WWII submarine USS Pampanito (SS-383) were made of this wood. The aft main shaft strut bearings for USS Nautilus (SSN-571), the world's first nuclear-powered submarine, were composed of this wood. Also, the bearings in the original 1920s turbines of the Conowingo hydroelectric plant on the lower Susquehanna River were made from lignum vitae. The shaft bearings on the horizontal turbines at the Pointe du Bois generating station in Manitoba are made from lignum vitae. Other hydroelectric plant turbine bearings, many of them still in service, were fabricated with lignum vitae and are too numerous to list here.

 

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Greaseless ball bearings: A revolutionary spin on a design that's been around for ages

May 26, 2015

http://www.gizmag.com/greaseless-ball-bearings-coo-space-adb/37689/


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Controlling Surface Topography with Particle-Enhanced Soft Composites

 

June 11, 2015

An MIT team has developed a way of making soft materials, using a 3-D printer, with surface textures that can then be modified at will to be perfectly smooth, or ridged or bumpy, or even to have complex patterns that could be used to guide fluids.

http://scitechdaily.com/controlling-surface-topography-with-particle-enhanced-soft-composites/

 

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Graphene and diamonds prove a slippery combination

May 25, 2015

 Scientists at the U.S. Department of Energy's Argonne National Laboratory have found a way to use tiny diamonds and graphene to give friction the slip, creating a new material combination that demonstrates the rare phenomenon of "superlubricity."


 http://phys.org/news/2015-05-graphene-diamonds-slippery-combination.html#ajTabs




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Silicone grease is even being used for lubrication on firearms. Even greases that contain lithium and synthetic lithium have been used as greases. They even have different types of non-toxic lubricants, such as food grade lubricants for use on machines.

 

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Electrons and liquid helium advance understanding of zero-resistance

 

February 2, 2016

 

The end of Moore's Law, the prediction that transistor density would double every two years, was one of the hottest topics in electronics-related discussions in 2015. Silicon-based technologies have nearly reached the physical limits of the number and size of transistors that can be crammed into one chip, but alternative technologies are still far from mass implementation. The amount of heat generated during operation and the sizes of atoms and molecules in materials used in transistor manufacturing are some of problems that need to be solved for Moore's Law to persist.

Atomic and molecular sizes cannot be changed, but the heat problem is not unsolvable. Recent research has shown that in two-dimensional systems, including semiconductors, electrical resistance decreases and can reach almost zero when they are subjected to magnetic and microwave influence. Electrical resistance produces a loss of energy in the form of heat; therefore, a decrease in resistance reduces heat generation. There are several different models and explanations for the zero-resistance phenomenon in these systems. however, the scientific community has not reached an agreement on this matter because semiconductors used in electronics are complex and processes in them are difficult to model mathematically.

http://phys.org/news/2016-02-electrons-liquid-helium-advance-zero-resistance.html#nRlv

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Researchers demonstrate method that reduces friction between two surfaces to almost zero at macroscopic scale

 

May 15, 2015



As most people are aware, friction causes energy loss and wear and tear on mechanical parts—lubricants such as oil are used to help reduce friction and to dissipate heat, but scientists would really like to find a way to prevent it from happening in the first place. In this new effort, the researchers were studying friction properties at the nanoscale, where it is more about the attractive forces between atoms, than microscopic imperfections that are present at the macroscopic scale. They were testing an idea they had, that if one flat material was coated with graphene and another with a diamond-carbon mixture, there likely would be little friction when one was slid over the other.
 

http://phys.org/news/2015-05-method-friction-surfaces-macroscopic-scale.html#jCp


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Researchers create fatigue-free, stretchable conductor

 

September 21, 2015

Researchers have discovered a new stretchable, transparent conductor that can be folded or stretched and released, resulting in a large curvature or a significant strain, at least 10,000 times without showing signs of fatigue.

This is a crucial step in creating a new generation of foldable electronics - think a flat-screen television that can be rolled up for easy portability - and implantable medical devices. The work, published Monday in the Proceedings of the National Academy of Sciences, pairs gold nanomesh with a stretchable substrate made with polydimethylsiloxane, or PDMS.

 http://phys.org/news/2015-09-fatigue-free-stretchable-conductor.html#jCp


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Flexible foam made from algae

 

August 25, 2015

Algae is proving to be pretty darn useful – in recent years, it’s been used to produce oxygen, purify wastewater, provide light and serve as a source of biofuel. Now, bioplastics firm Algix and clean tech company Effekt are making flexible foam out of the stuff, too.

 http://www.gizmag.com/flexible-foam-made-from-algae/39102/?li_source=LI&li_medium=default-widget

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Researchers develop a library of elastin-like proteins to help in creating synthetic designs

 

September 23, 2015


A pair of researchers at Duke University has built a library of protein data that outlines the specific amino acid sequences that control changes of many elastin proteins. In their paper published in the journal Nature Materials, Felipe García Quiroz and Ashutosh Chilkoti describe their research, the making of their library, and their belief that what they have created will help in the development of new synthetic designs for possible use in medical applications.


Proteins are organic compounds essential to all living organisms, they are especially prevalent in components that have structure, such as muscle, skin, hair, etc. They provide structure by self-forming into different shapes under different conditions, two of which are solubility and temperature. Proteins are made of sequences of amino acids—the order and type of which drive the shape of the protein when certain conditions are met. Scientists still do not quite understand how proteins self assemble into the specific 3D shapes they take, nor which amino acids lead to which shapes, or indeed, how the order in which they exist contributes to those shapes.

 http://phys.org/news/2015-09-library-elastin-like-proteins-synthetic.html#jCp

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Scientists Unveil Safer Way To Make “Miracle Material” MXene

 

April 16, 2025

 

Researchers at TU Wien have developed a safer, non-toxic electrochemical method to produce MXenes, remarkable 2D materials with applications in energy storage, sensors, and solid lubrication. This breakthrough eliminates the need for hazardous hydrofluoric acid, potentially enabling industrial-scale production...

https://scitechdaily.com/scientists-unveil-safer-way-to-make-miracle-material-mxene/

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New technology could mean better chemical analysis on earth and in space

 

September 24, 2015

A new lightweight, energy-efficient tool for analyzing a material's chemical makeup could improve the detection abilities of various technologies, ranging from bomb-detecting drones to space rovers searching for signs of life, says a Texas A&M University biomedical engineer who is part of the team developing the instrument.

 http://phys.org/news/2015-09-technology-chemical-analysis-earth-space.html#jCp

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Scientists turn table salt into forbidden compounds that violate textbook rules

 

January 20, 2014

 http://www.gizmag.com/scientists-create-forbidden-compounds-table-salt/30520/?li_source=LI&li_medium=default-widget

In the field of exotic new materials, we've examined one of the strongest ones and another declared to be impossible; scientists now report creating "forbidden" materials out of ordinary table salt that violate classical rules of chemistry. Not only does the development challenge the theoretical foundation of chemistry, but it is also expected to lead to the discovery of new exotic chemical compounds with practical uses and shed light on the deep interiors of planets.
The international team of researchers led by Artem R. Oganov, a Professor of Crystallography at Stony Brook University, predicted that taking table salt and subjecting it to high pressure in the presence of an excess of one of its constituents (either chlorine or sodium) would lead to the formation of totally unexpected compounds. In spite of salt being one of the most thoroughly studied chemical compounds out there, the researchers predicted the formation of compounds forbidden by classical chemistry, such as Na3Cl and NaCl3. Their predictions were proven by subsequent experiments.
"Sodium has one electron in its outermost shell, and chlorine has seven," Weiwei Zhang, the lead author, a Professor of Physics at China Agricultural University and visiting scholar at Oganov's lab, tells Gizmag. "When sodium meets chlorine, sodium would like to give away an electron and chlorine wants to take one according to the Octet rule. Since one Na can supply only one electron to one Cl, the only possible combination of these atoms in a compound is 1:1, rocksalt NaCl. Take NaCl3 as an example, when you try to satisfy three Cl by one Na, there is no way to distribute electrons according to this rule. So NaCl3 is forbidden in the classical frame of chemistry..."


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Carnivorous plant inspires new super-slippery material

 

September 23, 2011

Who doesn't like carnivorous plants? They eat pesky bugs, they look like something out of Flash Gordon, and now it turns out that one of them has inspired a new type of liquid-repellent surface. The inspirational flora is the pitcher plant, which is shaped like - well, like a water pitcher, or perhaps a wide-end-up trumpet. When insects step onto its slippery inner surface, they lose their footing and fall down into a pool of collected rainwater in its base, where they are digested. Scientists from Harvard University's School of Engineering and Applied Sciences (SEAS) have copied the structure of that inner surface and come up with a material that resists not only most liquids, but also ice and bacteria, and it does so under a wide range of conditions.

 http://www.gizmag.com/pitcher-plant-slippery-surface/19935/

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Materials scientists create highly water repellant ceramics (w/ video)

 

January 21, 2013

Researchers at MIT have created several new types of ceramics that all demonstrate a high degree of liquid repellency. All are based, they write in their paper published in the journal Nature Materials, on the oxides of the lanthanides, and unlike most ceramics are extremely hydrophobic.
 

http://phys.org/news/2013-01-materials-scientists-highly-repellant-ceramics.html#nRlv

 
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New material is super water-resistant, cheap and safe

 

December 16, 2015

Scientists at Rice University, the University of Swansea, the University of Bristol and the University of Nice - Sophia Antipolis have developed a new class of hydrocarbon-based material that they say could be "greener" substitute for fluorocarbon-based materials currently used to repel water.
Rice chemist Andrew Barron led the research. He says the team took inspiration from the lotus leaf – one of the most hydrophobic (water-repelling) surfaces known – which is actually made up of a hierarchy of double structures on the microscopic and nano scales.

"In the lotus leaf, these [structures] are due to papillae within the epidermis and epicuticular waxes on top," he said. "In our material, there is a microstructure created by the agglomeration of alumina nanoparticles mimicking the papillae and the hyperbranched organic moieties simulating the effect of the epicuticular waxes."

http://www.gizmag.com/cheap-nontoxic-super-hydrophobic-coating-rice/40923/


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Hydrophobic Coating Inspired by Water Ferns Could Make Ships Consume 10 Percent Less

  

May 5, 2010


http://www.greenoptimistic.com/water-fern-fuel-efficient-ships-20100505/#.VSX0jpO-2zk


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Tear-inspired material can be tuned to repel or attract water

  

April 12, 2013

http://www.gizmag.com/hydrophobic-hydrophilic-material/27051/

Last year, a group of Harvard University scientists led by Dr. Joanna Aizenberg announced the development of a highly-hydrophobic (water-repellant) material known as SLIPS, or Slippery Liquid Porous Surfaces. The material is remarkable, in that it repels virtually any liquid. Now, Aizenberg and colleagues have created a new material inspired by human tears, the repellency of which can be fine-tuned for different applications.
Like SLIPS, the new material consists of a substrate infused with a continuous liquid film – just like the human eye is covered with a film of tears. Whereas SLIPS has a rigid substrate, however, the substrate of the new material is elastic.


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Magnetic microhair material can change transparency, and make water flow uphill

 

August 8, 2014

 

 

What if your house's windows could automatically reduce the amount of hot sunlight passing through them, or your car's windshield could cause rain droplets to bead off to its edges? These things and more could soon be possible, thanks to a new animal hair-inspired material developed at MIT.
The material consists of a base layer of transparent flexible silicone, studded with a dense array of tiny nickel microhairs (or "micropillars"). At around 70 microns in height and 25 microns in width, each one is approximately a quarter the diameter of a human hair.
When an external magnetic field is applied at one side of the array, all of the hairs simultaneously bend towards it. The degree to which they bend can be controlled by varying the intensity of the field.

http://www.gizmag.com/magnetic-microhair-material/33291/



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Chapter 29: Displays



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____________________________________

Graphene champions the next generation 3D display technology

 

Apr 23, 2015

Moving holograms like those used in 3D science fiction movies such as Avatar and Elysium have to date only been seen in their full glory by viewers wearing special glasses.

Now researchers at Swinburne University of Technology have shown the capacity of a technique using graphene oxide and complex laser physics to create a pop-up floating display without the need for 3D glasses.


Read more at: http://phys.org/news/2015-04-graphene-champions-3d-technology.html#jCp



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A new and efficient way to create nanographene for power and display devices

November 11, 2020

https://sciencebulletin.org/a-new-and-efficient-way-to-create-nanographene-for-power-and-display-devices/

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Multicolor meta-hologram produces light across entire visible spectrum

 

May 04, 2015 

 

 There are many different ways to generate a hologram, each with its own advantages and disadvantages. Trying to maximize the advantages, researchers in a new study have designed a hologram made of a metamaterial consisting of aluminum nanorods that can produce light across the entire visible spectrum, and do so in a way that yields brighter images than other methods.

 http://phys.org/news/2015-05-multicolor-meta-hologram-entire-visible-spectrum.html?utm_source=menu&utm_medium=link&utm_campaign=item-menu



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Tiny motions bring digital doubles to life (w/ Video)

December 7, 2014

 

Researchers at the Max Planck Institute for Intelligent Systems unveil new technology for motion and shape capture (MoSh) that helps animators jump the "Uncanny Valley" by turning a few moving dots into detailed body shapes that jiggle and deform like real humans.

http://phys.org/news/2014-12-tiny-motions-digital-life.html

 
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Researchers develop molecular backbone of super-slim, bendable digital displays

 

Mar 30, 2015 

 

From smartphones and tablets to computer monitors and interactive TV screens, electronic displays are everywhere. As the demand for instant, constant communication grows, so too does the urgency for more convenient portable devices—especially devices, like computer displays, that can be easily rolled up and put away, rather than requiring a flat surface for storage and transportation.

Read more at: http://phys.org/news/2015-03-molecular-backbone-super-slim-bendable-digital.html#jCp

 From smartphones and tablets to computer monitors and interactive TV screens, electronic displays are everywhere. As the demand for instant, constant communication grows, so too does the urgency for more convenient portable devices—especially devices, like computer displays, that can be easily rolled up and put away, rather than requiring a flat surface for storage and transportation.

 

http://phys.org/news/2015-03-molecular-backbone-super-slim-bendable-digital.html?utm_source=menu&utm_medium=link&utm_campaign=item-menu

 

 

____________________________________

 

Graphene used to create world's thinnest light bulb

June 15, 2015

 http://www.gizmag.com/graphene-thinnest-incandescent-lightbulb/38024/

 

____________________________________

 


 Ultrathin lens could revolutionise next-gen devices

September 23, 2015

http://phys.org/news/2015-09-ultrathin-lens-revolutionise-next-gen-devices.html



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New electronic paper could make inexpensive electronic displays

Apr 21, 2015

http://phys.org/news/2015-04-electronic-paper-inexpensive.html?utm_source=menu&utm_medium=link&utm_campaign=item-menu


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New 3D printing technology creates stronger ceramics

January 4, 2016

http://www.gizmag.com/3d-printing-stronger-ceramics-hrl/41142/?li_source=LI&li_medium=default-widget

Researchers at HRL Laboratories have developed a 3D printing technology designed to overcome the limitations of working with traditional ceramic processing. The process includes a resin formulation that once printed can be fired and converted into a ceramic that is harder, stronger and more compatible with ultra-high temperatures.



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Eggshells could find use in ceramics production

 

February 27, 2014



According to the US Department of Agriculture, every year approximately 455,000 tons (412,769 tonnes) of discarded eggshells must be transported and disposed of in the US alone. Now, however, scientists at the University of Aveiro in Portugal have developed a method of using such eggshell waste in the production of ceramic goods.

Although the specifics of the technology are still under wraps, it involves incorporating crushed eggshells into a ceramic slurry which is subsequently processed "according to a specific protocol that includes a 3-cycle cooking phase." Samples of porous pavement made from the slurry exhibit desirable qualities such as porosity and water absorption, and are overall considered to be of sufficient quality to meet industry standards...
 

http://www.gizmag.com/eggshell-waste-ceramics/31003/?li_source=LI&li_medium=default-widget

____________________________________

Eggshells could be used to fight global warming

 

October 29, 2010 

 

Carbon capture and sequestration (CCS) is a hot area of research in the effort to fight global warming through the process of removing carbon from the atmosphere and ferreting it away within carbon soaking materials, a team from the University of Calcutta has found an unexpected (or should that be uneggspected) material that could trap carbon from the atmosphere in the form of eggshells. The team has demonstrated that the membrane that lines an eggshell can absorb almost seven times its own weight of carbon dioxide from the atmosphere, allowing the gas to be stored until environmentally friendly methods of disposing, or even using it, can be found.

http://www.gizmag.com/eggshells-to-fight-global-warming/16771/?li_source=LI&li_medium=default-widget



____________________________________

 

 Startup announces development of flexiramics—ceramics with paper-like properties

February 3, 2016

 Dutch startup Eurekite has announced on their web page that they have developed a new kind of ceramic, one that is both flexible and easily made at varying degrees of thickness. The company (affiliated with the University of Twente in the Netherlands) is initially marketing the new product as a replacement for traditional printed circuit board materials.

http://phys.org/news/2016-02-startup-flexiramicsceramics-paper-like-properties.html#jCp

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Making ceramics that bend without breaking

 

September 26, 2013

 

Ceramics are not known for their flexibility: they tend to crack under stress. But researchers from MIT and Singapore have just found a way around that problem—for very tiny objects, at least.

The team has developed a way of making minuscule ceramic objects that are not only flexible, but also have a "memory" for shape: When bent and then heated, they return to their original shapes. The surprising discovery is reported this week in the journal Science, in a paper by MIT graduate student Alan Lai, professor Christopher Schuh, and two collaborators in Singapore.

http://phys.org/news/2013-09-ceramics.html#nRlv

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Graphene optical lens a billionth of a meter thick breaks the diffraction limit

 

• January 31, 2016

With the development of photonic chips and nano-optics, the old ground glass lenses can't keep up in the race toward miniaturization. In the search for a suitable replacement, a team from the Swinburne University of Technology has developed a graphene microlens one billionth of a meter thick that can take sharper images of objects the size of a single bacterium and opens the door to improved mobile phones, nanosatellites, and computers.

http://www.gizmag.com/optical-lens-one-billionth-meter-thick/41588/?li_source=LI&li_medium=default-widget

 
____________________________________

 

Innovation in optoelectronic nanotechnology: MIT grows precise nano-LED arrays

 

2023-07-13

 

A new technique can produce perovskite nanocrystals exactly where they are needed, so this extremely delicate material can be integrated into nanoscale devices. MIT researchers have developed a breakthrough method to precisely grow halide perovskite nanocrystals, eliminating the need for disruptive manufacturing techniques. The technique could help develop nanoLEDs and other functional nanoscale devices with the potential for advances in optical communications, computing, and high-resolution display technologies.

 

A new platform at MIT enables researchers to "grow" halide peritectic nanocrystals and precisely control the position and size of each crystal to integrate them into nanoscale light-emitting diodes. The picture shows the light-emitting effect of the nanocrystal array. 

 

Halide perovskites are a class of materials that have attracted attention due to their excellent optoelectronic properties and potential applications in devices such as high-performance solar cells, light-emitting diodes, and lasers. 

 

These materials have been primarily used in thin-film or micrometer-sized device applications. Precise integration of these materials at the nanoscale could open up more extraordinary applications, such as on-chip light sources, photodetectors, and memristors. However, achieving such integration remains challenging because such delicate materials can be damaged by conventional fabrication and patterning techniques. 

 

To overcome this obstacle, MIT researchers have invented a technique that can grow individual halide perovskite nanocrystals on-site, exactly where they are needed, with precise control of location and size to within 50 nanometers. (A sheet of paper is 100,000 nanometers thick) The size of the nanocrystals can also be precisely controlled with this technique, which is important because size affects their properties. Because the material is grown locally with the desired features, there is no need for traditional photolithography patterning steps that can cause damage. 

 

 

 https://en.eeworld.com.cn/news/manufacture/eic645731.html

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Flexible graphene-based LED clears the way for flexible displays

 

February 2, 2015

Researchers from the University of Manchester and University of Sheffield have developed a new prototype semi-transparent, graphene-based LED device that could form the basis of flexible screens for use in the next-generation of mobile phones, tablets and televisions. The incredibly thin display was created using sandwiched "heterostructures", is only 10-40 atoms thick and emits a sheet of light across its entire surface.

 http://www.gizmag.com/graphene-led-display-flexible-electronics/35884/?li_source=LI&li_medium=default-widget

 
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UC Irvine physicists discover first transformable nano-scale electronic devices

 

April 20, 2023

 

Professor Javier Sanchez-Yamagishi and his team (including UCI Ph.D. students Andrew Barabas and Ian Sequeira, undergraduate student Yuhui Yang, and PostDoc Aaron Barajas-Aguilar) at the University of California, Irvine, have been featured in a UCI School of Physical Sciences article for their discovery of nano-scale devices that can change into different forms despite their solid states. 

 

From UCI News, “What we discovered is that for a particular set of materials, you can make nano-scale electronic devices that aren’t stuck together,” said Javier Sanchez-Yamagishi, "The parts can move, and so that allows us to modify the size and shape of a device after it’s been made.” In addition, these findings indicate that that "what was once thought to be fixed and static can be made flexible and dynamic" as Dr. Sanchez-Yamagishi adds.

 
https://www.physics.uci.edu/node/14595

 

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New flexible material can make any window 'smart'

 

August 22, 2016 

 

 http://phys.org/news/2016-08-flexible-material-window-smart.html

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Limpet's shell could inspire next-gen transparent displays

 

 February 27, 2015

The humble limpet has been receiving a lot of press lately, as scientists recently determined that the material from which its teeth are made is officially the world's strongest natural material. Now, an MIT/Harvard study suggests that a specific type of limpet's shell may hold the key to transparent displays that require no internal light source.

http://www.gizmag.com/limpet-shell-transparent-displays/36321/?li_source=LI&li_medium=default-widget


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Limpets sink their teeth into world's strongest natural material crown

 

February 18, 2015

Spider's silk has long been the strongest natural material known to man, prompting researchers to attempt to uncover its secrets so they can replicate its remarkable properties in man-made materials. But scientists now have a new source of inspiration in the form of limpet teeth, which are made of a material researchers say is potentially stronger than spider silk, is comparable in strength to the strongest commercial carbon fibers, and could one day be copied for use in cars, boats and planes.


http://www.gizmag.com/limpet-teeth-strongest-natural-material/36162/

 

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High-Performance Nanodiamonds for Advanced Bioimaging and Quantum Sensing

 

December 25, 2024

 

Researchers achieved a breakthrough in nanodiamond sensors with quantum-grade spin properties, ideal for bioimaging and biosensing. These advanced sensors promise transformative applications in medicine and energy technologies.

 

Quantum sensing is an emerging field that harnesses the unique quantum properties of particles — such as superposition, entanglement, and spin states — to detect changes in physical, chemical, or biological environments. One promising tool in this field is nanodiamonds (NDs) embedded with nitrogen-vacancy (NV) centers. These NV centers are formed when a carbon atom in the diamond lattice is replaced by nitrogen near a vacancy. When illuminated, the NV centers emit photons that preserve stable spin information and respond to external factors such as magnetic fields, electric fields, and temperature.

 

By using a technique called optically detected magnetic resonance (ODMR), scientists can measure fluorescence changes in the NV centers under microwave radiation, revealing subtle shifts in spin states. Biocompatible and customizable, NDs with NV centers can be engineered to interact with specific biological molecules, making them valuable tools for sensing within biological systems. However, compared to bulk diamonds, NDs used in bioimaging often have lower spin quality, which limits their sensitivity and accuracy in detecting changes.

https://scitechdaily.com/high-performance-nanodiamonds-for-advanced-bioimaging-and-quantum-sensing/

 

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New research points the way to biodegradable displays

 

October 21, 2015

Electronic waste is a huge environmental problem, causing harm to the planet and human health because of the toxic materials used. While this situation is unlikely to change in the near future, there has been research on using materials that biodegrade. More recently, scientists have demonstrated a new route to creating biodegradable electronics by using organic components in screen displays.

http://www.gizmag.com/biodegradable-displays-electronic-waste-reduction/39895/


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Kekulé's shattered dream: snakes become ladders

 

November 2021

 

The Universities of Bonn and Regensburg create novel molecules that serve as ziplines for energy

 

Researchers from the Universities of Bonn and Regensburg move packets of energy along a molecular ladder made of hundreds of benzene rings. Such polymers can potentially be used to design new displays based on organic light-emitting diodes, or for solar cells. The extraordinary material is now described in the journal Nature Communications.

https://www.uni-bonn.de/en/news/286-2021

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One of the World's Most Precise Microchip Sensors – Thanks to a Spiderweb

11/24/2021

https://www.powersystemsdesign.com/articles/one-of-the-worlds-most-precise-microchip-sensors-thanks-to-a-spiderweb/97/18487

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A lighter, smarter magnetoreceptive electronic skin

March 27, 2025

Imagine navigating a virtual reality with contact lenses or operating your smartphone underwater: This and more could soon be a reality thanks to innovative e-skins.

A research team led by the Helmholtz-Zentrum Dresden-Rossendorf (HZDR) has developed an electronic skin that detects and precisely tracks magnetic fields with a single global sensor. This artificial skin is not only light, transparent and permeable, but also mimics the interactions of real skin and the brain, as the team reports in the journal Nature Communications.

Originally developed for robotics, e-skins imitate the properties of real skin. They can give robots a sense of touch or replace lost senses in humans. Some can even detect chemical substances or magnetic fields. But the technology also has its limits. Highly functional e-skins are often impractical because they rely on extensive electronics and large batteries.

"Previous technologies have used numerous individual sensors and transistors to localize sources of a magnetic field, similar to touch sensors in a smartphone display. Our idea was to develop a more energy-efficient system that is more akin to our soft human skin and thus better suited for humans," says Denys Makarov from the Institute of Ion Beam Physics and Materials Research at HZDR.

https://techxplore.com/news/2025-03-lighter-smarter-magnetoreceptive-electronic-skin.html

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New Nanoplastic Paves the Way for Sustainable Street Lighting

March 19, 2025

A new study resulting from a collaboration between King Abdullah University of Science and Technology (KAUST) and King Abdulaziz City for Science and Technology (KACST) shows how nanomaterials can significantly reduce the carbon emissions of LED (light-emitting diode) streetlights. The research team estimates that by adopting this technology, the United States alone can reduce carbon dioxide emissions by more than one million metric tons.

https://techxplore.com/news/2025-03-nanoplastic-paves-sustainable-street.html 

 

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Luminescent wood could light up homes of the future

  

Nov 04, 2020

 

 (Nanowerk News) The right indoor lighting can help set the mood, from a soft romantic glow to bright, stimulating colors. But some materials used for lighting, such as plastics, are not eco-friendly.

Now, researchers reporting in ACS Nano ("Luminescent and Hydrophobic Wood Films as Optical Lighting Materials") have developed a bio-based, luminescent, water-resistant wood film that could someday be used as cover panels for lamps, displays and laser devices.

 

https://www.nanowerk.com/nanotechnology-news2/newsid=56545.php

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'Zero modification' emission layer can achieve high-performance perovskite LEDs

19 March 2025

https://techandsciencepost.com/news/tech/zero-modification-emission-layer-can-achieve-high-performance-perovskite-leds/

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10 nm New Electronic “Skin” Unveiled for Cooling-Free Night-Vision Glasses

April 23, 2025

https://engineeringness.com/10-nm-new-electronic-skin-unveiled-for-cooling-free-night-vision-glasses/


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Programmable Pixels Advance Infrared Light Applications

April 07, 2025

https://www.ece.cmu.edu/news-and-events/story/2025/04/programmable-pixels.html

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Infrared contact lenses allow people to see in the dark, even with their eyes closed

May 22, 2025

https://phys.org/news/2025-05-infrared-contact-lenses-people-dark.html

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Self-Glowing Quantum Sensor Detects Invisible Signals.

July 7, 2025

A revolutionary breakthrough in quantum technology has led to the creation of a self-glowing quantum sensor that can detect nearly invisible signals—without any external power source. This next-gen sensor is not just highly sensitive but also autonomous, glowing on its own to interact with and detect weak environmental signals such as magnetic fields, electromagnetic waves, and even biological activity.

https://technologicinnovation.com/2025/07/07/self-glowing-quantum-sensor-detects-hidden-signals/

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Scientists develop hydrogen sensor that could pave the way for safer, cleaner energy

March 7, 2025

https://hydrogen-central.com/scientists-develop-hydrogen-sensor-that-could-pave-the-way-for-safer-cleaner-energy/


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Nanodiamonds in water droplets boost quantum sensing precision

March 5, 2025 

Combine a garden-variety green laser, microwaves with roughly the energy of your wi-fi, and some diamond dust in drops of water, and what do you get? A precise chemical detection tool.

https://phys.org/news/2025-03-nanodiamonds-droplets-boost-quantum-precision.html

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Almond Shell Waste Powers Sustainable Graphene-Based Sensors

Jul 18 2025

https://www.azonano.com/news.aspx?newsID=41472

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A New, Highly Sensitive Chemical Sensor Uses Protein Nanowires

 

 May 13, 2020

 

 

 

Protein nanowires (light green) harvested from Geobacter (background) are sandwiched between electrodes (gold) to form bioelectronic sensor for detection of biomolecules (red).

 

UMass Amherst team introduces high-performing ‘green’ electronic sensor 

 

AMHERST, Mass. – Writing in the journal NanoResearch, a team at the University of Massachusetts Amherst reports this week that they have developed bioelectronic ammonia gas sensors that are among the most sensitive ever made. 

 

The sensor uses electric-charge-conducting protein nanowires derived from the bacterium Geobacter to provide biomaterials for electrical devices. More than 30 years ago, senior author and microbiologist Derek Lovley discovered Geobacter in river mud. The microbes grow hair-like protein filaments that work as nanoscale “wires” to transfer charges for their nourishment and to communicate with other bacteria.

 

First author and biomedical engineering doctoral student Alexander Smith, with his advisor Jun Yao and Lovley, say they designed this first sensor to measure ammonia because that gas is important to agriculture, the environment and biomedicine. For example, in humans, ammonia on the breath may signal disease, while in poultry farming, the gas must be closely monitored and controlled for bird health and comfort and to avoid feed imbalances and production losses.

https://www.umass.edu/news/article/new-highly-sensitive-chemical-sensor-uses

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Thin metal oxide films printed at room temperature can transform display tech

 

Aug 15, 2024

 

The films are transparent and highly conductive, thus valuable for applications such as touch screens and display technologies.

 

https://interestingengineering.com/innovation/metal-oxide-film-printed-room-temperature



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Light-Speed Advances: Graphene Nanoprocessing With a Femtosecond Laser

 

June 3, 2023

 

Researchers at Tohoku University used a femtosecond laser to successfully micro/nanofabricate graphene films, creating multi-point holes without damage and removing contaminants. The technique could replace traditional, more complex methods, offering potential advancements in quantum materials research and biosensor development. 

 
https://scitechdaily.com/light-speed-advances-graphene-nanoprocessing-with-a-femtosecond-laser/

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Memristors get the hues

 

22 April 2021

 

The memristor, in which an external electric field controls the formation and annihilation of conductive channels, has been described both as a missing electronic element and a memory and computational element. Here, their utility as building blocks for promising reflective and energy-efficient colour technology is described. 

https://www.nature.com/articles/s41565-021-00891-7

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Floating solid-state thin films with dynamic structural colour

 

22 April 2021

 

Abstract

 

Thin-film architectures are a staple in a wide range of technologies, such as semiconductor devices, optical coatings, magnetic recording, solar cells and batteries. Despite the industrial success of thin-film technology, mostly due to the easy fabrication and low cost, a fundamental drawback remains: it is challenging to alter the features of the film once fabricated. Here we report a methodology to modify the thickness and sequence of the innermost solid-state thin-film layers. We start with a thin-film stack of amorphous iron oxide and silver. By applying a suitable voltage bias and then reversing it, we can float the silver layer above or below the oxide layer by virtue of the migration of silver atoms. Scanning transmission electron microscopy reveals various sequences and thicknesses of the silver and oxide layers achieved with different experimental conditions. As a proof-of-principle, we show a dynamic change of structural colours of the stack derived from this process. Our results may offer opportunities to dynamically reconfigure thin-film-based functional nanodevices in situ.

 

https://www.nature.com/articles/s41565-021-00883-7 

 

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Novel Gel Proves Itself to Be Highly Tunable Color Filter

 

June 27, 2022

 

Neutron research at NIST reveals the secret to a gel’s unusual ability to precisely filter light.

 

Color these scientists happy. An exotic gel they studied at the National Institute of Standards and Technology (NIST) has an unexpected property: The material’s temperature determines which color of light can pass through it.

 

The material, which the research team calls “SeedGel,” already has shown promise as a multipurpose tool, with applications ranging from batteries to water filters to tissue engineering. The team’s new paper, appearing in Nature Communications, highlights the gel’s newfound capability as a temperature-sensitive light filter. Shine white light at the gel, and depending on the gel’s temperature, only a specific wavelength, or color, will pass through it. A temperature change of less than a tenth of a degree Celsius can be enough to alter the permitted wavelength, which can be any color in the visible range as well as parts of the ultraviolet and infrared. 

 

“Our previous work showed that the SeedGel can transform from clear to opaque and back again, but we did not explore what it can do with color,” said Yun Liu, who is both a scientist at the NIST Center for Neutron Research (NCNR) and a professor at the University of Delaware. “Its ability to control color precisely was a new discovery.” 

 

The team’s creation is distinct from others that may be familiar from the marketplace. Don’t confuse it with a mood ring, whose thermochromic liquid crystals change color with temperature. Neither is it a variation on photochromic sunglass lenses, which darken when exposed to ultraviolet rays. Instead, the gel functions as a temperature-sensitive gate for a particular wavelength of light.

 

Their gel begins as a transparent fluid made of water and liquid solvents with silica nanoparticles added. If this mix is heated to a certain temperature, the liquids and nanoparticles will form a physical gel that initially remains transparent but now possesses a different internal structure. Instead of a formless fluid, the liquids form interlocking microscopic channels, with the nanoparticles confined within one of them.

 

As it is heated through a specific range of higher temperatures, the newly discovered effect appears: The gel grows opaque to all but individual colors, at first allowing shorter, bluer wavelengths to pass through, then progressively longer, redder wavelengths. Eventually, once this temperature range is exceeded, the gel grows opaque to all visible light. 

 

"Our previous work showed that the SeedGel can transform from clear to opaque and back again, but ... its ability to control color precisely was a new discovery.” —Yun Liu, NCNR scientist and University of Delaware professor

 

Neutron scattering experiments performed at the NCNR explain this unusual behavior. Changing the temperature causes an exchange of liquid molecules between the microscopic channels, altering the overall refractive index of these channels. One wavelength of light gets through, but other colors get scattered.

 

https://www.nist.gov/news-events/news/2022/06/novel-gel-proves-itself-be-highly-tunable-color-filter

 

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Revolutionizing Displays: Dual-Mode Electrochemical Devices Merge Light and Color

February 5, 2025

 

Researchers introduce an innovative device that combines light emission and color control with clay compounds, offering a versatile solution for multifunctional displays.

 

The field of display technology is on the verge of a major breakthrough, driven by the growing interest in electrochemical stimuli-responsive materials. These materials can undergo rapid electrochemical reactions in response to external stimuli, such as low voltage.

 

A key advantage of these reactions is their ability to produce different colors almost instantly, paving the way for next-generation display solutions. An electrochemical system consists of electrodes and electrolytes, and researchers have found that integrating luminescent and coloration molecules directly onto the electrodes—rather than within the electrolyte—can significantly enhance efficiency and stability in display devices.

 
https://scitechdaily.com/revolutionizing-displays-dual-mode-electrochemical-devices-merge-light-and-color/


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Deep-UV Laser Breakthrough Is Transforming the Future of Diamond Tech

January 26, 2025

 

Researchers have built a deep-ultraviolet microscope to study hard-to-analyze materials like diamond, offering a new way to probe their electronic and thermal properties at the nanoscale.

 

This innovation, sparked by an industry challenge, creates nanoscale heat patterns using high-energy laser light, revealing transport behaviors critical for advanced electronics.

 
https://scitechdaily.com/deep-uv-laser-breakthrough-is-transforming-the-future-of-diamond-tech/

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Self-powered artificial synapse mimics human color vision

 

June 2, 2025

Despite advances in machine vision, processing visual data requires substantial computing resources and energy, limiting deployment in edge devices. Now, researchers from Japan have developed a self-powered artificial synapse that distinguishes colors with high resolution across the visible spectrum, approaching human eye capabilities. The device, which integrates dye-sensitized solar cells, generates its electricity and can perform complex logic operations without additional circuitry, paving the way for capable computer vision systems integrated in everyday devices. 

 

https://www.sciencedaily.com/releases/2025/06/250602155323.htm

 

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New “Electric Eye” Neuromorphic Artificial Vision Device Developed Using Nanotechnology

  

April 20, 2022

 

Using nanotechnology, scientists have created a newly designed neuromorphic electronic device that endows microrobotics with colorful vision. 

https://scitechdaily.com/new-electric-eye-neuromorphic-artificial-vision-device-developed-using-nanotechnology/

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Ultra-thin lenses that make infrared light visible

 

June 2, 2025

 

Physicists have developed a lens with 'magic' properties. Ultra-thin, it can transform infrared light into visible light by halving the wavelength of incident light.

https://www.sciencedaily.com/releases/2025/06/250602155511.htm

 

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Ordinary Microscope Sees in Super-Resolution With Specially Engineered Light-Shrinking Material

 

June 1, 2021

 

 

This light-shrinking material turns a conventional light microscope into a super-resolution microscope. 

 

New material boosts standard microscopes to image live cells at 40-nm resolution, with 3D capabilities underway.

 

Electrical engineers at the University of California San Diego developed a technology that improves the resolution of an ordinary light microscope so that it can be used to directly observe finer structures and details in living cells.

 

The technology turns a conventional light microscope into what’s called a super-resolution microscope. It involves a specially engineered material that shortens the wavelength of light as it illuminates the sample — this shrunken light is what essentially enables the microscope to image in higher resolution.

 

https://scitechdaily.com/ordinary-microscope-sees-in-super-resolution-with-specially-engineered-light-shrinking-material/

 

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“Magic wand” reveals a colorful nano-world

 

 November 23, 2021

 

Novel color photography using a high-efficiency probe can super-focus white light into a 6-nanometer spot for nanoscale color imaging

 

Scientists have developed new materials for next-generation electronics so tiny that they are not only indistinguishable when closely packed, but they also don’t reflect enough light to show fine details, such as colors, with even the most powerful optical microscopes. Under an optical microscope, carbon nanotubes, for example, look grayish. The inability to distinguish fine details and differences between individual pieces of nanomaterials makes it hard for scientists to study their unique properties and discover ways to perfect them for industrial use.

 

In a new report in Nature Communications, researchers from UC Riverside describe a revolutionary imaging technology that compresses lamp light into a nanometer-sized spot. It holds that light at the end of a silver nanowire like a Hogwarts student practicing the “Lumos” spell, and uses it to reveal previously invisible details, including colors. 

 

The advance, improving color-imaging resolution to an unprecedented 6 nanometer level, will help scientists see nanomaterials in enough detail to make them more useful in electronics and other applications.

https://news.ucr.edu/articles/2021/11/23/magic-wand-reveals-colorful-nano-world

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Mind-Controlled Robots: New Graphene Sensors Are Turning Science Fiction Into Reality

 

April 4, 2023

 

New 3D Graphene Dry Sensors Bring Brain-Controlled Robotics Closer to Reality

 

Researchers have designed a 3D-patterned, graphene-based, dry sensor that can measure the brain’s electrical activity without relying on conductive gels. The dry sensors are less irritating and allergenic compared to traditional “wet” sensors used in electroencephalography (EEG) to diagnose neurological disorders or control external devices through brain-machine interfaces. When incorporated into an elastic headband and used with an augmented reality headset, the dry sensors enabled hands-free control of a robot by interpreting brain signals. Although not as effective as wet sensors yet, this development marks progress toward easily implemented, non-invasive brain-machine interfaces.

 

https://scitechdaily.com/mind-controlled-robots-new-graphene-sensors-are-turning-science-fiction-into-reality/

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Electrically Switchable Nanoantennas Enable Dynamic Holographic Tech

 

December 28, 2021

 

https://www.electronicsforu.com/special/editor-choice/electrically-switchable-nanoantennas-enable-dynamic-holographic-tech

 

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10,000x Smaller: Tiny Nano-Antenna Could Revolutionize Wireless Tech

Mar 1 2025


https://lifeboat.com/blog/2025/03/10000x-smaller-tiny-nano-antenna-could-revolutionize-wireless-tech

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The shape-shifting of things to come

 

October 2, 2019 

 

What would it take to transform a flat sheet into a human face? How would the sheet need to grow and shrink to form eyes that are concave, a nose that’s convex, and a chin that protrudes?

 

How to encode and release complex curves in shape-shifting structures is at the center of research led by the Harvard John A. Paulson School of Engineering and Applied Sciences (SEAS) and the Harvard Wyss Institute of Biologically Inspired Engineering.

 

Over the past decade, theorists and experimentalists have found inspiration in nature as they sought to unravel the physics, build mathematical frameworks, and develop materials and 3D- and 4D-printing techniques for structures that can change shape in response to external stimuli.

 

However, complex multiscale curvature has remained out of reach.

 

Now, researchers have created the most complex shape-shifting structures to date — lattices composed of multiple materials that grow or shrink in response to changes in temperature. To demonstrate their technique, the research team printed flat lattices that morph into a frequency-shifting antenna or the face of pioneering mathematician Carl Friedrich Gauss.

 

https://news.harvard.edu/gazette/story/2019/10/shape-shifting-structures-can-take-the-form-of-a-face-antenna/

 

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Cambridge Scientists Develop Ultra-Thin Quantum Sensor for Nanoscale Magnetic Imaging

May 29 2025

 

 A team of physicists at the University of Cambridge has made a major advance in quantum sensing, demonstrating that spin defects in hexagonal boron nitride (hBN) can function as highly sensitive, room-temperature sensors capable of detecting vectorial magnetic fields at the nanoscale.

 

https://www.azosensors.com/news.aspx?newsID=16477

 

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Nobel Prize in Chemistry 2023 spotlights quantum dot pioneers

 

Oct 04, 2023 

 

(Nanowerk News) The Nobel Prize in Chemistry 2023 rewards the discovery and development of quantum dots, nanoparticles so tiny that their size determines their properties. These smallest components of nanotechnology now spread their light from televisions and LED lamps, and can also guide surgeons when they remove tumour tissue, among many other things.

Everyone who studies chemistry learns that an element’s properties are governed by how many electrons it has. However, when matter shrinks to nano-dimensions quantum phenomena arise; these are governed by the size of the matter. The Nobel Laureates in Chemistry 2023 have succeeded in producing particles so small that their properties are determined by quantum phenomena. The particles, which are called quantum dots, are now of great importance in nanotechnology.

 

https://www.nanowerk.com/nanotechnology-news2/newsid=63768.php 

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Biofuel Cell: Wearable Device Turns the Touch of Finger Into a Source of Power

July 26, 2021

A new wearable device turns the touch of a finger into a source of power for small electronics and sensors. Engineers at the University of California San Diego developed a thin, flexible strip that can be worn on a fingertip and generate small amounts of electricity when a person’s finger sweats or presses on it.

What’s special about this sweat-fueled device is that it generates power even while the wearer is asleep or sitting still. This is potentially a big deal for the field of wearables because researchers have now figured out how to harness the energy that can be extracted from human sweat even when a person is not moving.

https://fuelcellsworks.com/news/biofuel-cell-wearable-device-turns-the-touch-of-a-finger-into-a-source-of-power

 

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Nanometer thin spacer boosts blue OLEDs portability and efficiency

 

June 26, 2025

https://phys.org/news/2025-06-nanometer-thin-spacer-boosts-blue.html

 

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New Diamond Magnetometer Paves the Way for GPS-Free Navigation

 

June 21, 2025 

 

https://scitechdaily.com/new-diamond-magnetometer-paves-the-way-for-gps-free-navigation/ 

 

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Chapter 30: Water harvesting & Carbon



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Atmospheric water generator

An atmospheric water generator (AWG), is a device that extracts water from humid ambient air. Water vapor in the air is condensed by cooling the air below its dew point, exposing the air to desiccants, or pressurizing the air. Unlike a dehumidifier, an AWG is designed to render the water potable. AWGs are useful where pure drinking water is difficult or impossible to obtain, because there is almost always a small amount of water in the air that can be extracted. The two primary techniques in use are cooling and desiccants.

The extraction of atmospheric water may not be completely free of cost, because significant input of energy is required to drive some AWG processes. Certain traditional AWG methods are completely passive, relying on natural temperature differences, and requiring no external energy source. Research has also developed AWG technologies to produce useful yields of water at a reduced (but non-zero) energy cost.

See also

• Air well (condenser)
• Dew pond
• Fog collection
• Rainwater harvesting
• Solar chimney
• Watermaker
• Solar still
• Water-Gen

http://en.wikipedia.org/wiki/Atmospheric_water_generator

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New desalination technology could answer state drought woes

 

Feb 18, 2015

 

Could desalination be the answer to California's drought? As parts of the state become drier, scientists are looking at ways to turn seawater into drinkable wateDesalination has made headlines in recent months as a possible solution to the state's water shortage. But in addition to being expensive, its byproduct—salty brine—can harm marine life once it's reintroduced into the ocean.

A team of researchers from Humboldt State University and the University of Southern California is hoping to address those concerns with a new process called Reverse Osmosis-Pressure Retarded Osmosis (RO-PRO)...

http://phys.org/news/2015-02-desalination-technology-state-drought-woes.html#jCp

 

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Solar-powered system offers a route to inexpensive desalination

 

February 14, 2022

 

Passive solar evaporation system could be used to clean wastewater, provide potable water, or sterilize medical tools in off-grid areas.

https://news.mit.edu/2022/solar-desalination-system-inexpensive-0214

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Improved desalination process also removes toxic metals to produce clean water

 

April 16, 2021

 

University of California, Berkeley, chemists in the labs of Professor of Chemistry and Chemical and Biomolecular Engineering Jeffrey Long and Facility Director, Inorganic Nanostructures at the Molecular Boundary Jeffrey Urban(link is external) have discovered a way to simplify the removal of toxic metals, like mercury and boron, during desalination to produce clean water, while at the same time potentially capturing valuable metals, such as gold.

 

Desalination — the removal of salt — is only one step in the process of producing drinkable water, or water for agriculture or industry, from ocean or waste water. Either before or after the removal of salt, the water often has to be treated to remove boron, which is toxic to plants, and heavy metals like arsenic and mercury, which are toxic to humans. Often, the process leaves behind a toxic brine that can be difficult to dispose of.

 

The new technique, which can easily be added to current membrane-based electrodialysis desalination processes, removes nearly 100% of these toxic metals, producing a pure brine along with pure water and isolating the valuable metals for later use or disposal.

https://chemistry.berkeley.edu/news/improved-desalination-process-also-removes-toxic-metals-produce-clean-water

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New desalination technique pushes salt to one side with shockwaves

  

November 13, 2015
 

http://www.gizmag.com/shock-electrodialysis-desalination/40384/

 As access to clean water continues to be an issue throughout the developing world, there's an increased demand for easier ways to turn contaminated and salty water into something you can drink. Researchers at MIT may have found a solution using a method they are calling shock electrodialysis. It uses electric shock waves to separate contaminated or salty water into two separate streams, with a natural barrier between each one.

 

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This self-filling water bottle is the ultimate in vaporware

 

January 28, 2016

Austrian startup Fontus is developing a novel water bottle that is vaporware in just about every sense of the phrase. Not only does it not yet exist in the marketplace, but it is claimed to literally pull water vapor out of the air to fill itself.

 http://www.gizmag.com/fontus-airo-ryde-self-filling-water-bottle/41545/?li_source=LI&li_medium=default-widget

 
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Nanomaterial Collects Natural Atmospheric Humidity and Produces Electrical Signals

Aug 7 2023

 

https://www.azonano.com/news.aspx?newsID=40353

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Sponge creates steam using ambient sunlight

 

August 22, 2016

http://phys.org/news/2016-08-bubble-wrapped-sponge-steam-sunlight.html

 

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Smart spongy device captures water from thin air

May 7, 2025 

https://techxplore.com/news/2025-05-smart-spongy-device-captures-thin.html

 

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Researchers harness machine learning to discover membranes that remove ‘forever chemicals’ from drinking water

February 17, 2025

https://engineering.wisc.edu/news/researchers-harness-machine-learning-to-discover-membranes-that-remove-forever-chemicals-from-drinking-water/

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Tiny device grabs more solar energy to disinfect water faster

 

August 15, 2016

 

http://phys.org/news/2016-08-tiny-device-solar-energy-disinfect.html?utm_source=menu&utm_medium=link&utm_campaign=item-menu

 
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Harvesting the sun's energy for clean drinking water

 

Dec 11, 2020

 

Without drinkable water there is no life. Yet, nearly 1.1 billion people worldwide lack access to fresh water and another 2.4 billion suffer from diseases borne by unclean drinking water. This is because while science has yielded advanced water treatment methods such as membrane distillation and reverse osmosis, these are often difficult to implement in developing countries owing to their high cost and low productivity.

 

A more nascent technology shows promise as an alternative for such regions of the world: direct solar steam generation (DSSG). DSSG involves harvesting the heat from the sun to convert water into vapor, thereby desalinating it or ridding it of other soluble impurities. The vapor is then cooled and collected as clean water for use.

 

This is a simple technology, but a key step, evaporation, is presenting roadblocks for its commercialization. With existing technology, evaporation performance has hit the theoretical limit. However, this is not sufficient for practical implementation. Measures to improve device design to minimize solar heat loss before it reaches bulk water, recycle latent heat in the water, absorb and utilize energy from the surroundings as well, and so on, have been taken to improve the evaporation performance beyond the theoretical limit and make this technology viable.

https://www.solardaily.com/reports/Harvesting_the_suns_energy_for_clean_drinking_water_999.html

 

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MIT engineers unveil origami-inspired device that pulls clean drinking water out of thin air: 'A promising solution' (Controversial)

 

July 29, 2025

 

"This is just a proof-of-concept design, and there are a lot of things we can optimize."

 

https://www.thecooldown.com/green-tech/drinking-water-air-mit-device/

 

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Engineers Develop New System to Provide Low-Cost Drinking Water

 

June 11, 2018

 
https://scitechdaily.com/engineers-develop-new-system-to-provide-low-cost-drinking-water/

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New 2-D Catalyst Fits Two Co-Catalysts on a single Nanosheet for much better Water Purification

 

January 22, 2022

 

Scientists fit two co-catalysts on one nanosheet for better water purification. Scientists have designed and tested a new two-dimensional (2-D) catalyst that can be used to improve water purification using hydrogen peroxide.

 

“Many processes need two reactions in one. This means that you need two co-catalysts. However, the challenge is that the two co-catalysts have to stay separated, otherwise they’ll interact with each other and create a negative effect on the efficiency of the whole process,” said Eli Stavitski, a chemist and beamline scientist at NSLS-II.

 

https://science-atlas.com/technology/new-2-d-catalyst-fits-two-co-catalysts-on-a-single-nanosheet-for-much/

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3D nanotech blankets offer new path to clean drinking water

Mar 24, 2025

Researchers have developed a new material that, by harnessing the power of sunlight, can clear water of dangerous pollutants.  

Created through a combination of soft chemistry gels and electrospinning — a technique where electrical force is applied to liquid to craft small fibers — the team constructed thin fiber-like strips of titanium dioxide (TiO₂), a compound often utilized in solar cells, gas sensors and various self-cleaning technologies. 

Despite being a great alternative energy source, solar fuel systems that utilize TiO₂ nanoparticles are often power-limited because they can only undergo photocatalysis, or create chemical reactions, by absorbing non-visible UV light. This can cause significant challenges to implementation, including low efficiency and the need for complex filtration systems. 

Yet when researchers added copper to the material to improve this process, their new structures, called nanomats, were able to absorb enough light energy to break down harmful pollutants in air and water, said Pelagia-Iren Gouma, lead author of the study and a professor of materials science and engineering at The Ohio State University.

https://news.osu.edu/3d-nanotech-blankets-offer-new-path-to-clean-drinking-water/

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Sodium battery contains solution to water desalination

• February 4, 2016

 Much scientific effort goes into shoring up both our energy and water supplies for the future, but what if both problems could be addressed by the same technology? Researchers at the University of Illinois have come up with a new battery design that not only relies on salt water to store and release electricity, but removes the salt ions from the water in the process.
 

http://www.gizmag.com/sodium-battery-water-desalination/41683/?li_source=LI&li_medium=default-widget

 

---------------



Agenda 21 could restrict water resources in different ways.

The government would like to be able to tax rainwater.

Some governments would even try to ban the harvesting of rainwater, even for personal use.

Different governments would even try to ban or tax the collecting of water from atmospheric water generators.

Some people question the environmental impact of collecting moisture from the air, with millions of machines at a time collecting water near the high desert. We know that there is already very little moisture in the high desert.  Some machines can even make their own moisture, from the cold and condensation that is created by the energy from the machine. 

We also can have many options for sustainable groundwater. Recent droughts in different areas have caused  problems with trying to use water as a natural resource. 

 Others believe that maybe it is our job to protect the planet, including the regulation of the atmosphere, jungles, forests and deserts. It could be possible to avoid a catastrophic event, by balancing out the atmosphere on our planet. However, we can see news articles, including conferences, about people modifying the weather with lazers. Many people think that people, companies and governments could also abuse this type of technology as well.

 

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Device that harvests water from thin air wins the James Dyson Award

November 11, 2011
 

http://www.gizmag.com/airdrop-wins-james-dyson-award/20471/

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US scientists build solar water purifier that stores heat to work even after sunset

May 15, 2025

https://interestingengineering.com/innovation/solar-system-recycles-heat-to-produce-water

 

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Researchers create tiny pump that provides continuous and spontaneous antigravity water delivery

 

June 15, 2015

 To build their pump, the researchers created a superhydrophobic material by exposing a copper mesh to an alkali solution—the microscopic sized pockets it created caused water to slide with almost no friction. They then affixed the mesh to the bottom of a plastic tube that sat vertically. They next attached another tube to the first creating a right angle at the top and then attached a very short third tube to the second at its other end, this one pointing straight down. That was all it took. To use the pump, a bit of liquid was introduced into the pump, priming it, then a drop was introduced from beneath the pump, through the wire mesh. The liquid in the pump rose, because it was repelled from below, into the second tube and then into the third where it was expelled.

http://phys.org/news/2015-06-tiny-spontaneous-antigravity-delivery.html#jCp

 

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 Scientists create ‘magic’ material that pulls drinking water from thin air

23 June 2025

https://www.aumanufacturing.com.au/scientists-create-magic-material-that-pulls-drinking-water-from-thin-air

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Nanoscale control of internal inhomogeneity enhances water transport in desalination membranes

 

1 Jan 2021

 

Finding the path to better desalination

 

Polyamide membranes have been used in large-scale desalination for decades. However, because of the thinness of the membranes and their internal variability, it has been hard to determine which aspects of the membranes most affect their performance. Culp et al. combined electron tomography, nanoscale three-dimensional (3D) polyamide density mapping, and modeling of bulk water permeability with zero adjustable parameters to quantify the effect of 3D nanoscale variations in polymer mass on water transport within the polyamide membrane (see the Perspective by Geise). They found that variability in local density most affects the performance of the membranes. Better synthesis methods could thus improve performance without affecting selectivity.

https://scitechdaily.com/controlling-the-nanoscale-structure-of-desalination-membranes-is-key-for-clean-water/

 

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Device mimics the mangrove’s water-purifying power

 

Feb 21, 2020

 

The mangrove tree survives in its subtropical habitat by efficiently converting the salty water of its environment into fresh water — an engineering feat that has long baffled scientists.

 

Now, a team of researchers in the lab of Yale engineering professor Menachem Elimelech has developed a water-purifying device that mimics the mangrove. In addition to offering a better understanding of plants’ plumbing systems, it could lead to new desalination technologies, his research team said. The results appeared Feb. 21 in Science Advances.

 

https://news.yale.edu/2020/02/21/device-mimics-mangroves-water-purifying-power

 

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From batteries to water purifiers, carbon nanotubes are where it’s at

 

Oct. 24, 2022

 

Lawrence Livermore National Laboratory (LLNL) scientists are scaling up the production of vertically aligned single-walled carbon nanotubes (SWCNT) that could revolutionize diverse commercial products ranging from rechargeable batteries, automotive parts and sporting goods to boat hulls and water filters.  

 
https://www.llnl.gov/article/49156/batteries-water-purifiers-carbon-nanotubes-are-where-its

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Experiments reveal water can "talk" to electrons in graphene

 

26 June 2023

 

For the last 20 years, scientists have been puzzled by how water behaves near carbon surfaces. It may flow much faster than expected from conventional flow theories or form strange arrangements such as square ice. Now, an international team of researchers from The University of Manchester, the Max Planck Institute for Polymer Research of Mainz (Germany), and the Catalan Institute of Nanoscience and Nanotechnology (ICN2, Spain), reports in a study published recently in Nature Nanotechnology that water can interact directly with the carbon’s electrons: a quantum phenomenon that is very unusual in fluid dynamics. The results of this research could lead to applications in water purification and desalination processes and maybe even to liquid-based computers.  

https://scitechdaily.com/scientists-reveal-that-water-can-talk-to-electrons-in-graphene/

 

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MIT Engineers Find a Way To Save Energy and Make Water Boil More Efficiently

 

July 17, 2022 

 

 

MIT engineers design new surface treatments that make water boil more efficiently. 

 

Microscale Cavities and Nanostructures Improve Boiling Efficiency

 

Adding a series of microscale cavities, or dents, to a surface is a way of controlling the way bubbles form on that surface, keeping them effectively pinned to the locations of the dents and preventing them from spreading out into a heat-resisting film. In this work, the researchers created an array of 10-micrometer-wide dents separated by about 2 millimeters to prevent film formation. But that separation also reduces the concentration of bubbles at the surface, which can reduce the boiling efficiency. To compensate for that, the team introduced a much smaller-scale surface treatment, creating tiny bumps and ridges at the nanometer scale, which increases the surface area and promotes the rate of evaporation under the bubbles.

 

In these experiments, the cavities were made in the centers of a series of pillars on the material’s surface. These pillars, combined with nanostructures, promote wicking of liquid from the base to their tops, and this enhances the boiling process by providing more surface area exposed to the water. In combination, the three “tiers” of the surface texture — the cavity separation, the posts, and the nanoscale texturing — provide a greatly enhanced efficiency for the boiling process, Song says.

 

“Those micro cavities define the position where bubbles come up,” he says. “But by separating those cavities by 2 millimeters, we separate the bubbles and minimize the coalescence of bubbles.” At the same time, the nanostructures promote evaporation under the bubbles, and the capillary action induced by the pillars supplies liquid to the bubble base. That maintains a layer of liquid water between the boiling surface and the bubbles of vapor, which enhances the maximum heat flux.

 

 

The key to the new surface treatment is to add textures at several different size scales. Electron microscope images show millimeter-scale pillars and dents(first two images), whose surfaces are covered with tiny nanometer-scale ridges (bottom two images) to improve the efficiency of the boiling reaction. 

https://scitechdaily.com/mit-engineers-find-a-way-to-save-energy-and-make-water-boil-more-efficiently/

 

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Chapter 31: Refrigeration

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We have the technology to create sustainable refrigeration with new technology that can replace antifreeze. 

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Triton: advances in dilution refrigerator technology for quantum info processing

 

In this webinar Prof. Charles Marcus presents an overview of his work using the Triton dilution refrigerator at the Niels Bohr Institute’s Center for Quantum Devices, University of Copenhagen. He reviews the latest advances in dilution refrigerator technology for QIP, specifically focusing on the integration of high-density RF interconnects.
The scaling of single- or few-electron spin-qubit devices to multi-qubit architectures presents a challenge to cryogenic technology. Particularly demanding is the integration of large numbers of RF interconnects to samples operating at millikelvin temperatures in high magnetic fields within physical space, heat load and electrical noise limits. With its advanced sample loading, integrated magnet solutions and quantum information processing (QIP)-specific wiring options, the Triton dilution refrigerator has been adopted as the system of choice for studies in this exciting area of emerging technology.


http://connect.physicsworld.com/triton-advances-in-dilution-refrigerator-technology-for-quantum-info-processing/2001160.article

 

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The quantum fridge

February 1, 2016

 When cold milk is poured into a hot cup of tea, a temperature equilibrium is reached very quickly. The milk droplets and the tea particles interact, and after a few moments they all have the same average energy. This process is called thermalization. It plays a crucial role in cooling down gases to ultra-low temperatures. But surprisingly, even gases for which this effect is suppressed can be cooled. Scientists at TU Wien (Vienna) took a closer look at this phenomenon and found a special quantum-mechanical kind of cooling at work.

http://phys.org/news/2016-02-quantum-fridge.html

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Solar Cooling System Preserves Food Without Electricity

 April 3, 2015

 http://www.greenoptimistic.com/solar-cooling-system-preserve-food/#.VSFm8uG-2zk

 An eco-friendly and cheap cooling system developed by a Mexican researcher uses solar energy to maintain temperature of food and water at nine degrees Celsius for three months.
Refrigerating systems have been under the spot light ever since they were found guilty of polluting the atmosphere with the Chlorofluorocarbons (CFCs), causing a depletion in the ozone layer. As of the 1970s, the negative effect of these compounds has globally acknowledged and heavily regulated. Nevertheless, their use in refrigerating systems continues to be apparent, and it will remain so until year 2020 (2030 for developing countries), when all CFCs should be faced out, as agreed during a United Nations-sponsored Montreal summit .
It is somewhat needless to say that any technology that can accelerate the process of complete elimination of these chemicals by providing an eco-friendly and affordable alternative, is more than welcome. One such development comes from the Institute of Science of the Meritorious University of Puebla (BUAP), in Mexico, by researcher Susana Elvia Toledo Flores. A solar-powered, eco-friendly, cooling system.


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Laser Refrigeration is Fastest, Coolest Chilling Tech Yet

September 3, 2009


http://www.popsci.com/scitech/article/2009-09/laser-refrigeration-fastest-coolest-chilling-tech-yet



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Shape memory alloys the basis for more efficient refrigerant-free cooling

  

February 4, 2016

Shape memory materials, also known as "metal muscles" or "artificial muscles," have the ability to snap back into their original shape after being stretched, squashed, bent, or otherwise deformed. If the material is a metal alloy, such as nickel-titanium, the deformation changes the material's crystal lattice structure in what's known as phase transition, which causes the material to become hotter. Allowing the material to relax and return to its original form cools it by about 20° C (36° F) below the ambient temperature.

"In our systems, shape memory alloys (SMAs) are used to remove heat," says Stefan Seelecke, Professor for Intelligent Material Systems at Saarland University. "Shape memory means that wires or sheets made from a nickel-titanium alloy have a certain ability to remember their original shape: If they undergo deformation, they will return to their earlier shape, so they are able to tense and flex like muscles. The fact that they absorb and release heat when they do so is something we exploit to achieve cooling."

 http://www.gizmag.com/shape-memory-refrigerant-free/41652/?li_source=LI&li_medium=default-widget
 

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3D-printed bricks can cool a room with water

 

 February 18, 2015

 

We've previously seen designers use the presence of swimming pools or take advantage of prevailing winds to help passively cool homes. But what if every brick used to build a house could cool it down? Design studio Emerging Objects has come out with 3D-printed porous bricks called Cool Bricks that can be filled with water to bring down temperatures.

 http://www.gizmag.com/3d-printed-cool-bricks/36144/

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Novel cement lets buildings cool themselves

 

August 21, 2025 

 

https://techxplore.com/news/2025-08-cement-cool.html 

 

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Porous plastic sheets can cool buildings by radiating light to space 

February 5, 2025

https://www.psu.edu/news/engineering/story/porous-plastic-sheets-can-cool-buildings-radiating-light-space

 
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Your refrigerator still uses technology from the 1950s, but a revolutionary upgrade is in the works

2025-02-09

The thermogalvanic cells

At the heart of this innovation are the thermogalvanic cells, which provide a cooling effect thanks to a reversible electrochemical reaction. This mechanism is intriguing because it allows for the generation of cold from ambient heat. These cells represent a significant advancement in cooling, calling into question the efficiency of traditional systems.

Conversion of heat to electricity

The cells function by converting heat into electricity. When an electric current is applied, it triggers a process that enables cooling. This innovative method promises energy efficiency that could revolutionize our approach to cooling and reduce the ecological impact of current appliances.

A spectacular chemical evolution

The evolution in the chemical composition of the materials used is also remarkable. The researchers have managed to increase the cooling capacity by over 1300%, an impressive result that redefines industrial standards. This demonstrates that suitable materials can radically change the efficiency of thermogalvanic systems.
The role of the electrolyte

The importance of a good electrolyte is crucial for the optimal functioning of the cells. Currently, a hydrated iron salt with perchlorate is used, which significantly improves the solubility of iron ions. This innovation promotes a 70% efficiency improvement in cooling, a significant step towards more powerful and sustainable refrigerators.

https://cybersciencecenter.nl/en/your-refrigerator-still-uses-technology-from-the-1950s-but-a-revolutionary-upgrade-is-in-the-works-8773/

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NIST Team Demonstrates Novel Way to Convert Heat to Electricity

 

May 19, 2023

 

Researchers at the National Institute of Standards and Technology (NIST) have fabricated a novel device that could dramatically boost the conversion of heat into electricity. If perfected, the technology could help recoup some of the recoverable heat energy that is wasted in the U.S. at a rate of about $100 billion each year.

 

The new fabrication technique — developed by NIST researcher Kris Bertness and her collaborators — involves depositing hundreds of thousands of microscopic columns of gallium nitride atop a silicon wafer. Layers of silicon are then removed from the underside of the wafer until only a thin sheet of the material remains. The interaction between the pillars and the silicon sheet slows the transport of heat in the silicon, enabling more of the heat to convert to electric current. Bertness and her collaborators at the University of Colorado Boulder reported the findings online March 23 in Advanced Materials.

 

Once the fabrication method is perfected, the silicon sheets could be wrapped around steam or exhaust pipes to convert heat emissions into electricity that could power nearby devices or be delivered to a power grid. Another potential application would be cooling computer chips. 

https://www.nist.gov/news-events/news/2023/05/nist-team-demonstrates-novel-way-convert-heat-electricity

 

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A Super Material Applicable Fuel Cells, Batteries and Other Energy Conversion Devices

 

 September 19, 2021

 

 Researchers have discovered a material that is only four atoms thick and allows for the study of the motion of charged particles in only two dimensions. Such studies could lead to pivotal discoveries in solid electrolytes for batteries and other applications. 

 

Unplanned discovery could lead to future pivotal discoveries in batteries, fuel cells, devices for converting heat to electricity and more.

 

https://fuelcellsworks.com/news/a-super-material-applicable-to-batteries-and-other-energy-conversion-devices

 

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New breakthrough in thermoelectric materials

 

Apr 02, 2015 

 

 http://phys.org/news/2015-04-breakthrough-thermoelectric-materials.html#ajTabs

A joint South Korean and American research group has developed a scalable production method for a state of the art alloy for the use in solid state thermoelectric devices. This new alloy is nearly twice as efficient as existing materials and may lead to a new host of applications. Uses include refrigeration, consumer electronics, transportation as well as novel devices which have not been produced yet do to the inefficiencies of existing materials.



French physicist Jean Charles Athanase Peltier discovered a key concept necessary for thermoelectric (TE) temperature control in 1834. His findings were so significant, TE devices are now commonly referred to Peltier devices. Since his work, there have been steady advancements in materials and design. Despite the technological sophistication Peltier devices, they are still less energy efficient than traditional compressor/evaporation cooling.

In the 1960's, Peltier devices were primarily made from Bismuth-Telluride (Bi2Te3) or Antimony-Telluride (Sb2Te3) alloys and had a peak efficiency (zT) of 1.1, meaning the electricity going in was only slightly less than the heat coming out. Since the 1960's there have been incremental advancements in alloy technology used in Peltier devices.

In 2014, researchers in South Korea at IBS Center for Integrated Nanostructure Physics along with Samsung Advanced Institute of Technology, the Department of Nano Applied Engineering at Kangwon National University, the Department of Energy Science at Sungkyunkwan University, and Materials Science department at California Institute of Technology California, USA have formulated a new method for creating a novel and much more efficient TE alloy.

TE alloys are special because the metals have an incredibly high melting point. Instead of melting the metals to fuse them, they are combined through a process called sintering which uses heat and/or pressure to join the small, metallic granules. The joint team, including IBS researchers, used a process called liquid-flow assisted sintering which combined all three antimony, bismuth and telluride granules into one alloy (Bi0.5Sb1.5Te3). Additional melted tellurium was used as the liquid between the Bi0.5Sb1.5Te3 granules to help fuse them into a solid alloy, and excess Te is expelled in the process.

By creating the alloy this way, the joints between the fused grains, also known as the grain boundaries, took on a special property. Traditionally sintered Bi0.5Sb1.5Te3 have thick, coarse joints which have led to a decrease in both thermal and electrical conductivity. The new liquid-phase sintering creates grain boundaries which are organized and aligned in seams called dislocation arrays. These dislocation arrays greatly reduce their thermal conduction, leading to an enhancement of their thermoelectric conversion efficiency.

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From Lab Curiosity to Industrial Reality: The New Dawn of Transition Metal Telluride Nanosheets

April 14, 2024

https://scitechdaily.com/from-lab-curiosity-to-industrial-reality-the-new-dawn-of-transition-metal-telluride-nanosheets/

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Nanodiamond “Heat Highways” Offer Four Times Better Heat Dissipation for Electronics

 

2023


https://scitechpost.com/nanodiamond-heat-highways-offer-four-times-better-heat-dissipation-for-electronics/

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Nanodiamonds Are Key to Efficient Hydrogen Purification – And a Zero-Carbon Future

 

February 6, 2022

 

Researchers from Kyoto University have developed nanodiamond-reinforced composite membranes that significantly improve hydrogen purification, making hydrogen production more efficient and cost-effective.

 

This advancement addresses a critical challenge in achieving a hydrogen-based economy, a key component in combating climate change. By integrating nanodiamonds, which stabilize the membranes under humid conditions, this technology could also have applications in other industries requiring humidity control.

 

https://scitechdaily.com/nanodiamonds-are-key-to-efficient-hydrogen-purification-and-a-zero-carbon-future/

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New hydrogel to cool down electronics and converting their heat into electricity

 

April 22, 2020

https://www.techexplorist.com/new-hydrogel-cool-down-electronics-converting-heat-electricity/31762/

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New capabilities in DNA nanostructure self-assembly eliminate need for extreme heating and controlled cooling

March 12, 2025

University at Albany researchers at the RNA Institute are pioneering new methods for designing and assembling DNA nanostructures, enhancing their potential for real-world applications in medicine, materials science and data storage.

Their latest findings demonstrate a novel ability to assemble these structures without the need for extreme heat and controlled cooling. They also demonstrate successful assembly of unconventional "buffer" substances including nickel. These developments, published in the journal Science Advances, unlock new possibilities in DNA nanotechnology.

DNA is most commonly recognized for its role in storing genetic information. Composed of base pairs that can easily be manipulated, DNA is also an excellent material for constructing nanoscale objects. By "programming" the base pairs that make up DNA molecules, scientists can create precise structures as small as a few nanometers that can be engineered into shapes with intricate architectures.

With their tiny scale and custom design, these structures can be used for highly accurate placement of things like biomolecules, cells and nanoparticles, with applications in biomedicine (e.g., drug delivery, therapeutics and diagnostic tools) and material design.

Creating these structures often requires DNA strands to be heated then cooled in special buffer solutions that typically contain magnesium ions. However, the need for precise temperature control limits possibilities for practical applications, and DNA nanostructures assembled in magnesium can pose challenges, including structural instability in biological environments.

https://phys.org/news/2025-03-capabilities-dna-nanostructure-extreme-cooling.html

 

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Overcoming Longstanding Quantum Computing Roadblock: Scientists Develop Efficient 2D Device for Quantum Cooling

 

July 10, 2024

 

EPFL researchers have created a groundbreaking device that operates efficiently at millikelvin temperatures required for quantum computing, potentially revolutionizing cooling systems for advanced technologies. The LANES lab’s 2D device made of graphene and indium selenide 

 
https://recodenews.com/overcoming-longstanding-quantum-computing-roadblock-scientists-develop-efficient-2d-device-for-quantum-cooling/index.html

 

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Advancements in electronics cooling techniques: focus on graphene’s prospects, challenges, and future directions

 

03 February 2025

https://link.springer.com/article/10.1007/s10973-024-13985-w

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New powerful green cooling system that could replace air conditioners

March 12, 2025

A team of researchers from the Hong Kong University of Science and Technology (HKUST) has created the world’s first kilowatt-scale elastocaloric cooling device, a new type of air conditioning system that is energy-efficient and environmentally friendly.

This breakthrough technology can cool indoor spaces quickly, reaching a comfortable 21°C–22°C within just 15 minutes, even when outdoor temperatures are above 30°C.

The research, published in the journal Nature, offers a promising solution for reducing energy consumption and cutting down greenhouse gas emissions in the cooling industry.

https://knowridge.com/2025/03/new-powerful-green-cooling-system-that-could-replace-air-conditioners/

 

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Thermophotovoltaic device turns waste heat into electricity—while defying a physical limit

February 18, 2025

A team of engineers and material scientists in the Paul M. Rady Department of Mechanical Engineering at CU Boulder has developed a new technology to turn thermal radiation into electricity in a way that literally teases the basic law of thermal physics.

https://techxplore.com/news/2025-02-thermophotovoltaic-device-electricity-defying-physical.html


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Scientists Develop Fungi Tiles with Elephant Skin Texture to Cool Buildings

13 Jun 2025

 

 
Scientists at Nanyang Technological University (NTU) in Singapore have developed a promising new building material to help reduce energy consumption in buildings. The research team has created special fungi tiles with an elephant skin-like texture that can naturally cool buildings without using electricity or other energy sources.

These innovative tiles are made from a biomaterial that combines mycelium, the root network of fungi, with organic waste. The researchers collaborated with local ecology and biomimicry design firm bioSEA to give the tiles a bumpy, wrinkly texture modeled after elephant skin.

Elephants lack sweat glands and rely on skin wrinkles to regulate body temperature in hot climates. The scientists applied this natural cooling mechanism to their fungi tiles with impressive results.

Laboratory tests showed that the elephant skin-inspired fungi tiles cooled 25% faster than flat mycelium tiles. The textured tiles also heated up more slowly, with a heating rate 2% lower than flat tiles. Even more remarkably, the cooling effect improved by an additional 70% in simulated rainy conditions, making them particularly suitable for tropical climates.

Associate Professor Hortense Le Ferrand, who led the study, highlighted the potential of these fungi tiles as a sustainable alternative to conventional building materials. “Insulation materials are increasingly integrated into building walls to enhance energy efficiency, but these are mostly synthetic and come with environmental consequences throughout their life cycle,” she explained.

The construction industry accounts for nearly 40% of all energy-related emissions worldwide. Finding eco-friendly alternatives like these fungi tiles could help significantly reduce this environmental impact.

https://techxplore.com/news/2025-04-scientists-fungi-tiles-elephant-skin.html

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Remarkable New Fabric Efficiently Transfers Heat – Could Help Keep You Cool Even Without A/C

 

July 30, 2020

 

Researchers have developed a material that cools the wearer without using any electricity. The fabric transfers heat, allows moisture to evaporate from the skin and repels water. 

 

Air conditioning and other space cooling methods account for about 10% of all electricity consumption in the U.S., according to the U.S. Energy Information Administration. Now, researchers reporting in ACS Applied Materials & Interfaces have developed a material that cools the wearer without using any electricity. The fabric transfers heat, allows moisture to evaporate from the skin and repels water.

 

Cooling off a person’s body is much more efficient than cooling an entire room or building. Various clothing and textiles have been designed to do just that, but most have disadvantages, such as poor cooling capacity; large electricity consumption; complex, time-consuming manufacturing; and/or high cost. Yang Si, Bin Ding, and colleagues wanted to develop a personal cooling fabric that could efficiently transfer heat away from the body, while also being breathable, water-repellent, and easy to make.

 

https://scitechdaily.com/remarkable-new-fabric-efficiently-transfers-heat-could-help-keep-you-cool-even-without-a-c/

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Sustainable cooling film could slash building energy use by 20% amid rising global temperatures

June 24, 2025

https://techxplore.com/news/2025-06-sustainable-cooling-slash-energy-global.html

 

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Passive cooling paint sweats off heat to deliver 10X cooling and 30% energy savings

June 18, 2025 

A new cement-based paint can cool down the building by sweating off the heat. The cooling paint, named CCP-30, was designed by an international team of researchers and features a nanoparticle-modified porous structure composed of a calcium silicate hydrate (C-S-H) gel network.

https://techxplore.com/news/2025-06-passive-cooling-10x-energy.html 

 

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Inspired by butterflies, researcher invents new paint that has no pigments

 

 Mar 10, 2023

 

It can not only keep us safe from the dangerous effects of synthetic paints but also keep buildings cooler.

 

Researchers at the NanoScience Technology Center at the University of Central Florida have invented a new paint that does not use any pigments at all. Called plasmonic paint, it uses nanoscale structural arrangements of aluminum and aluminum oxide to generate its hues. 

 

Exterior paints on the building have a topic of quite some research as scientists look for ways to keep the heat in cooler regions and out in the warmer regions of the world. Last year, Interesting Engineering reported how researchers were working to make the world’s whitest paint thinner so that lesser quantities would be required to paint surfaces.

 

Structural Color: A Sustainable Alternative

 

“The range of colors and hues in the natural world are astonishing — from colorful flowers, birds and butterflies to underwater creatures like fish and cephalopods,” Chanda says. “Structural color serves as the primary color-generating mechanism in several extremely vivid species where geometrical arrangement of typically two colorless materials produces all colors. On the other hand, with manmade pigment, new molecules are needed for every color present.”

 

Based on such bio-inspirations, Chanda’s research group innovated a plasmonic paint, which utilizes nanoscale structural arrangement of colorless materials — aluminum and aluminum oxide — instead of pigments to create colors.

 

While pigment colorants control light absorption based on the electronic property of the pigment material and hence every color needs a new molecule, structural colorants control the way light is reflected, scattered or absorbed based purely on the geometrical arrangement of nanostructures.

 

Such structural colors are environmentally friendly as they only use metals and oxides, unlike present pigment-based colors that use artificially synthesized molecules.

 

The researchers have combined their structural color flakes with a commercial binder to form long-lasting paints of all colors.

 

 https://scitechdaily.com/inspired-by-butterflies-scientist-creates-the-lightest-paint-in-the-world/

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Optical Illusion Produced by Butterflies’ Wing Scales Is Secret to Ultra-Black, Lightweight Materials

  

January 29, 2022

 

Permanent Wings: – Biologically improbable due to human bone and muscle structure (though at the same time, usually easy to rationalize at first glance due to the nature of our shoulders), and if they’re intended for actual flight, you may have to write off several laws of physics as well. Therefore, such characters are often assumed to be not entirely of this world, especially since the domain of birds shares a name with God’s kingdom: Heaven. This ties into the classic depictions of winged angels as well.

 

Some butterflies have ultra-black wings that rival the blackest materials made by humans, using wing scales that are only a fraction as thick — here’s how they do it. Set against a piece of black construction paper, the wings of the male cattleheart butterfly look even blacker than black.

 

The blackness on the wings of many male butterflies is darker than it is on their female counterparts, so one theory is it helps them show off to potential mates. The black regions always border white, colored, or iridescent patches, so the idea is they might work like a dark picture frame to make the brighter blotches pop.

 

In a study in the March 10 issue of the journal Nature Communications, Duke researchers report that ultra-black butterflies from disparate regions of the globe appear to have converged on the same trick. The secret to making blacks this dark and lightweight, they say, isn’t a surplus of melanin — the pigment responsible for a crow’s feathers or a black cat’s fur. It’s an optical illusion created by the 3-D structure of the butterflies’ wing scales.

https://science-atlas.com/biology/optical-illusion-produced-by-butterflies-wing-scales-is-secret-to/


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Nanostructures and Living Cells in Butterfly Wings Could Inspire Radiative-Cooling Materials & Advanced Flying Machines

 

January 28, 2020

 

Researchers discover that butterflies have specialized behaviors and wing scales to protect the living parts of their wings; nanostructures found in the wing scales could inspire the design of radiative-cooling materials to help manage excessive heat conditions; sensory network in the wings could inspire the design of advanced flying machines. 

https://scitechdaily.com/nanostructures-and-living-cells-in-butterfly-wings-could-inspire-radiative-cooling-materials-advanced-flying-machines/

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Memristors get the hues

 

22 April 2021

 

The memristor, in which an external electric field controls the formation and annihilation of conductive channels, has been described both as a missing electronic element and a memory and computational element. Here, their utility as building blocks for promising reflective and energy-efficient colour technology is described. 

https://www.nature.com/articles/s41565-021-00891-7

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Revolutionary Phase Change Nano Inks: The Future of Energy-Efficient Climate Control in Buildings & Cars

April 5, 2023

 

Phase change inks using nanotechnology have been developed to control temperature and provide passive climate control, reducing energy consumption. The versatile inks have potential applications in buildings, electronics, and clothing, and could become a sustainable solution to address climate change. 

 

World-first ‘phase change inks’ that could transform how we heat and cool buildings, homes, and cars – to achieve sophisticated ‘passive climate’ control – have been developed, with enormous potential to help reduce energy use and global greenhouse gas emissions.

 

New research published in The Royal Society of Chemistry’s Journal of Materials Chemistry A led by Dr. Mohammad Taha, documents proof-of-concept ‘phase change inks’ that use nanotechnology to control the temperature in everyday environments. They achieve this by adjusting the amount of radiation that can pass through them, based on the surrounding environment.

 

Dr. Taha said these inks could be used to develop coatings to achieve passive heating and cooling, reducing our need to rely on energy creation to regulate temperatures.

 

“Humans use a lot of energy to create and maintain comfortable environments – heating and cooling our buildings, homes, cars, and even our bodies,” Dr. Taha said.

 

Revolutionizing Energy Efficiency with Nanotechnology

 

The breakthrough was achieved by discovering how to modify one of the main components of ‘phase change materials’ – vanadium oxide (VO2). Phase change materials use triggers, like heat or electricity, to create enough energy for the material to transform itself under stress. However, phase change materials previously needed to be heated to very high temperatures for their ‘phase changing’ properties to be activated.

 

“We used our understanding of how these materials are put together to test how we could trigger the insulator to metal (IMT) reaction, where the material basically acts as a switch to block heat beyond a particular temperature – near-room temperature (30-40^oC),” Dr. Taha said.

 

Dr. Taha said the next step will involve taking the research, patented by the University of Melbourne, to production.

 

https://scitechdaily.com/revolutionary-phase-change-nano-inks-the-future-of-energy-efficient-climate-control-in-buildings-cars/

 

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 Closing the gaps—MXene-coated air filters show enhanced performance and reusability

May 24 2025

 

 

Despite improvements to air filtration technology in the aftermath of the COVID-19 pandemic, some of the smallest particles—those of automobile and factory emissions—can still make their way through less efficient, but common filters. An interdisciplinary team of researchers from Drexel University’s College of Engineering have introduced a new way to improve textile-based filters by coating them with a type of two-dimensional nanomaterial called MXene.

Recently published in the journal C—Journal of Carbon Research, the team’s research reports that a non-woven polyester textile—a low-cost material with low filtration efficiency—coated with a thin layer of MXene nanomaterial can turn it into a potent filter capable of pulling some of the finest nanoparticles from the air.

“It can be challenging for common filters to contend with particles less than 100 nanometers, which include those emitted by industrial processes and automobiles,” said Michael Waring, Ph.D., a professor in Drexel’s College of Engineering, and co-author of the research. “Being able to augment a filter, through a simple coating process, to make it effective against these emissions is a significant development.”

https://lifeboat.com/blog/2025/05/closing-the-gaps-mxene-coated-air-filters-show-enhanced-performance-and-reusability

 

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A new crystal that 'breathes' oxygen expands possibilities for clean energy and electronics

 

August 15, 2025

 

A team of scientists from Korea and Japan has discovered a new type of crystal that can "breathe"—releasing and absorbing oxygen repeatedly at relatively low temperatures. This unique ability could transform the way we develop clean energy technologies, including fuel cells, energy-saving windows, and smart thermal devices. 

 https://phys.org/news/2025-08-crystal-oxygen-possibilities-energy-electronics.html

 

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Physicists Solve a Perplexing Nano-Scale Mystery That May Assist In Preventing Overheating in Electronics

 

December 4, 2021

https://science-atlas.com/technology/physicists-solve-a-perplexing-nano-scale-mystery-that-may-assist-in/

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Underground ‘Groundfridge’ keeps produce fresh without electricity

 

March 16, 2025 

 

The naturally cool cellar.

 

https://www.techexplorist.com/underground-ground-fridge-dont-use-electricity/3995/

 

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Goodbye, frost. Scientists reveal long-lasting antifreeze technology

11.11.2024

 

Engineers at Northwestern University in the United States have developed a new strategy to prevent ice formation before it starts.

 

In the new research, scientists discovered that adjusting the texture of any surface and adding a thin layer of graphene oxide prevents 100% frost formation on surfaces for a week or more.

 

The result is, according to , 1000 times longer lasting than current state-of-the-art antifreeze surfaces.

 

“A unwanted frost accumulation it is a major concern in the industrial, residential and government sectors”, highlighted expert Kyoo-Chul Kenneth Park. “It is critical to develop effective anti-icing techniques for long periods of time in extreme environmental conditions. It is also necessary to develop antifreeze methods that are easy to manufacture and implement.”

 

Researchers have created an antifreeze technique hybrid able to prevent frost from forming for weeks. In addition to being durable, it is scalable and easily manufactured through 3D printing.

 

Four years ago, Park and his team discovered that adding millimeter-scale textures to a surface reduced ice formation by up to 80%. Published on Proceedings of the National Academy of Sciences, was inspired by the wavy geometry of the leaves.

 

“There is more frost formation in the convex regions of a leaf,” he explained. “In the concave regions (the ribs), we see much less frost. There was no explanation for the formation of these patterns, until we discovered that it is the geometry — and not the material — that controls it.”

 

https://lnginnorthernbc.ca/2024/11/11/goodbye-frost-scientists-reveal-long-lasting-antifreeze-technology/

 

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Way cool: UVA professor developing ‘freeze ray’ technology for the Air Force

 

31-Jul-2023

https://www.eurekalert.org/news-releases/997140

 

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MIT Physicists Create Ultracold Molecules of ²³Na⁴⁰K

 

June 10, 2015

(MIT researchers have successfully cooled a gas of sodium potassium (NaK) molecules to a temperature of 500 nanokelvin. In this artist’s illustration, the NaK molecule is represented with frozen spheres of ice merged together: the smaller sphere on the left represents a sodium atom, and the larger sphere on the right is a potassium atom.)

 http://scitechdaily.com/mit-physicists-create-ultracold-molecules-of-23na40k/

A team of physicists from MIT has successfully cooled molecules in a gas of sodium potassium (NaK) to a temperature of 500 nanokelvins, creating ultracold molecules.
The air around us is a chaotic superhighway of molecules whizzing through space and constantly colliding with each other at speeds of hundreds of miles per hour. Such erratic molecular behavior is normal at ambient temperatures.
But scientists have long suspected that if temperatures were to plunge to near absolute zero, molecules would come to a screeching halt, ceasing their individual chaotic motion and behaving as one collective body. This more orderly molecular behavior would begin to form very strange, exotic states of matter — states that have never been observed in the physical world.
Now experimental physicists at MIT have successfully cooled molecules in a gas of sodium potassium (NaK) to a temperature of 500 nanokelvins — just a hair above absolute zero, and over a million times colder than interstellar space. The researchers found that the ultracold molecules were relatively long-lived and stable, resisting reactive collisions with other molecules. The molecules also exhibited very strong dipole moments — strong imbalances in electric charge within molecules that mediate magnet-like forces between molecules over large distances.

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Cold Atom Laboratory Chills Atoms to New Lows

 

September 26, 2014

 

 

 (Artist's concept of an atom chip for use by NASA's Cold Atom Laboratory (CAL) aboard the International Space Station. CAL will use lasers to cool atoms to ultracold temperatures.Image Credit: NASA)

http://www.jpl.nasa.gov/news/news.php?feature=4312

Cold Atom Laboratory researchers used lasers to optically cool rubidium atoms to temperatures almost a million times colder than that of the depths of space. The atoms were then magnetically trapped, and radio waves were used to cool the atoms 100 times lower. The radiofrequency radiation acts like a knife, slicing away the hottest atoms from the trap so that only the coldest remain.

The research is at the point where this process can reliably create a Bose-Einstein condensate in just seconds.

"This was a tremendous accomplishment for the CAL team. It confirms the fidelity of the instrument system design and provides us a facility to perform science and hardware verifications before we get to the space station," said CAL Project Manager Anita Sengupta of JPL.

While so far, the Cold Atom Laboratory researchers have created Bose-Einstein condensates with rubidium atoms, eventually they will also add in potassium. The behavior of two condensates mixing together will be fascinating for physicists to observe, especially in space.

Besides merely creating Bose-Einstein condensates, CAL provides a suite of tools to manipulate and probe these quantum gases in a variety of ways. It has a unique role as a facility for the atomic, molecular and optical physics community to study cold atomic physics in microgravity, said David Aveline of JPL, CAL ground testbed lead.

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This New Element is Lighter than Hydrogen. What?!?!

Feb 2, 2023

When we first learn about atoms, we learn that the simplest has one electron buzzing around one proton, aka hydrogen. But it turns out there's an atom that's even simpler than this. It's called muonium, and it's an atom that's partially made of antimatter!

https://www.youtube.com/watch?v=KrabgulN1L8

 

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Scientists discover a new phase of high-density, ultra-hot ice

October 9, 2023

The outer planets of our solar system, Uranus and Neptune, are water-rich gas giants. These planets have extreme pressures 2 million times the Earth's atmosphere. They also have interiors as hot as the surface of the sun. Under these conditions, water exhibits exotic, high-density ice phases.

Researchers recently observed one of these phases, called Ice XIX, for the first time using high-power lasers to reproduce the necessary extreme conditions. They measured the Ice XIX structure using the Matter at Extreme Conditions instrument at the Linac Coherent Light Source, a pioneering X-ray laser facility, to show that oxygen atoms pack in a body-centered cubic structure, while the hydrogen atoms move freely like a fluid, dramatically increasing conductivity. Their paper was published in Scientific Reports.

https://phys.org/news/2023-10-scientists-phase-high-density-ultra-hot-ice.html

 

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Skate Anywhere Like Frozone! (Freeze and Skate)

Jul 14, 2023 

 

https://www.youtube.com/watch?v=QYmKDngX7rY


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Experimental study of alternative refrigerants to replace R134a in a domestic refrigerator

March 2018

https://www.researchgate.net/publication/338763358_Experimental_study_of_alternative_refrigerants_to_replace_R134a_in_a_domestic_refrigerator

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The Ancient World’s Ingenious Ice Making Air Conditioning System

Apr 3, 2024

https://www.youtube.com/watch?v=ta940DX_zko

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Why CO2 Heat Pumps Are The Future Of Cooling

Sep 12, 2023

https://www.youtube.com/watch?v=npqzHpeIvhM

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Super Antifreeze in Cells: The Ability to Survive in Ice and Snow Developed in Animals Far Earlier Than We Thought

2023

https://www.lifetechnology.com/blogs/life-technology-science-news/super-antifreeze-in-cells-the-ability-to-survive-in-ice-and-snow-developed-in-animals-far-earlier-than-we-thought

 

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Pot-in-Pot Magic: How the Clay Pot Cooler Africa is Shaping Off-Grid Cooling Solutions 

April 22, 2025

A Cool Revolution Rising from the Clay

In scorching rural towns across Africa, where electricity flickers or is altogether absent, innovation has always found a way to thrive. One such marvel? The humble clay pot cooler Africa communities have long relied on. Once dismissed as outdated or “backward,” this ingenious invention — also known as the pot-in-pot refrigerator — is now celebrated globally as one of the most efficient off-grid cooling solutions available. In countries like Nigeria, Sudan, and Burkina Faso, these coolers have preserved vegetables, medicine, and even human dignity for decades.

With climate change pushing temperatures higher and energy costs soaring, the world is beginning to take notice. A clay pot cooler Africa not only preserves perishable goods without electricity, but also preserves an entire philosophy of low-impact living. As the UNDP Climate Promise notes, Indigenous knowledge is becoming central in the fight against climate change — and these coolers are a testament to that wisdom.

The Science Behind the Clay: How Nature Cools Better

The genius of the clay pot cooler Africa design lies in its simplicity. When water evaporates from the wet sand between the pots, it draws heat away from the inner chamber. This passive cooling method can lower temperatures by up to 14°C — enough to store tomatoes, milk, and even insulin.

In regions where power outages are common, or where families live miles from the nearest grid connection, these off grid cooling solutions offer life-changing reliability. Unlike solar fridges that require costly panels and batteries, a clay pot cooler Africa is affordable, accessible, and repairable with locally available materials.

UNESCO has recognized this design as one of the most impactful grassroots innovations in sustainable development — a rare example of low-tech brilliance solving high-stakes problems.

https://echoesofafrika.com/clay-pot-cooler-africa-off-grid-cooling/ 

 

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Mud Homes: Nature’s Answer to Summer Heat

May 12, 2024

https://medium.com/@kristanvihaan11/mud-homes-natures-answer-to-summer-heat-844246913a51 

 

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Scientists make remarkable discovery after studying 'green roofs' on buildings: 'Can offer unexpected co-benefits'

August 15, 2025 

A Tongji University research project has provided evidence that green roofs can remove microplastics from rainwater, according to Anthropocene.

The vegetative building toppers have long been used to help insulate structures, reducing heating and cooling costs. They can also reduce stormwater runoff. They consist of a waterproof membrane, soil, plants, and some other infrastructure needed to hold it all together. They also provide urban habitat for birds and insects, and can last twice as long as regular roofs, all according to the Government Accountability Office.

A lab-scale mockup in Shanghai demonstrated the ability to filter out the tiny plastic polluters. The roof was able to collect 97.5% of ground rubber, polyurethane fibers, and other microplastics that were added to simulated rainfall, per the lab summary.

https://www.yahoo.com/news/articles/scientists-remarkable-discovery-studying-green-233000859.html 

 

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10 Ancient Home Design Tricks That Still Work (Thousands of Years Later)

June 22, 2025

1. Roman Atrium

2. Japanese Shoji Screens

3. Greek Courtyard

4. Persian Rugs

5. Egyptian Papyrus Motifs

6. Moroccan Mosaic Tiles

7. Chinese Feng Shui Principles

8. Aztec Patterns in Textiles

9. Indian Jali Screens

10. Scandinavian Hygge Concepts

https://decofond.com/ancient-home-design-tricks/ 

 

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Ancient Cooling Techniques: How Our Ancestors Beat the Heat

8th January 2025

Table of Contents

    Architecture Designed for Cooling

    Water as a Cooling Element

    Harnessing Natural Elements

    Ingenious Cooling Devices

    Lessons for Sustainable Living Today

    Timeless Wisdom for Modern Comfort

Architecture Designed for Cooling

Ancient civilisations mastered the art of designing buildings that naturally stayed cool, even in scorching climates. Their architectural innovations harnessed materials, airflow and shade to create comfortable living spaces without modern technology.

Here are some of the most effective techniques:

    Thick walls and natural materials: Many ancient homes featured thick walls made of materials like adobe, stone or mud brick, which absorbed heat during the day and released it slowly at night.

    High ceilings: High ceilings allowed hot air to rise, keeping the living areas cooler.

    Strategic orientation: Buildings were often positioned to maximise shade and minimise direct sunlight.

    Open courtyards: Central courtyards provided shaded, ventilated areas for relaxation and gathering.

    Windcatchers: Persian windcatchers directed breezes into homes, cooling the interior naturally.

These timeless designs highlight the beauty of blending practicality with sustainability, offering inspiration for modern eco-friendly architecture.

Water as a Cooling Element

Water has always been one of the most effective ways to combat heat, and our ancestors understood this well. Ancient civilisations used water features not just for decoration but also as natural cooling systems.

The Romans, for example, built aqueducts to transport water into cities, feeding fountains and pools that cooled public spaces. Similarly, Islamic architecture often featured courtyards with central fountains, where evaporating water lowered the surrounding temperature.

In Persia, ingenious qanats − underground channels − brought cool water from distant mountains into homes and gardens, creating an oasis effect. Even in residential settings, simple methods like placing clay pots of water near windows helped cool the air as it evaporated.

These techniques weren’t just functional; they turned spaces into serene environments. Today, we can draw from these ideas by incorporating water features into our homes and gardens to create cooling, relaxing spaces while staying energy efficient.
Harnessing Natural Elements

Ancient civilisations relied on nature’s power to stay cool, using simple yet effective techniques that didn’t rely on modern air conditioning technology. By understanding and working with their environment, they created comfortable spaces even in the hottest climates.

Here are some ways they harnessed natural elements:

    Shade from trees: Planting trees around homes provided natural shade, reducing direct sunlight and cooling the air. This technique was common in ancient Greece and India.

    Pergolas and vines: Structures like pergolas covered with climbing plants created shaded walkways and living spaces. The cooling effect of greenery added a refreshing touch.

    Cross-ventilation: Openings in homes were strategically aligned to encourage airflow, letting cool breezes pass through.

    Natural insulation: Materials like straw, clay, and mud were used to insulate homes, keeping interiors cooler.

Ingenious Cooling Devices

Our ancestors’ resourcefulness in creating cooling devices is nothing short of impressive. Long before modern fans and air conditioners, simple yet effective tools were crafted to beat the heat. One remarkable example is the use of clay pots and wet mats.

In ancient India and Egypt, people would fill clay pots with water and let evaporation cool the surrounding air. Similarly, damp mats hung in doorways created a cooling breeze as air passed through.

In Persia, badgirs (or windcatchers) were tall structures designed to channel cool air into buildings, acting as natural air conditioners. Underground tunnels, or qanats, further enhanced this system by directing cool air from water sources into homes.

These devices were not only innovative but also sustainable, relying on natural processes to provide relief from the heat. They remind us that simple, eco-friendly solutions can be both effective and beautifully in tune with nature.
Lessons for Sustainable Living Today

The cooling techniques of our ancient ancestors offer valuable insights for creating sustainable and energy-efficient solutions in our modern lives.

By adopting their strategies, we can stay comfortable while reducing our environmental footprint.

Here are some key lessons we can apply today:

    Passive cooling designs: Incorporate features like thick walls, high ceilings, and shaded courtyards into modern architecture to reduce reliance on air conditioning.

    Greenery for cooling: Plant trees and climbing vines around homes to create natural shade and improve air quality.

    Water features: Add fountains or ponds to outdoor spaces to take advantage of evaporative cooling, much like ancient palaces did.

    Cross-ventilation: Design buildings with windows and openings that allow breezes to flow naturally, minimising the need for mechanical cooling.

    Sustainable materials: Use eco-friendly materials like clay, straw, or adobe for insulation and temperature regulation.

These ancient practices remind us that sustainable living starts with thoughtful design and a deep respect for nature. 

 

https://www.upside-down.com.au/blog/ancient-cooling-techniques-how-our-ancestors-beat-the-heat/ 

 

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How this ANCIENT wind catcher make building cool

 

 Sep 1, 2023

 

https://www.youtube.com/watch?v=aARLB7C0Les 

 

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Chapter 32: Vertical & sustainable farming methods



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We could have billions of people living on other planets, including in the oceans of our planet and other planets. The carbon could even be made to be converted to energy and minerals that could biodegrade properly. Imagine the amount of ideas, cultures, technology and life that we could create in other parts of the Universe. We need human minds to produce ideas, for advancement in technology. 

We need an environmentally friendly standard of farming. Food is not getting to the right places.  Too much food is being wasted, while many people go starving. It is debated if we should use organic traditional farming methods, synthetic farming or vertical farming.


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Vertical farming designs & concepts.

https://www.youtube.com/watch?v=hVk2B-9WQ0w&list=PLDCE2FF0D4101CC66&index=1

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Underwater Cities in The Future | Full Documentary 

https://www.youtube.com/watch?v=qs0a6Im9Alk



____________________________________ 

How 1 MILLION Pounds Of Organic Food Can Be Produced On 3 Acres

  

http://wakeup-world.com/2011/07/14/how-1-million-pounds-of-organic-food-can-be-produced-on-3-acres/

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Up to 90 percent of Americans could be fed entirely by local agriculture

 

Jun 02, 2015

 

 New farmland-mapping research published today (June 1) shows that up to 90 percent of Americans could be fed entirely by food grown or raised within 100 miles of their homes.


 http://phys.org/news/2015-06-percent-americans-fed-local-agriculture.html#jCp

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We can see the problems with too many added chemicals, pesticides, fungicides and synthetic fertilizers in current farming methods.

 

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 Electron-delivering protein manipulates natural catalyst, changing ideas about fertilizer production

 

 June 8th, 2015

 Results: In industry, synthesizing ammonia for fertilizers uses massive amounts of hydrogen, typically generated from fossil fuels, but in nature, the nitrogenase enzyme produces ammonia without added hydrogen. In studying the enzyme, scientists came up against a protein, called the Fe protein. This little protein delivers electrons to the larger nitrogenase MoFe enzyme. The smaller protein's actions limit the enzyme's speed. Recently, scientists at Pacific Northwest National Laboratory and three universities found that the smaller protein and larger enzyme roll across each other, likely pushing at the MoFe surface to deliver electrons.

Why It Matters: Producing ammonia for the world's crop fertilizers consumes 1 to 2 percent of all the energy produced by humankind. Part of that energy is used to generate hydrogen gas, which is combined with nitrogen gas in the Haber-Bosch process. This research sheds new light on how an enzyme catalyzes a reaction without added hydrogen; instead, the enzyme uses protons and electrons.

Methods: The little Fe protein that delivers the electrons comes under scrutiny, as it is the dissociation of this protein from the MoFe protein or enzyme that is the slowest step in the process. And, the dissociation step must happen 8 times for each molecule of ammonia that is produced. Expediting or removing this rate-limiting step would provide fundamental insights into the nature of the enzyme, insights that could be applied to synthetic catalysts.

Substitution of three amino acids buried deep in the MoFe protein allows electrons to be delivered from small molecule electron carriers to support the transformation, or reduction, of several substrates, including azide to ammonia, hydrazine to ammonia and protons to molecular hydrogen, or H2...

 http://phys.org/news/2015-06-electron-delivering-protein-natural-catalyst-ideas.html#jCp


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Different groups think that we should use a system of aquaponics to grow food. Aaquponics can be sustainable. I do not think that 100% of our food should be grown using aquaponics. Many types of berries grow wild, this includes other types of bushes and trees that give off fruit and other types of harvests. We should use a system of organic gardening, this includes forest gardens, vertical farming and aquaponics.

 

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Hydroponics   -   http://en.wikipedia.org/wiki/Hydroponics

Aquaponics   -   http://en.wikipedia.org/wiki/Aquaponics

Aeroponics   -   http://en.wikipedia.org/wiki/Aeroponics

Organic farming   -   http://en.wikipedia.org/wiki/Organic_farming

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Deep Sea Fish Farming in Geodesic Domes: Upgrade

https://www.youtube.com/watch?v=WpPZUGIJ2M0


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There are ways to work with the land, to co-exist. However, the way many farms mass-produce many crops and livestock, with synthetic chemicals and runoff from agriculture and livestock production, is not sustainable.

In certain areas in South America some cultures would only plant crops every few years, or have a system of crop rotation.  This would be considered an extremely organic way of farming and coexisting with nature.

Many farmers import tons of soil used for production of farming. Eventually farmers even discard this soil when their harvest is over, then import new soil in by trucks to plant a new harvest. Many claim that this would be a good example, of how farmers can burn out their soil. It becomes very difficult for any type of plant to grow naturally, when soil is burnt out from the use of over-farming.  This is why many farmers try to get thousands of acres. So that they can shift around the areas where they grow crops on their land.

With good organic farming and crop rotation, farmers can co-exist with the land. 

The big debate now, is if we should find a type of super soil to use with other soils such as terra preta. This includes if we should use a use a system of monoculture, forest farming, polyculture or both.

 


____________________________________

 

Terra preta

 

https://en.wikipedia.org/wiki/Terra_preta

 

Terra preta (Portuguese pronunciation: [ˈtɛʁɐ ˈpɾetɐ], literally "black earth" in Portuguese), also known as Amazonian dark earth or Indian black earth, is a type of very dark, fertile anthropogenic soil (anthrosol) found in the Amazon Basin. In Portuguese its full name is terra preta do índio or terra preta de índio ("black soil of the Indian", "Indians' black earth"). Terra mulata ("mulatto earth") is lighter or brownish in color. 

 

Terra preta owes its characteristic black color to its weathered charcoal content,  and was made by adding a mixture of charcoal, bones, broken pottery, compost and manure to the low fertility Amazonian soil. A product of indigenous Amazonian soil management and slash-and-char agriculture, the charcoal is stable and remains in the soil for thousands of years, binding and retaining minerals and nutrients.

 

Terra preta is characterized by the presence of low-temperature charcoal residues in high concentrations; of high quantities of tiny pottery shards; of organic matter such as plant residues, animal feces, fish and animal bones, and other material; and of nutrients such as nitrogen, phosphorus, calcium, zinc and manganese. Fertile soils such as terra preta show high levels of microorganic activities and other specific characteristics within particular ecosystems. 

 

Terra preta zones are generally surrounded by terra comum ([ˈtɛʁɐ koˈmũ, ku-]), or "common soil"; these are infertile soils, mainly acrisols, but also ferralsols and arenosols.  Deforested arable soils in the Amazon are productive for a short period of time before their nutrients are consumed or leached away by rain or flooding. This forces farmers to migrate to an unburned area and clear it (by fire). Terra preta is less prone to nutrient leaching because of its high concentration of charcoal, microbial life and organic matter. The combination accumulates nutrients, minerals and microorganisms and withstands leaching.

Terra preta soils were created by farming communities between 450 BCE and 950 CE. Soil depths can reach 2 meters (6.6 ft). It is reported to regenerate itself at the rate of 1 centimeter (0.4 in) per year.

 

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Monoculture

 Monoculture is the agricultural practice of producing or growing a single crop or plant species in a field at a time. Polyculture, where more than one crop is grown in the same space at the same time, is the alternative to monoculture.  Monoculture is widely used in modern industrial agriculture and its implementation has allowed for increased efficiencies in planting and harvest.
 

http://en.wikipedia.org/wiki/Monoculture


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Polyculture

 http://en.wikipedia.org/wiki/Polyculture

 Polyculture is agriculture using multiple crops in the same space, in imitation of the diversity of natural ecosystems, and avoiding large stands of single crops, or monoculture. It includes multi-cropping, intercropping, companion planting, beneficial weeds, and alley cropping. It is the raising at the same time and place of more than one species of plant or animal.



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Fertilizer Runoff Overwhelms Streams and Rivers--Creating Vast "Dead Zones"

 

The nation's waterways are brimming with excess nitrogen from fertilizer--and plans to boost biofuel production threaten to aggravate an already serious situation

 

March 14, 2008

http://www.scientificamerican.com/article/fertilizer-runoff-overwhelms-streams/

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All Natural, Mushroom-Based Pesticide Could Revolutionize Agriculture

 

May 14, 2015

Could an insecticide made from mushrooms compete with commercial pesticides applied to crops the world over?

Fungus expert Paul Stamets thinks so, with a product he calls SMART pesticides. They are made from natural fungi, which kill insects and protect crops without creating toxic residue and runoff. If adopted, the mushroom pesticides would be a breath of fresh air in our increasingly toxic environment.

Pesticides can be necessary for large-scale food production, but they also have harmful effects on the natural world as well as on human health. Many of the chemicals used in commercial pesticides, like  ammonia, arsenic, benzene, chlorine, dioxins, formaldehyde and glyphosate are dangerous to people even in small doses, and they show up in human bodies after consumption of conventionally-grown food.

Widespread pesticide use is also one possible culprit for the massive decline in bee populations over the last decade, as well as a persistent cause of ground and fresh water pollution.

http://reset.me/story/all-natural-mushroom-based-pesticide-could-revolutionize-agriculture/

 

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Bioactive Nanocarrier Spray: Better Crops Without Genetic Modification

 

February 23, 2022

 

 

 

(Left) Schematic of the process. A bioactive molecule (like DNA or RNA) is combined with a peptide nanocarrier (a cell-penetrating peptide, CPP) in an aqueous solution and then sprayed onto plant leaves with a spray atomizer. This technique can alter gene expression without altering the genes themselves. (Right) Evidence that the system can be used to promote gene expression. Blue staining can be seen after spraying with a plasma DNA/CPP complex containing the GUS reporter gene. Note the upper leaf without any blue staining. This leaf was sprayed with a solution that contained the plasma DNA but not the peptide carrier. 

 

Scientists have developed a bioactive spray that delivers molecules to plant cells, enhancing crop quality without altering their genes. 

 
https://scitechdaily.com/bioactive-nanocarrier-spray-better-crops-without-genetic-modification/

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Drone footage follows 10,000 ducks “cleaning” rice paddies in Thailand

Sep 15, 2020

https://www.youtube.com/watch?v=Nw4c5RhRYMY

 

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How farmers can use ducks to control pests

Sep 22, 2018

https://www.standardmedia.co.ke/farmkenya/article/2001296522/login.html


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A functional overview of conservation biological control

2016

https://www.sciencedirect.com/science/article/abs/pii/S0261219416303210

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How Effective Is Conservation Biological Control in Regulating Insect Pest Populations in Organic Crop Production Systems?

2020

https://pmc.ncbi.nlm.nih.gov/articles/PMC7692856/

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Conservation biological control: Improving the science base

2018

https://pmc.ncbi.nlm.nih.gov/articles/PMC6099858/

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Planting for biocontrol

April 24, 2024 

How conservation biocontrol can help you keep pests at bay through thoughtful planting.

https://www.greenhousemag.com/article/conservation-biocontrol-planting-growing-beneficial-insects-ipm-integrated-pest-management/

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Types of biological control: augmentative, conservation and classical

The three main types of biological control for crops – conservation, augmentative and classical.

https://bioprotectionportal.com/resources/types-of-biological-control/

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Conservation biological control

06/02/2018 

https://dicoagroecologie.fr/en/dictionnaire/conservation-biological-control/


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The rise of nanoagrochemicals

08 October 2021

 

Intrigued by the growing interest in nanoagrochemicals, Melanie Kah, Rai Kookana, Alexander Gogos and Thomas Bucheli detected a lack of systematic comparison between fertilizers and pesticides in the nanoform and conventional products. In their view, such a comparison was essential to guide research and development in the field towards the right direction. They proceeded to scrutinize existing papers in the literature and assessed both the efficacy and potential hazard of nanofertilizers and nanopesticides. The results of their analysis were published in Nature Nanotechnology in May 2018 (Nat. Nanotechnol. 13, 677–684; 2018). 

https://www.nature.com/articles/s41565-021-00995-0

 

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Nanoparticle smart spray helps crops block infection before it starts

 

 June 4, 2025

 

 

Image at 3,000x magnification shows the SENDS nanoparticles (in blue) surrounding the stomata of a plant. 

 

https://phys.org/news/2025-06-nanoparticle-smart-spray-crops-block.html#google_vignette 

 

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 What are the greenhouse gases ?


 http://www.manicore.com/anglais/documentation_a/greenhouse/greenhouse_gas.html

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Some have mentioned if we should use bacterium for fungicides, pesticides and plant food.  



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Some people think that the world is currently overpopulated, and that we are currently not living as environmentally friendly as we could be, with many of these harmful chemicals going around. 

We could have trillions of people living off the planet, and living on other planets, moons and different areas in the Universe. We could harvest ideas from trillions of people, while creating new types of areas for humans and animals to live in. 

 

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Chapter 33: Clean-up technology



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The following chapter is dedicated to the preservation of the Earth, including how to fix contaminated sources of water, soil and atmospheric pollution.

Many landfills have toxic and radioactive chemicals in them. In this chapter, we will go into detail on what we can do as a civilization in order to fix many of these problems. 

 

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Superfund

Superfund or Comprehensive Environmental Response, Compensation, and Liability Act of 1980 (CERCLA) is a United States federal law designed to clean up sites contaminated with hazardous substances as well as broadly defined "pollutants or contaminants". Superfund also gives authority to federal natural resource agencies, states and Native American tribes to recover natural resource damages caused by releases of hazardous substances, and it created the Agency for Toxic Substances and Disease Registry (ATSDR). CERCLA's broad authority to clean up releases or threatened releases of hazardous substances that may endanger public health or welfare or the (natural) environment was given primarily to the Environmental Protection Agency (EPA) and to states (though most states now have and most often use their own versions of CERCLA).

http://en.wikipedia.org/wiki/Superfund



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List of Superfund sites in the United States


http://en.wikipedia.org/wiki/List_of_Superfund_sites_in_the_United_States

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Brownfield land

 

Brownfield is a term used in urban planning to describe land previously used for industrial purposes or some commercial uses. Such land may have been contaminated with hazardous waste or pollution or is feared to be so. Once cleaned up, such an area can become host to a business development such as a retail park. Land that is more severely contaminated and has high concentrations of hazardous waste or pollution, such as a Superfund site, does not fall under the brownfield classification. Mothballed brownfields are properties that the owners are not willing to transfer or put to productive reuse.

http://en.wikipedia.org/wiki/Brownfield_land


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Air pollution also comes from the manufacturing of industrial products, the burning of fuels and agriculture production. Even driving on a farm road, that has been sprayed down with pesticides, fungicides and chemicals can cause extra air pollution in the environment.  We should have a better standard for how we produce energy and how we manufacture everyday items.

 

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Big polluters: one massive container ship equals 50 million cars

 April 23, 2009

 April 23, 2009 The Guardian has reported on new research showing that in one year, a single large container ship can emit cancer and asthma-causing pollutants equivalent to that of 50 million cars. The low grade bunker fuel used by the worlds 90,000 cargo ships contains up to 2,000 times the amount of sulfur compared to diesel fuel used in automobiles. The recent boom in the global trade of manufactured goods has also resulted in a new breed of super sized container ship which consume fuel not by the gallons, but by tons per hour, and shipping now accounts for 90% of global trade by volume.

 http://www.gizmag.com/shipping-pollution/11526/



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India River Pollution: 80 Percent of Indian Sewage Flows Untreated Into Country's Rivers 

 

 2013

 

http://www.huffingtonpost.com/2013/03/05/india-river-pollution-sewage_n_2810213.html

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World’s highest drug levels entering India stream

 

2009

 

PATANCHERU, India (AP) When researchers analyzed vials of treated wastewater taken from a plant where about 90 Indian drug factories dump their residues, they were shocked. Enough of a single, powerful antibiotic was being spewed into one stream each day to treat every person in a city of 90,000.
And it wasn’t just ciprofloxacin being detected. The supposedly cleaned water was a floating medicine cabinet a soup of 21 different active pharmaceutical ingredients, used in generics for treatment of hypertension, heart disease, chronic liver ailments, depression, gonorrhea, ulcers and other ailments. Half of the drugs measured at the highest levels of pharmaceuticals ever detected in the environment, researchers say.
Those Indian factories produce drugs for much of the world, including many Americans. The result: Some of India’s poor are unwittingly consuming an array of chemicals that may be harmful, and could lead to the proliferation of drug-resistant bacteria.

 http://www.washingtontimes.com/news/2009/jan/26/worlds-highest-drug-levels-entering-india-stream/#ixzz2shxgPbtB

 

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250 Million Pounds of Drugs Flushed Down the Toilet by Hospitals

  

http://www.treehugger.com/green-food/250-million-pounds-of-drugs-flushed-down-the-toilet-by-hospitals.html

 

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NASA Satellites Track Vanishing Groundwater

   

Feb 24, 2010


Data from NASA's GRACE satellites helps gauge groundwater fluctuations in northwestern India

 http://news.nationalgeographic.com/news/2010/02/100217-groundwater-crisis-nasa-satellites-india-environment/

 

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Urge Pharmaceutical Companies to Manage Safe Drug Disposal

 

http://forcechange.com/45898/urge-pharmaceutical-companies-to-manage-safe-drug-disposal/

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Many people think that herbal medicine, including new forms of medicine technology can replace many harmful pharmaceuticals. We can see how cannabis can be used as a form of medicine, in order to help with cancer. Others think that even similar medicinal types of medicine, could be extracted from plants that have been known to numb pain. Many plants on this planet have a purpose for different uses. This is why it is important to preserve our forests. Even some plants, trees and herbs in the past few thousand years have now gone extinct. There is no telling what types of benefits that many of these extinct plants could have had. Many of these plants could have been utilized for medical research. Some even question if we can use fossils, DNA or other materials to bring back certain plants and animals, this is currently being debated around the globe. Trying to genetically modify extinct species of plants, bacteria and animals could also have negative consequences.


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Researchers discover how opium poppies synthesize morphine

 

July 13, 2015 

 

 Many people who live in developing countries do not have access to the pain relief that comes from morphine or other analgesics. That's because opiates are primarily derived from the opium poppy plant (Papaver somniferum) and are dependent on the plant health and supply around the world.

After years of leading research on the opium poppy, University of Calgary scientists, Peter Facchini, his PhD student, Scott Farrow, and research associate Jill Hagel, have characterized a novel gene that encodes the gateway enzyme in the formation of morphine -which is to say, they've begun to understand how poppies synthesize the pain killing enzymes. The discovery opens the door to alternative production systems, aside from the plant itself.

Farrow, who is building on the insights Facchini and his team have been gathering over more than 23 years of research into opium poppies, is the lead author of a new paper that describes one of many significant discoveries arising from Facchini's research program.



"The gene we've isolated actually consists of a natural fusion between two ancestral genes, which encodes the gateway enzyme in the formation of morphine," says Farrow. "It's really interesting to see these fused genes in a metabolic pathway. It provides us with a new tool to search for something missing in other plants as well."

http://phys.org/news/2015-07-opium-poppies-morphine.html#jCp

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Many people want a solution to the problems concerning ground contamination, including air and water pollution. We must be cautious of introducing certain types of cleaning agents and industrial chemicals into the environment, this includes dispersants and surfactants.

 

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Dispersant

 

A dispersant or a dispersing agent or a plasticizer or a superplasticizer is either a non-surface active polymer or a surface-active substance added to a suspension, usually a colloid, to improve the separation of particles and to prevent settling or clumping. Dispersants consist normally of one or more surfactants, but may also be gases.

http://en.wikipedia.org/wiki/Dispersant



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Surfactant

 

 http://en.wikipedia.org/wiki/Surfactant

Surfactants are compounds that lower the surface tension (or interfacial tension) between two liquids or between a liquid and a solid. Surfactants may act as detergents, wetting agents, emulsifiers, foaming agents, and dispersants.

Health and environmental controversy

 

Surfactants are routinely deposited in numerous ways on land and into water systems, whether as part of an intended process or as industrial and household waste. Some of them are known to be toxic to animals, ecosystems, and humans, and can increase the diffusion of other environmental contaminants. As a result, there are proposed or voluntary restrictions on the use of some surfactants. For example, PFOS is a persistent organic pollutant as judged by the Stockholm Convention. Additionally, PFOA has been subject to a voluntary agreement by the U.S. Environmental Protection Agency and eight chemical companies to reduce and eliminate emissions of the chemical and its precursors.
The two major surfactants used in the year 2000 were linear alkylbenzene sulfonates (LAS) and the alkyl phenol ethoxylates (APE). They break down in the aerobic conditions found in sewage treatment plants and in soil to the metabolite nonylphenol, which is thought to be an endocrine disruptor


http://en.wikipedia.org/wiki/Surfactant

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We should be cautious of adding more harmful chemicals in the ground, to try and clean up existing harmful chemicals in the soil and water.

  

There exists many natural remedies to clean and purify water and soil.

We can use simple materials from mushrooms, plants and other materials to clean-up pollution from the ground.

 
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Mushrooms – Nature’s Recyclers and Pollution-Zappers

 April 5, 2015

 http://www.greenoptimistic.com/mushrooms-recycle-pollution/#.VSFjo-G-2zk

For ages, man has eaten mushrooms as a gustatory delight, some even to the point of intoxication like medicine men and other people out for a good time.   But there is more to these wonderful plants than meet the eye.

For one thing, they’re Mother Nature’s recyclers.  After animals and plants die, they decompose them back to dust so that they can be used again to bring about new life.  The stuff they decompose isn’t limited to plants and animals, though. They can also feed on plastic, just like the Pestalotiopsis microspora, a fungus discovered in the Ecuadorian Amazon that has an appetite for polyurethane.
And the Pestalotiopsis microspora is not alone in its earth saving abilities.

Researchers have discovered fungi that absorb toxic heavy metals without suffering side effects, effectively removing these from the environment.  There are even some mushrooms that will eat up radioactive waste and may be used to help remediate Fukushima.


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Orange Peel Can Help Clean Up Dirty Water

 

October 27, 2008

http://www.sciencedaily.com/releases/2008/10/081020093500.htm

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How to Clean Out Polluted Soil

 http://www.doityourself.com/stry/how-to-clean-out-polluted-soil


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Using plants to clean contaminated soil

 Aug 11, 2014


http://www.resilience.org/stories/2014-08-11/using-plants-to-clean-contaminated-soil

 

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MURUNGA - THE ULTIMATE ANSWER TO POLLUTED WATER

http://infolanka.com/org/diary/13.html

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Plant-based Silver Nanoparticles Made From Magnolia Leaves For Medical and Environmental Applications

Jul 14 2025

 

Researchers have developed eco-friendly silver nanoparticles from Magnolia alba leaf extract. These nanoparticles show enhanced antioxidant and dye-degrading properties with potential medical and environmental applications. 

 

Antioxidant Activity Enhanced

 

The researchers assessed the antioxidant potential of the nanoparticles by measuring total flavonoid content (TFC) and total phenolic content (TPC).

 

TFC was determined using an aluminium chloride colourimetric method, which measures the ability of flavonoids to form complexes with aluminium ions, detectable at 415 nm. TPC was quantified with the Folin-Ciocalteu reagent, which reacts with phenolic compounds to produce a blue chromogen, detected at 765 nm.

 

Both TFC and TPC were significantly higher in the nanoparticle formulations than in the leaf extract. These findings indicate that the surface-bound flavonoid and phenolic compounds enhanced the free radical scavenging capabilities of the nanoparticles.

 

This could be particularly valuable in applications aimed at mitigating oxidative stress, including cancer therapy, wound healing, and drug delivery.

 

Photocatalytic Potential for Water Treatment

 

Photocatalytic degradation studies demonstrated the potential of the nanoparticles in environmental cleanup. They successfully decolorized methyl orange dye in water, which the researchers used to simulate wastewater contamination. 

 

In the experiment, the nanoparticles were mixed with a methyl orange solution and sodium borohydride (NaBH₄) as a reducing agent. The team measured the dye’s absorbance at regular intervals to track its degradation.

 

Results showed efficient dye breakdown under mild conditions, which was attributed to the large surface area and reactive surface sites of the MLE silver nanoparticles, demonstrating their potential for environmental remediation.

 
https://www.azonano.com/news.aspx?newsID=41467

 

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Practical guide on innovative methods for decontaminating water with nanoparticles

 

06/08/2025

 

Main innovative methods for decontaminating water with nanoparticles

 

Water decontamination with nanoparticles covers a wide variety of techniques, from adsorbent nanomaterials and catalysts to graphene membranes and carbon nanotubes. Let's look at how the main proposals work and how they differ from traditional methods.

 

1. 'Reusable' nanoparticles based on iron and agro-industrial by-products

 

Spanish researchers have developed "recyclable" nanoparticles made from iron and vegetable water, a liquid waste product from the olive oil industry. These particles, encapsulated in a carbon shell, can effectively eliminate contaminants such as paracetamol, caffeine and pesticides, according to tests carried out by the Solar Water Treatment Unit of the Almería Solar Platform (CIEMAT-PSA) and the company Smallops SL

 

Their great advantage is that they maintain their decontaminating capacity during several cycles of use., which reduces costs and waste. Upon receiving sunlight (photons), the nanoparticles activate their bioremediation function and, after use, can be easily separated by simple sedimentation, without the need for expensive equipment or complex processes.

 

In experiments, these nanoparticles managed to reduce the concentration of pollutants by up to 50% in urban wastewater in just 120 minutes. Furthermore, they are easy to use because they are in the form of a very fine powder, smaller than a grain of salt, and their recovery after treatment is practical and economical.

 

The next step in the development of this technology is integrating nanoparticles into decontamination meshes or nets, optimizing efficiency and further facilitating its recovery. This would allow its use to be expanded to an industrial scale and improve the environmental sustainability of the process.

https://en.postposmo.com/Practical-guide-on-innovative-methods-for-decontaminating-water-with-nanoparticles/

 

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Removing chromium from polluted water using hyacinth

 

2017-09-07

 

The new method uses water hyacinth, a weed known for its ability to spread rapidly over water bodies. It is used for cleansing polluted water bodies owing to its remarkable capacity of absorbing pollutants.

http://www.indiawaterportal.org/articles/removing-chromium-polluted-water-using-hyacinth

 

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Removing fluoride with nanoparticles

  

2017-08-29

 

 A low-cost method to remove fluoride from drinking water with specially made teabag-like pouches has been developed by a team of Indian researchers.
This method uses pouches covered with nanoparticles synthesised from organically-grown jojoba seeds to remove fluoride from water. Jojoba is easily available and nanoparticles used (iron and aluminum) are synthesised from waste byproducts of the oil extraction process from jojoba seeds.
After synthesis, nanoparticles are soaked onto a foam material—polyurethane foam—wherein they get stuck to the surface of the foam. Infusion pouches or bags are then made from the nanoparticle-coated foam sheet. The nanoparticles on the pouches attract fluoride in the water and they too get stuck to the surface of the pouch. This process is a commonly used water purification method called adsorption. 

 

http://www.indiawaterportal.org/articles/removing-fluoride-nanoparticles


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Copper and cadmium removal from synthetic industrial wastewater using chitosan and nylon 6.

 

2011

https://www.ncbi.nlm.nih.gov/pubmed/22359148

 
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"Smart rust" purifies water instead of polluting it

 

08-17-2023

 

A new study suggests that pouring rust into water may not be as counterintuitive as it sounds. A team of researchers has come up with a unique type of iron oxide nanoparticles – called “smart rust” – that surprisingly purifies water instead of contaminating it.

 

https://www.earth.com/news/smart-rust-purifies-water-instead-of-polluting-it/

 

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Got Milk? Lactate Helps Clean Polluted Soil

 

2009

 

http://cleantechnica.com/2009/12/17/got-milk-lactate-helps-clean-polluted-soil/

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Students invent natural way to purify polluted water

 

Nov 15, 2002 

http://www.cbc.ca/news/technology/students-invent-natural-way-to-purify-polluted-water-1.324915

 

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Method for treating oil slicks


http://www.freepatentsonline.com/4623468.html



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Newly Invented Bioglass Nanofibers Could Make Better CO2 Catcher

 

December 18, 2009

http://www.greenoptimistic.com/newly-invented-bioglass-nanofibers-could-make-better-co2-catchers-20091218/#.VSX1tZO-2zk



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Pumpkins Pull Pollutants out of Contaminated Soil

 

October 25, 2004 

 

http://www.scientificamerican.com/article/pumpkins-pull-pollutants/

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IN SITU REMEDIATION OF SOILS AND GROUND WATER CONTAINING ORGANIC CONTAMINANTS

http://www.freepatentsonline.com/y2014/0255099.html

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Remediation apparatus and method for organic contamination in soil and groundwater


http://www.freepatentsonline.com/5525008.html

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Hydrogen Peroxide and Horticulture

http://www.quickgrow.com/gardening_articles/hydrogen_peroxide_horticulture.html

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Peanut Husks Could Be Used Clean Up Waste Water

 

November 8, 2007


 http://www.sciencedaily.com/releases/2007/11/071108080114.htm

 
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PEARL Membrane: New “Swiss Army Knife” Cleans Up Water Pollution

 

June 1, 2021

 

First Used To Soak Up Oil in Water, New Sponge Sequesters Excess Phosphate From Water

 

Phosphate pollution in rivers, lakes, and other waterways has reached dangerous levels, causing algae blooms that starve fish and aquatic plants of oxygen. Meanwhile, farmers worldwide are coming to terms with a dwindling reserve of phosphate fertilizers that feed half the world’s food supply.

 

Inspired by Chicago’s many nearby bodies of water, a Northwestern University-led team has developed a way to repeatedly remove and reuse phosphate from polluted waters. The researchers liken the development to a “Swiss Army knife” for pollution remediation as they tailor their membrane to absorb and later release other pollutants...

 

https://scitechdaily.com/pearl-membrane-new-swiss-army-knife-cleans-up-water-pollution/


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TAML catalysts safely and effectively remove estrogenic compounds from wastewater

 

June 12, 2015

 Catalysts created by Carnegie Mellon University chemist Terrence J. Collins effectively and safely remove a potent and dangerous endocrine disruptor from wastewater.

 http://phys.org/news/2015-06-taml-catalysts-safely-effectively-estrogenic.html#nRlv

 

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Soils could keep contaminants in wastewater from reaching groundwater, streams

 

January 22, 2015

 http://phys.org/news/2015-01-soils-contaminants-wastewater-groundwater-streams.html#nRlv

 With endocrine-disrupting compounds affecting fish populations in rivers as close as Pennsylvania's Susquehanna and as far away as Israel's Jordan, a new research study shows that soils can filter out and break down at least some of these emerging contaminants. The results suggest that water pollution can be diminished by spraying treated wastewater on land rather than discharging it directly into streams, according to researchers in Penn State's College of Agricultural Sciences.

Using Penn State's 600-acre "Living Filter"—a wastewater reuse system less than a mile from the University Park campus—as a laboratory, researchers tested soil samples for the presence and accumulation of three estrogens. For almost three decades, more than 500 million gallons of treated wastewater from the campus has been sprayed annually from irrigation pipes onto this site, which is composed of cropland, grassland and forest.

To understand how endocrine-disrupting compounds behave in the soil, researchers extracted samples and analyzed for two natural estrogens, 17-beta-estradiol and estrone—hormones naturally produced by humans and animals, such as dairy cattle—and one synthetic estrogen, 17-alpha-ethynylestradiol—a compound in birth-control pills.


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CRIQ and INRS awarded a patent for a system that removes micropollutants from wastewater

January 12, 2016


In preliminary studies the patented membrane bioreactor system eliminated 99% of bisphenol-A (BPA) and other compounds in heavily contaminated wastewater. BPA, which is used in the manufacture of plastics, is a micropollutant thought to disrupt various physiological mechanisms. The system is designed for installation at factory outlets to treat wastewater at the source and can also be incorporated into wastewater treatment plants.


http://phys.org/news/2016-01-criq-inrs-awarded-patent-micropollutants.html#jCp


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Non-toxic corn starch could replace cyanide in gold mines

• May 14, 2013

 

In the gold-mining process, the precious metal is often extracted from low-grade ore in a technique known as gold cyanidation. As its name suggests, the process utilizes highly-poisonous cyanide, some of which ends up entering the environment in the mines’ tailings. That’s not so good. Scientists at Illinois’ Northwestern University, however, recently announced their discovery of a new gold recovery process that’s based on a non-toxic component of corn starch.
 

http://www.gizmag.com/corn-starch-gold-sequestration/27504/?li_source=LI&li_medium=default-widget

 

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Urban mining gets quicker and cleaner

 

23 Nov 2021

 

Electronic waste could be transformed from an environmental headache into a literal goldmine thanks to a technique known as flash Joule heating. The technique, which scientists at Rice University in the US have now expanded to include a broader range of materials, can be used to recover valuable metals from waste quickly and simply, without toxic solvents and with much less energy than current laboratory methods. The processed waste also contains a very low concentration of heavy metals, making it safe for agricultural use.

 

The world’s consumers produce more than 40 million tonnes of electronic waste each year. Since only about 20% of this e-waste is recycled, it is becoming an increasingly serious problem. Most of the rest ends up in landfills, which is disastrous for the environment – not least as it often contains heavy metals such as chromium (Cr), arsenic (As), cadmium (Cd), mercury (Hg) and lead (Pb), some of which are highly toxic.

 

 https://physicsworld.com/a/urban-mining-gets-quicker-and-cleaner/

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Companies such as Monsanto and DuPont have investments in plastic parts for reverse osmosis water purification machines. 

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Four dollars for a gallon of water? The dream of Monsanto and other corporations wanting to privatize water

 

April 18, 2012

http://www.naturalnews.com/035603_water_monopoly_privatization.html

 

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Companies such as BP,  including Procter & Gamble, have financial gain and incentive for chemicals that clean-up and purify different sources of water.

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Corexit

  

https://en.wikipedia.org/wiki/Corexit

  

Corexit (often styled COREXIT) is a product line of oil dispersants used during oil spill response operations. It is produced by Nalco Company, associated with BP and Exxon and an indirect subsidiary of Ecolab. Corexit was originally developed by the Standard Oil Company of New Jersey. Corexit is typically applied by aerial spraying or spraying from ships directly onto an oil slick. On contact with the dispersant, oil that would otherwise float on the surface of the water is emulsified into tiny droplets and sinks or (in the unusual case of sub-surface application) remains suspended in the water. In theory this allows the oil to be more rapidly degraded by bacteria (bioremediation) and prevents it from accumulating on beaches and in marshes.

 

Criticism

EPA whistleblower Hugh Kaufman gave an interview to Democracy Now during the height of the Deepwater Horizon Oil Spill news coverage and explained his views on the use of Corexit, saying "EPA now is taking the position that they really don’t know how dangerous it is, even though if you read the label, it tells you how dangerous it is. And, for example, in the Exxon Valdez case, people who worked with dispersants, most of them are dead now. The average death age is around fifty. It’s very dangerous, and it’s an economic — it’s an economic protector of BP, not an environmental protector of the public."

Marine toxicologist Riki Ott blamed BP for poisoning locals with Corexit, which she alleges they used to hide their responsibility. In August 2010 she wrote an open letter to the Environmental Protection Agency alleging that dispersants were still being used in secret and demanding that the agency take action.^[102] The letter was published in the Huffington Post. Ott told Al Jazeera, "The dispersants used in BP's draconian experiment contain solvents, such as petroleum distillates and 2-butoxyethanol. Solvents dissolve oil, grease, and rubber. It should be no surprise that solvents are also notoriously toxic to people, something the medical community has long known."



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Safer Water Worldwide

 

2006

 

CINCINNATI (Ivanhoe Broadcast News) -- In the United States, with just the turn of a knob, clean, drinkable water is right at our fingertips. That's not the case in many parts of the world. But new technology is making it possible for people worldwide to have drinkable water ... With a stir of a powerful powder.

You wouldn't drink dirty water straight out of a river. But in developing nations, tap water is not a choice.

"People have to share their drinking water sources with their animals. People many times drink from open ponds or streams," Greg Allgood, Ph.D., of P&G Children's Safe Drinking Water Program based in Cincinnati, tells Ivanhoe.

...And that leads to deadly water-borne illnesses. Dr. Allgood, an industrial toxicologist, is director of P&G's Children's Safe Drinking Water Program, a non-profit venture for the consumer-products giant.

http://www.ivanhoe.com/science/story/2006/12/222a.html

 
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There's a Surprisingly Easy Way to Remove Microplastics in Your Drinking Water

August 15, 2025

Tiny fragments of plastics are making their way deep inside our bodies in concerning quantities, particularly through our food and drink.

In 2024, scientists in China found a simple and effective means of removing them from water. The team ran tests on both soft water and hard tap water (which is richer in minerals).

They added in nanoplastics and microplastics before boiling the liquid and then filtering out any precipitates.

"Tap water nano/microplastics (NMPs) escaping from centralized water treatment systems are of increasing global concern, because they pose potential health risks to humans via water consumption," the researchers from Guangzhou Medical University and Jinan University write in their published paper.

In some cases, up to 90 percent of the NMPs were removed by the boiling and filtering process, though the effectiveness varied based on the type of water.

https://www.yahoo.com/news/articles/theres-surprisingly-easy-way-remove-230824392.html 

 

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Plugging up leaky graphene: New technique may enable faster, more durable water filters

May 07, 2015

Read more at: http://phys.org/news/2015-05-leaky-graphene-technique-enable-faster.html#jCp

Plugging up leaky graphene: New technique may enable faster, more durable water filters

May 07, 2015


Read more at: http://phys.org/news/2015-05-leaky-graphene-technique-enable-faster.html#jCp

Plugging up leaky graphene: New technique may enable faster, more durable water filters

May 07, 2015

Read more at: http://phys.org/news/2015-05-leaky-graphene-technique-enable-faster.html#jCp

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It is still debated the impact of some of these devices that would take moisture out of areas that would need moisture, such as a high desert. This would also include a tax on rainwater. Many groups claim that it is their right to have free water without being taxed.  It is debated if we should desalinate fresh water from the ocean. Some people even dig out pools called condensation pools, this is in order to collect moisture from the sky and turn it into water. Some have said we should make water pipelines to take water from melting areas of ice. The oceans need fresh water in order to balance out the salt content in the water. This is why we should also be cautious of how much water wew take out of rivers that flow out into the ocean. For more information on how we can collect and save water, view the article titled " Pollution Science 101 - Cancer Investigated (California) - http://pollutionscience101cancerinvestigated.blogspot.com ."

 

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Membranes that filter and destroy pollutants

 

31 March 2022

 

Decoration of nanofiltration membranes with catalysts lead to efficient removal and degradation of micropollutants. 

https://www.nature.com/articles/s41565-021-01064-2

 

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Decontaminating pesticide-polluted water using engineered nanomaterial and sunlight

 

January 15, 2020

 

The materials’ challenges

 

To make photoelectrodes (light-sensitive electrodes), Professor El Khakani has chosen titanium oxide (TiO2), a material that is very abundant, chemically stable, and used in many applications including white pigment in paints or sunscreens. Usually, this semiconducting material converts the light energy provided by UV rays into active charges. In order to take advantage of the entire solar spectrum, i.e. visible light in addition to UV, Professor El Khakani had to make the TiO2 films sensitive to visible sunlight. To this end, his team modified titanium oxide on an atomic scale by incorporating nitrogen and tungsten atoms using a plasma process. This doping reduces the photon energy required to trigger PEC in these novel photoelectrodes. 

 

https://bioengineer.org/decontaminating-pesticide-polluted-water-using-engineered-nanomaterial-and-sunlight/


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Solar Sponge Efficiently Makes Steam

 

It could be great for desalinating water and other applications.

 
July 25, 2014


http://www.popsci.com/article/science/solar-sponge-efficiently-makes-steam

 
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This Breakthrough Sponge Could Change How the World Gets Clean Water

  

July 6, 2025

 

A team of scientists has developed a groundbreaking sponge-like aerogel that can turn seawater into clean drinking water using only sunlight. 

 

https://scitechdaily.com/this-breakthrough-sponge-could-change-how-the-world-gets-clean-water/ 

 

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“Magic” Cleaning Sponges Found to Release Trillions of Microplastic Fibers

  

August 7, 2025

 

https://scitechdaily.com/magic-cleaning-sponges-found-to-release-trillions-of-microplastic-fibers/ 

 

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Using graphene foam to filter toxins from drinking water

  

August 4, 2021

 

 

MIT-led research team fashions graphene foam into device that can extract uranium and other heavy metals from tap water.

 

https://news.mit.edu/2021/graphene-foam-filter-toxins-from-water-0804

 

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A device to convert plastic waste into fuel

 

2025

 

Specifically, the researchers are using a method known as pyrolysis, a process of using heat in the absence of oxygen to molecularly break materials down. In this case, it’s used to break plastics down to the components that produce fuels and other products.  

 

https://engineering.yale.edu/news-and-events/news/device-convert-plastic-waste-fuel

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Microrobots mop-up nanoplastics

10 August 2022

 

Catalytically active, self-propelled microrobots can trap and remove nanoplastics from water. 

 
https://www.nature.com/articles/s41565-022-01199-w

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First Living Robots Created by Assembling Living Cells From Frogs Into Entirely New Life-Forms

 

January 15, 2020

 

Tiny ‘xenobots’ assembled from cells promise advances from drug delivery to toxic waste clean-up.

 

A book is made of wood. But it is not a tree. The dead cells have been repurposed to serve another need.

 

Now a team of scientists has repurposed living cells—scraped from frog embryos—and assembled them into entirely new life forms. These millimeter-wide “xenobots” can move toward a target, perhaps pick up a payload (like a medicine that needs to be carried to a specific place inside a patient)—and heal themselves after being cut.

 

“These are novel living machines,” says Joshua Bongard, a computer scientist and robotics expert at the University of Vermont who co-led the new research. “They’re neither a traditional robot nor a known species of animal. It’s a new class of artifact: a living, programmable organism.”

 

The new creatures were designed on a supercomputer at UVM—and then assembled and tested by biologists at Tufts University. “We can imagine many useful applications of these living robots that other machines can’t do,” says co-leader Michael Levin who directs the Center for Regenerative and Developmental Biology at Tufts, “like searching out nasty compounds or radioactive contamination, gathering microplastic in the oceans, traveling in arteries to scrape out plaque.”

 

The results of the new research were published on January 13, 2020, in the Proceedings of the National Academy of Sciences.

 
https://scitechdaily.com/first-living-robots-created-by-assembling-living-cells-from-frog-embryos-into-entirely-new-life-forms/

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Featured Story: Stormwater Runoff

 

Here’s how you can prevent chemicals, garbage and other debris from winding up on the local beach

 

 http://www.epa.gov/region9/water/npdes/stormwater-feature.html

 Stormwater systems were originally intended to route rainwater quickly off the streets during a heavy storm. Unfortunately, these systems can carry pollutants such as pesticides, bacteria and chemicals through city streets and straight to our waters. Stormwater pollution can include chemicals, fast food wrappers, cigarette butts, Styrofoam cups, sewage overflow, cooking oil, bacteria from pet waste, used motor oil, fertilizers, paint and construction debris.

Used oil from a single oil change can pollute up to one million gallons of freshwater. Improper disposal of used oil, which includes oil leaking from cars, contributes significantly to stormwater pollution. The EPA estimates that American households improperly dump about 193 million gallons of used oil every year, or roughly the equivalent of 17 Exxon Valdez oil spills.
And household cleaners can hurt the environment as well, if not disposed of properly. One ounce of household bleach requires 312,000 ounces of water to be safe for fish. Even biodegradable soaps can pose problems for aquatic life — in order for one ounce of biodegradable detergent to be safe for fish, it needs to be diluted by almost 20,000 ounces of water.



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UCLA nanoscientists develop safer, faster way to remove pollutants from water

 

November 23, 2015

 

 

Using nanoparticles filled with enzymes proves more effective than current methods

https://scitechdaily.com/ucla-nanoscientists-develop-a-better-way-to-remove-pollutants-from-water/

 

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Tiny technology that can find pollution in South Africa’s water and trap it

05/05/2025

 

Nanotechnology is the use of materials that are one-billionth of a metre (a nanometre) in size. One of its potential uses is to clean up whatever is contaminating water supplies. Analytical chemist Philiswa Nomngongo, a leading researcher in nanotechnology for water in South Africa, tells The Conversation Africa what kinds of devices are being produced with nanotechnology and what they can do. 

 

How can nanotechnology help?

 

Monitoring water quality is very important. To find solutions, we first need to know what the problem is. Most of South Africa’s water contamination problems stem from inadequate monitoring. So, my research group and researchers in the Department of Chemical Sciences at the University of Johannesburg are using nanotechnology to identify the problems in different sources, like wastewater or river water – even in remote rural areas.

 

These are some of the ways in which nanotechnology can help find problems in our water supplies and fix them:

 

• Sensors: for example, tiny materials can be modified with a biological element (like enzymes or DNA) to rapidly detect and analyse what is contaminating water.

• Membranes made up of tiny materials that can sample the water and trap and remove pollutants at the same time.

• Photocatalytic materials that activate chemical reactions when they are exposed to light and break down polluting substances.

 

This technology can help countries meet the United Nations’ sustainable development goal six: achieving clean and available water and sanitation for all.

 
https://smartwatermagazine.com/blogs/philiswa-nomngongo/tiny-technology-can-find-pollution-south-africas-water-and-trap-it

 

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Combat Chemical Engineers Call On Nanoparticles to Polluted Groundwater.

 

http://www.thefreelibrary.com/Chemical+Engineers+Call+On+Nanoparticles+to+Combat+Polluted...-a0228229418


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Bio-Remediation or Bio-Hazard? Dispersants, Bacteria and Illness in the Gulf

 

09/17/2010

 

http://www.huffingtonpost.com/riki-ott/bio-remediation-or-bio-ha_b_720461.html

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The Magnetic Wand That Cleans Oil Spills: Upgrade

  

Dec 12, 2014

 https://www.youtube.com/watch?v=lYM324yDH-Q


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Environmentally Correct Oil Spill Cleanup Solution with Hay & Straw

 

May 13, 2010

In this video posted by the Walton County (FL) Sheriff's Department, Darryl Carpenter, Vice President of Florida-based CW Roberts Contracting and sub-contractor Otis Goodson, shows how hay, hay grass and straw can be used as a very effective environmentally correct oil spill cleanup solution.

In a scene reminiscent of a primetime cooking show, the Carpenter and Goodson video shows how Coastal Bermuda and Bahia hay could be scattered over the surface of the ocean with hay blowers to absorb the oil. To start, the two men pour oil into two large pans of water, stir in the hay, add a little "wave action," then skim off the oil-soaked hay...

https://www.youtube.com/watch?v=H7JkFW5nwMQ

 

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Sponges made from wood waste may soak up oil spills

 

May 6, 2014

As the Deepwater Horizon incident showed us, oil spills can be huge environmental disasters. That said, there are also considerable challenges in dealing with the waste products generated by the forestry and agriculture industries. Now, scientists from Switzerland's Empa research group have come up with a method of addressing the one problem with the other – they've developed sponges made from cellulose waste, that can soak up 50 times their own weight in oil.

http://www.gizmag.com/nanocellulose-oil-spill-sponges/31939/?li_source=LI&li_medium=default-widget

 

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Pollution-absorbing bikini "cleans the water" while its wearer swims

October 13, 2015

http://www.gizmag.com/swimsuit-absorbs-water-pollution/39832/?li_source=LI&li_medium=default-widget

 We've previously heard about air-purifying clothing, so perhaps it shouldn't come as a surprise to find out that scientists have now developed the aquatic equivalent – a bikini top that filters pollutants out of the water around the wearer. And yes, the technology could have other uses...

Sponge is derived from heated sucrose, and is at once highly hydrophobic (it repels water) while also being very good at absorbing harmful contaminants. This means that it can fill up just on pollutants – up to 25 times its own weight worth of them – without also becoming saturated with water.

The contaminants are stored in pores within the material, so they shouldn't come into contact with the wearer. In fact, the only way of releasing them is to heat the Sponge to at least 1,000 ºC (1,832 ºF). This can be done up to 20 times before the inserts start losing their absorbency...

 

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New technique may clean contaminated soil quickly

 

October 5, 2009 

 http://health.gaeatimes.com/2009/10/05/new-technique-may-clean-contaminated-soil-quickly-13028/

 

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Articles about Contaminated Soil

( Removing lead from contaminated soil shows mixed results Levels of toxins in children's blood go down but not as much as had been expected. )

 

http://articles.baltimoresun.com/keyword/contaminated-soil

 
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Clemson Research Cleans Up With Edible Oil

http://www.sciencedaily.com/releases/2006/09/060913185820.htm

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How Mussel Farming Could Help to Clean Fouled Waters

http://www.aquaknow.net/es/node/18205

 

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Designing Wetlands to Remove
Drugs and Chemical Pollutants

 

http://e360.yale.edu/feature/designing_wetlands_to_remove_drugs_and_chemical_pollutants/2856/


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Water Pollution: Sun-Powered Cleanup Crews

 

Todd learned that species in different ecosystems—such as those in streams, ponds, marshes, and tide pools—have remarkable capacities to self-clean and self-repair. He found that plants such as rushes filter out suspended materials in the water. Others absorb toxic metals such as mercury and lead, and still others produce antibodies that kill organisms capable of causing disease...

 Thus, John Todd and his colleagues at the New Alchemy Institute invented Living Machines to do the same job as nature. Using a collection of tanks that hold different aquatic ecosystems, Living Machines (also known as Eco-Machines) take black water, or sewage, and return it to its natural state, unpolluted by human waste.

http://www.planetseed.com/relatedarticle/water-pollution-sun-powered-cleanup-crews


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Ocean Cleanup project to test its first trash-catching barriers in Dutch waters

 

December 30, 2015

 Scooping up all the plastic waste in the world's oceans would be a massive undertaking given that scientists estimate there's around 5 trillion pieces of it currently bobbing about in the water. But the Ocean Cleanup project believes it is up to the challenge and has today announced plans for the first real-world test of its rubbish collection barriers off the coast of The Netherlands.

http://www.gizmag.com/ocean-cleanup-project-dutch-waters/41104/ 

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Ocean-friendly Seabin sucks up surrounding sea trash

 

December 21, 2015

The mounting plastic waste in the world's oceans has been the subject of of some pretty bold environmental undertakings, perhaps none more so than the Ocean Cleanup Project aiming to eradicate the Great Pacific Garbage Patch. The Seabin Project represents a smaller-scale approach, but it is noble in its aspirations all the same. Installation in ports and marinas sees this ocean-friendly trash can suck up the surrounding debris and even remove oil from the water.

http://www.gizmag.com/seabin-ocean-trash/41023/?li_source=LI&li_medium=default-widget

 
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Sensor detects toxins leaching from plastic

 

December 10, 2015 

 

In much the same way PAC-MAN gobbles through an intense maze of dots eating and destroying its aggressors, researchers from the Charles E. Schmidt College of Medicine at Florida Atlantic University have revealed for the first time how a similar mechanism in the eye lens does exactly the same thing. They have discovered that cells in close proximity to each other can sense when a cell is dying due to environmental stressors like UV light, smoke and other pollutants, and eat the cell before it becomes toxic.In a study just published in the Journal of Biochemistry and Molecular Biology, these researchers not only demonstrate that this happens with lens cells, but they uncover the molecules that are required to do it. They also reveal that the molecules needed for the cells to eat each other are degraded by UV light. And when that happens, the cells lose the ability to eat each other. Since these systems are not confined to the eye lens and diseases of the eye such as cataracts, uncovering the mechanisms and functions will provide important information in more complex tissues and disease states.

http://phys.org/news/2015-12-sensor-toxins-leaching-plastic.html



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How To Decontaminate Soil

By Tonya Sandersfeld

 http://www.howtodothings.com/home-and-garden/a3187-how-to-decontaminate-soil.html

 
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Soil decontamination method


http://patents.com/us-5275507.html

 
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Polymer breakthrough could revolutionize water purification

 

December 22, 2015

 

http://phys.org/news/2015-12-polymer-breakthrough-revolutionize-purification.html?utm_source=menu&utm_medium=link&utm_campaign=item-menu

We've all seen the Febreze air fresheners, which employ a derivative of corn starch to trap invisible air pollutants in the home and remove unwanted odors.

A team of Cornell researchers has used the same material found in Febreze, cyclodextrin, to develop a technique that could revolutionize the water-purification industry.

The team is led by Will Dichtel, associate professor of chemistry and chemical biology and a 2015 MacArthur Foundation Fellowship winner. His group invented a porous form of cyclodextrin that has displayed uptake of pollutants through adsorption at rates vastly superior to traditional activated carbon – 200 times greater in some cases.

Activated carbons have the advantage of larger surface area than previous polymers made from cyclodextrin – "more sites for pollutants to stick to," Dichtel said – but they don't bind pollutants as strongly as cyclodextrin.

"What we did is make the first high-surface-area material made of cyclodextrin," Dichtel said, "combining some of the advantages of the activated carbon with the inherent advantages of the cyclodextrin. When you combine the best features of those two materials, you get a material that's even better than either class.

 

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Research develops plasma-based process to synthesize photothermal materials for water purification

14/04/2025

https://smartwatermagazine.com/news/linstitut-national-de-la-recherche-scientifique-inrs/research-develops-plasma-based-process

 

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Molecular nanocages can remove 80–90% of PFAS from water

April 14, 2025

https://pfasproject.com/2025/04/14/molecular-nanocages-can-remove-80-90-of-pfas-from-water/

 

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Sunlight-activated material turns PFAS in water into harmless fluoride

  

August 8, 2025

 

https://phys.org/news/2025-08-sunlight-material-pfas-harmless-fluoride.html

 

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Recycling Breakthrough Turns “Forever Chemicals” Into Renewable Resources

 

May 19, 2025 

 

Scientists at the University of Leicester have developed a technique that uses soundwaves to separate materials in fuel cells within seconds. 

 

A new technique that uses sound waves to separate materials for recycling could help prevent harmful chemicals from leaching into the environment.

 

Researchers at the University of Leicester have reached a major breakthrough in fuel cell recycling by developing a method to efficiently separate valuable catalyst materials and fluorinated polymer membranes (PFAS) from catalyst-coated membranes (CCMs).

 

This advancement tackles significant environmental concerns related to PFAS, often called “forever chemicals,” which are known to pollute drinking water and pose serious health risks. The Royal Society of Chemistry has called for government action to lower PFAS levels in UK water supplies.

 

https://scitechdaily.com/recycling-breakthrough-turns-forever-chemicals-into-renewable-resources/ 

 

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Scientists make "Impossible Material" ... by accident

 

July 30, 2013

In an effort to create a more viable material for drug delivery, a team of researchers has accidentally created an entirely new material thought for more than 100 years to be impossible to make. Upsalite is a new form of non-toxic magnesium carbonate with an extremely porous surface area which allows it to absorb more moisture at low humidities than any other known material. "The total area of the pore walls of one gram of material would cover 800 square meters (8611 sq ft) if you would 'roll them out'", Maria Strømme, Professor of Nanotechnology at the Uppsala University, Sweden tells Gizmag. That's roughly equal to the sail area of a megayacht. Aside from using substantially less energy to create drier environments for producing electronics, batteries and pharmaceuticals, Upsalite could also be used to clean up oil spills, toxic waste and residues.


http://www.gizmag.com/upsalite-impossible-material/28393/?li_source=LI&li_medium=default-widget


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'Dry water' could be used to store carbon dioxide

 

August 25, 2010 

 

 

http://www.gizmag.com/dry-water-stores-carbon-dioxide/16138/

 

You know, I’m pretty sure I remember a Far Side cartoon or something, where someone was selling powdered water – “Just add water!” Well, dry water isn’t quite the same thing. It’s 95 percent liquid water, but that water takes the form of tiny droplets each encased in a tiny globe of silica. The resultant substance is dry and granular. It first came to light in 1968, and was used in cosmetics. More recently, a University of Liverpool research team has been looking into other potential uses for the substance. They have found several, but most interesting is its ability to store gases such as carbon dioxide.
In laboratory experiments, study leader Professor Andrew Cooper and his team found that dry water absorbed over three times as much CO2 as uncombined water and silica in the same amount of time. The gas combined with the water molecules to form a storable hydrate, which Cooper believes makes it ideal for reducing global warming.
The Liverpool team also found that dry water could be used to store methane gas. As methane is a component of natural gas, they believe this discovery could make natural gas a more environmentally-viable energy source. They suggest that dry water could be used to absorb and transport the methane from stranded deposits of natural gas, or as a storage medium for methane fuel for cars.


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Sucking CO2 out of the atmosphere to create carbon nanofibers

 

August 20, 2015

Carbon nanofibers hold tremendous potential. They may one day be put to use in tougher bulletproof vests, artificial muscles or rebuilding damaged hearts, just to name a few possibilities. But could the greatest gift these little wonders offer humanity be not what they bring into the world but what they take out of it? Scientists have developed a technique that could pull the mounting carbon dioxide in our atmosphere and transform it into carbon nanofibers, resulting in raw materials for use in anything from sports gear to commercial airliners.

http://www.gizmag.com/c02-atmosphere-carbon-nanofibers/39015/?li_source=LI&li_medium=default-widget 

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Copper Foam Provides a New Way to Turn CO2 into Useful Chemicals

 

September 16, 2014

 

 

Copper is the only metal that can reduce CO2 to useful hydrocarbons. A foam of copper offers sponge-like pores and channels, providing more active sites for CO2 reactions than a simple surface. 

 

A team of researchers at Brown University’s Center for Capture and Conversion of CO2 have discovered that copper foam could provide a new way of converting excess CO2 into useful industrial chemicals, including formic acid.

 

Providence, Rhode Island (Brown University) — A catalyst made from a foamy form of copper has vastly different electrochemical properties from catalysts made with smooth copper in reactions involving carbon dioxide, a new study shows. The research, by scientists in Brown University’s Center for the Capture and Conversion of CO2, suggests that copper foams could provide a new way of converting excess CO2 into useful industrial chemicals.

https://scitechdaily.com/copper-foam-provides-new-way-turn-co2-useful-chemicals/

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New material promises more efficient carbon capture

 

March 12, 2015

We've already seen a number of technologies developed for capturing carbon dioxide emissions from smokestacks or other sources, but many of them have a limitation – in order to reclaim the captured CO2 for disposal, a considerable amount of energy is needed. Now, however, scientists at the University of California, Berkeley have developed a new carbon-capture material that requires far less energy in order to give up its payload.
The material is a type of metal-organic framework (MOF), which are composites made from metal and organic compounds. In this case, the metal is either magnesium or manganese (depending on the application) and the organic compounds are nitrogen-based diamines.
Like other MOFs, it has a porous structure featuring microscopic parallel channels.
When the correct temperature and pressure are maintained, CO2 molecules in air passing through those channels bind with the material. The process gets more effective as the filtration process continues, as subsequent molecules bind with those that are already trapped in the MOF.
The temperature at which it works can range from room temperature to over 100 ºF (38 ºC) depending on how the diamines are synthesized, while the required pressure varies with the type of metal used. Once the material is saturated, it can be made to release the CO2 molecules simply by heating it to a temperature that's a total of 50 ºC (90 ºF) warmer than the temperature at which they were captured.
By contrast, many power plants currently utilize a carbon-capture technique in which flue gases are filtered by being bubbled through water containing amines (of which diamines are one type), the CO2 molecules binding with them. In order to subsequently release the captured CO2 from the amines, however, the water has to be heated to a temperature of 120 to 150 ºC (250 to 300 ºF). According to the university, the whole process can sometimes consume up to 30 percent of the power generated at the plant.
Plans now call for the material to be tested in a pilot study at a power plant. Lead scientist Prof. Jeffrey Long also hopes that it could be used to purify the air in submarines, or even aboard the International Space Station.

http://www.gizmag.com/carbon-capture-mof/36525/



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A simple chemical twist turns plastic waste into a carbon-soaking sponge

 

April 14, 2022

 

Plastic pollution and industrial carbon emissions are two of the most pressing environmental challenges the modern world faces. And researchers at Rice University have come up with an innovative solution to tackle both at the same time. By chemically treating plastic waste, they have turned it into an ultra-porous material that can soak up carbon dioxide.

 

The particles could be used in industrial and power plant smoke stacks to capture carbon dioxide from flue gases. “It is a win-win,” says professor of chemistry James M. Tour. “Two trash problems work together to solve each other. You’re essentially taking something of lower value and using it to make something of higher value.”

 

Most of the plastic waste produced in the world today ends up in landfills or littering the environment. Conventional mechanical recycling methods to recycle plastic typically give lower-quality materials that are used to make low-value products. Another technique called pyrolysis that heats up plastic waste gives waxes and oils and extremely low-value carbon products.

https://www.anthropocenemagazine.org/2022/04/researchers-have-turned-plastic-waste-into-a-carbon-soaking-sponge/

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Scalable Method for Porous Graphene Membranes for CO2 Capture

Apr 17 2025

https://www.azonano.com/news.aspx?newsID=41358

 

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Carbon Capture Reimagined: New Material Removes CO₂ From Air Like a Tree

 

June 28, 2025

 

The concept may sound futuristic: at ETH Zurich, researchers from multiple disciplines are collaborating to combine conventional materials with microorganisms like bacteria, algae, and fungi. Their shared goal is to create living materials that gain useful properties through microbial metabolism—“such as the ability to bind CO₂ from the air by means of photosynthesis,” explains Mark Tibbitt, Professor of Macromolecular Engineering at ETH Zurich.

 

Now, an interdisciplinary team led by Tibbitt has brought this idea to life. They successfully embedded photosynthetic bacteria, known as cyanobacteria, into a printable gel, creating a material that is alive, capable of growing, and actively capturing carbon from the atmosphere. The team introduced their “photosynthetic living material” in a recent study published in Nature Communications.

 

https://scitechdaily.com/carbon-capture-reimagined-new-material-removes-co%e2%82%82-from-air-like-a-tree/ 

 

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Using Sunlight to Alleviate Global Warming: Breakthrough in Decomposing CO2 With High Efficiency

June 22, 2021

 

Scientists find a way to efficiently use visible light from the sun to break down CO2, open doors to novel means of alleviating global warming.

 

Carbon dioxide (CO₂) emissions from human activities have risen drastically over the last century and a half and are seen as the primary cause of global warming and abnormal weather patterns. So, there has been considerable research focus, in a number of fields, on lowering our CO₂ emissions and its atmospheric levels. One promising strategy is to chemically break down, or ‘reduce,’ CO₂ using photocatalysts — compounds that absorb light energy and provide it to reactions, speeding them up. With this strategy, the solar-powered reduction of CO₂, where no other artificial source of energy is used, becomes possible, opening doors to a sustainable path to a sustainable future.

 

 A team of scientists led by Drs. Shinji Kawasaki and Yosuke Ishii from Nagoya Institute of Technology, Japan, have been at the forefront of efforts to achieve efficient solar-energy-assisted CO₂ reduction. Their recent breakthrough is published in Nature’s Scientific Reports.

 

Their research began with the need to solve the limited applicability problem of silver iodate (AgIO₃), a photocatalyst that has attracted considerable attention for being useful for the CO₂ reduction reaction. The problem is that AgIO₃ needs much higher energy than that which visible light can provide to function as an efficient photocatalyst, and visible light is the majority of solar radiation. 

 

Scientists have attempted to work around this efficiency problem by combining AgIO₃ with silver iodide (AgI), which can efficiently absorb and utilize visible light. However, AgIO₃-AgI composites have complicated synthesis processes, making their large-scale manufacturing impractical. Further, they don’t have structures that offer efficient pathways for the transfer of photoexcited electrons (electrons energized by light absorption) from AgI to AgIO₃, which is key to the composite’s catalytic activity. 

https://scitechdaily.com/using-sunlight-to-alleviate-global-warming-breakthrough-in-decomposing-co2-with-high-efficiency/

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Breakthrough Sees Development of Light-Emitting Solid Carbon From CO2 Gas

August 30, 2021

 

44.01 secures $5M to turn billions of tons of carbon dioxide to stone. Reducing global greenhouse gas emissions is an important goal, but another challenge awaits: lowering the levels of CO2 and other substances already in the atmosphere. One promising approach turns the gas into an ordinary mineral through entirely natural processes; 44.01 hopes to perform this proce… 

 

https://science-atlas.com/technology/breakthrough-sees-development-of-light-emitting-solid-carbon-from-co2/

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Small, Shapeshifting Catalytic Nanoparticles Steer Carbon Dioxide Conversion

 

August 7, 2025

 

First-of-its-kind multimodal study reveals that smaller catalytic nanoparticles transform while converting carbon dioxide, unlike their larger counterparts

 

UPTON, N.Y. — Researchers from the U.S. Department of Energy’s (DOE) Brookhaven National Laboratory have discovered that the size of catalytic nanoparticles determines how their shape and structure transform during chemical reactions. With insights into the nanoparticles’ atomic-scale behavior as they convert carbon dioxide into useful fuel — and a better understanding of how structural changes impact catalytic performance — researchers are newly positioned to design more effective catalysts for industrial applications.

 

Catalysts are substances that speed up chemical reactions. Though they may temporarily shapeshift to accelerate chemical transformations, they are not permanently altered, enabling them to facilitate subsequent reactions. In a new multimodal study, recently published in the Journal of the American Chemical Society, Brookhaven researchers leveraged several powerful techniques to characterize a catalyst made up of cobalt oxide nanoparticles that sit atop a cerium oxide base. In contrast to commonly used catalyst ingredients, like platinum or palladium, cobalt and cerium are significantly more abundant and less expensive.

 

“We previously found that this cobalt-cerium oxide nanocatalyst system behaved differently when the cobalt-containing nanoparticles were smaller, but we didn’t know why,” said Kaixi Deng, first author on the paper who conducted this research at Brookhaven Lab while he was a graduate student at Stony Brook University. Deng is now a postdoctoral researcher at DOE’s Argonne National Laboratory.

 

In some cases, the nanoparticles catalyzed the conversion of carbon dioxide to carbon monoxide. Other times, the reaction yielded methane — and sometimes the researchers observed a combination of both products.

 

“It’s important to control the morphology of the catalyst so reactions can yield the desired products, or ratio of products,” explained Jose Rodriguez, leader of the Catalysis: Reactivity and Structure group in Brookhaven’s Chemistry Division and co-lead author on the paper. “That’s how we optimize catalysts and make them more efficient for different applications.”

 

The research team expected the interface between cobalt and cerium oxide to play an important role in this behavior, and they used standard techniques in catalysis science, like in-situ X-ray absorption spectroscopy (XAS) and infrared spectroscopy, to start exploring this hypothesis.

 

“There was still an important part missing,” said Deng. “That’s why we wanted to take more direct measurements of this interface — ones that could show us what was happening during chemical reactions.”

 

https://www.bnl.gov/newsroom/news.php?a=122531

 

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Room Temperature Conversion of CO₂ to CO: A New Way to Synthesize Hydrocarbons

 

November 2, 2020

 

New method could potentially reduce carbon dioxide emission into the atmosphere and slash costs of chemical manufacturing.

https://www.nist.gov/news-events/news/2020/11/room-temperature-conversion-co2-co-new-way-synthesize-hydrocarbons


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Coffee grounds recycled as carbon capture material

September 8, 2015

Coffee grounds are not exactly noxious despoilers of the environment, but many millions of tons of them are generated every year and simply disposed of with other vegetable matter and food waste. Now, researchers have devised a way to utilize this innocuous waste product to get rid of a much more dangerous one. By modifying used coffee grounds into a carbon capture material, the new product may provide a simple, inexpensive way to remove a prolific and harmful greenhouse gas from the atmosphere.

http://www.gizmag.com/coffee-carbon-capture-methane/39299/?li_source=LI&li_medium=default-widget

 

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Photosynthetic living material uses bacteria to capture CO₂ in two different ways

June 19, 2025

Researchers are developing a living material that actively extracts carbon dioxide from the atmosphere. Photosynthetic cyanobacteria grow inside it, forming biomass and solid minerals and thus binding CO2 in two different manners.

https://techxplore.com/news/2025-06-photosynthetic-material-bacteria-capture-ways.html

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MIT’s super carbon Capture tech is 6 times faster, 20% cheaper than rivals

 

 May 21, 2025

 

This novel carbon capture system eradicates the common trade-off faced by carbon capture systems to boost overall efficiency.

https://interestingengineering.com/innovation/mits-carbon-capture-tech-6x-faster

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Nanofiltration approach can solve a bottleneck for CO₂ capture and conversion

May 20, 2025

In the quest to combat climate change, the need for efficient carbon capture and conversion technologies has never been more urgent. One promising solution that is gaining traction in the scientific community is the use of nanofiltration technology. Nanofiltration, a type of membrane filtration that operates on a nanometer scale, has the potential to address a critical bottleneck in the process of capturing and converting carbon dioxide (CO₂).

https://www.lifetechnology.com/blogs/life-technology-technology-news/nanofiltration-approach-can-solve-a-bottleneck-for-co-8322-capture-and-conversion

 

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Sunlight-powered system mimics plants to power carbon capture

May 12, 2025

Current methods of capturing and releasing carbon are expensive and so energy-intensive they often require, counterproductively, the use of fossil fuels. Taking inspiration from plants, Cornell University researchers have assembled a chemical process that can power carbon capture with an energy source that's abundant, clean and free: sunlight.

The research could vastly improve current methods of carbon capture -- an essential strategy in the fight against global warming -- by lowering costs and net emissions.

In the study, researchers found that they can separate carbon dioxide from industrial sources by mimicking the mechanisms plants use to store carbon, using sunlight to make a stable enol molecule reactive enough to "grab" the carbon. They also used sunlight to drive an additional reaction that can then release the carbon dioxide for storage or reuse. It's the first light-powered separation system for both carbon capture and release. Graduate student Bayu Ahmad is first author.

https://www.sciencedaily.com/releases/2025/05/250512153400.htm

 

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Catalytic Combo Converts CO₂ to Solid Carbon Nanofibers

 

January 11, 2024

https://www.bnl.gov/newsroom/news.php?a=121635

 
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New method stores high-density methane in graphene-coated nanoporous carbon

 

June 27, 2025

https://www.lifetechnology.com/blogs/life-technology-technology-news/new-method-stores-high-density-methane-in-graphene-coated-nanoporous-carbon

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Solving the mystery of an ancient enzyme could lead to new carbon capture strategies

 

June 27, 2025 

 

Researchers at the University of Illinois Urbana-Champaign have discovered important new clues in the mystery of how an ancient enzyme can turn atmospheric carbon into biomolecules, a natural process that could be helpful in developing new methods for converting greenhouse gases like carbon dioxide into useful chemicals.

 

As deforestation and the use of fossil fuels cause atmospheric gases, like carbon dioxide (CO₂), to rise to unprecedented levels, many scientists have turned to ancient biology searching for solutions to combat the imbalance of these gases in the atmosphere. From the beginning of life on Earth microscopic organisms have found ways to convert atmospheric carbon dioxide (CO₂) and carbon monoxide (CO) into useful biomolecules.

 

These organisms use specialized biological catalysts, or enzymes, to "fix" these gases into molecular building blocks. Scientists have been particularly interested in understanding how one special Ni-containing ancient enzyme—acetyl-CoA synthase (ACS)—takes in carbon dioxide and carbon monoxide and converts them into acetyl-CoA, which is a key biomolecule that metabolizes sugars, lipids, and proteins inside cells.

 
https://phys.org/news/2025-06-mystery-ancient-enzyme-carbon-capture.html

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Nanostructure Combines Copper, Gold and Silver To Give Carbon Capture and Utilization a Boost

March 16, 2022


https://scitechdaily.com/nanostructure-combines-copper-gold-and-silver-to-give-carbon-capture-and-utilization-a-boost/

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New Technology Keeps Surfaces Sterile With Silver and Electricity 

March 25, 2025

Metals like silver, gold and copper can kill bacteria and viruses. An electric current can also eliminate microorganisms. A team of U of A researchers combined the two approaches and created a new type of antimicrobial surface. 

“It is a synergistic effect,” said physicist Yong Wang, one of the lead researchers on the project. “It’s not like 1+1=2. When we combine the two, it’s much more effective.” 

In lab tests, the new technology, which uses thin nanowires of silver to carry a microampere electric current, eliminated all the E. coli bacteria on glass surfaces. 

https://news.uark.edu/articles/77049/new-technology-keeps-surfaces-sterile-with-silver-and-electricity

 

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Eco-Friendly Alchemy: Turning Waste Into Silver Using Everyday Oils

 

May 18, 2025 

 

Silver is becoming harder to mine, but researchers in Finland have found a creative and eco-friendly way to recover it from waste using common fatty acids and hydrogen peroxide.

 

These mild, green solvents not only dissolve silver efficiently but also allow for easy recycling of the acids themselves.

 

https://scitechdaily.com/eco-friendly-alchemy-turning-waste-into-silver-using-everyday-oils/ 

 

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Cheap Catalyst Turns Acids Into Pharmaceutical Gold

  

July 11, 2025

 

Photoactivated ketones show strong potential as hydrogen atom transfer photocatalysts, enabling the activation of carboxylic acids and the formation of new C–C, C–S, and C–Cl bonds.

 

Carboxylic acids are common components in bioactive compounds and serve as widely available building blocks in organic synthesis. When transformed into carboxy radicals, these acids can initiate the formation of valuable carbon-carbon and carbon-heteroatom bonds, a key step in the creation of new materials and pharmaceutical agents. Despite their utility, few existing methods rely on cost-effective catalysts.

 

Addressing this gap, a team from WPI-ICReDD and the University of Shizuoka developed a straightforward hydrogen atom transfer (HAT) strategy that selectively converts carboxylic acids into carboxy radicals. This method employs xanthone, a commercially available and inexpensive organic ketone, as the photocatalyst. The study was recently published in the Journal of the American Chemical Society.

 

https://scitechdaily.com/cheap-catalyst-turns-acids-into-pharmaceutical-gold/

 

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Scientists Turn Discarded Wood Waste Into Valuable Chemicals

 

April 14, 2025 

 

A new enzyme can turn lignin waste into valuable chemicals using green, hydrogen peroxide-based processing, offering a cleaner, sustainable alternative to petroleum-based methods.

 

Approximately 98% of lignin, a by-product of forestry derived from plants, is currently discarded. However, a newly discovered enzyme may enable the efficient extraction of valuable molecules from this waste using environmentally friendly, green chemistry methods.

 

https://scitechdaily.com/scientists-turn-discarded-wood-waste-into-valuable-chemicals/ 

 

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Using lightning to make ammonia out of thin air

 

July 23, 2025

 

 

Scientists have developed lightning-produced ammonia in gas form - a new, more efficient method that brings us closer to sustainable production of ammonia and transition to a hydrogen-based economy.

 

https://www.sydney.edu.au/news-opinion/news/2025/07/04/using-lightning-to-make-ammonia-out-of-thin-air.html

 

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Liquid laundry additive turns clothes into air purifiers

October 1, 2012

A laundry additive created by researchers from the University of Sheffield and the London College of Fashion turns clothing into a photocatalytic material that can help remove nitrogen oxides (NOx) from the air. One of the most prominent air pollutants, nitrogen oxides are emitted from the exhausts of ICE-powered vehicles and aggravate asthma and other respiratory diseases. The researchers claim one person getting around town in clothing treated with the additive for a day would be able to remove roughly the same amount of nitrogen oxides produced by the average family car each day.

http://www.gizmag.com/catclo-laundry-additive-air-purifying-clothing/24371/

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New hydrogel nanocomposite treatments turn water waste to fertilizer

Jun 11, 2025

Novel nanocomposites remove and recover nutrients from wastewater, subsequently upcycling them as agricultural fertilizers or as biorefinery feedstocks, while simultaneously mitigating the occurrence of harmful algal blooms.

https://www.nanowerk.com/nanotechnology-news3/newsid=67033.php

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Double-Duty: New Catalyst Generates Hydrogen Fuel While Cleaning Up Wastewater

 

April 4, 2021

 

Turning Wastewater into Hydrogen Fuel with Sunlight

 

Hydrogen is a pollution-free energy source when it’s extracted from water using sunlight instead of fossil fuels. But current strategies for “splitting” or breaking apart water molecules with catalysts and light require the introduction of chemical additives to expedite the process. Now, researchers reporting in ACS ES&T Engineering have developed a catalyst that destroys medications and other compounds already present in wastewater to generate hydrogen fuel, getting rid of a contaminant while producing something useful.

 
https://scitechdaily.com/double-duty-new-catalyst-generates-hydrogen-fuel-while-cleaning-up-wastewater/

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Study shows using oat hulls for power has considerable benefits to the environment and human health

September 25, 2015

Biomass burning sometimes gets a bad rap. That's because many associate the burning of living and dead vegetation with human-caused fires and clearing of land that release unhealthy particles and gases that spur global warming.


But what if you burned biomass in a controlled environment, such as in a power plant, that at least partially replaces using a fossil fuel? Would there be demonstrable environmental and health benefits?

In a new study, researchers at the University of Iowa report that burning oat hulls had considerable benefits to the environment as well as to human health. The study examined the practices at the UI Power Plant, where technicians have burned a mix of oat hulls and coal for more than a decade. The researchers found a 50-50 oat hulls-coal mix, when compared to burning only coal, reduced fossil carbon-dioxide emissions by 40 percent and significantly reduced the release of particulate matter, hazardous substances, and heavy metals.


 http://phys.org/news/2015-09-oat-hulls-power-considerable-benefits.html#jCp




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Banana fibre can fix marine oil spills, says study

 

http://www.scidev.net/global/farming/news/banana-fibre-can-fix-marine-oil-spills-says-study.html

 

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Banana peel can purify water, say scientists

 

http://www.scidev.net/global/pollution/news/banana-peel-can-purify-water-say-scientists.html


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Banana compost could boost crop yields, a study finds

http://www.scidev.net/global/biotechnology/news/banana-compost-could-boost-crop-yields-a-study-finds-1.html

 
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Scientists can now remove nanoplastics from our water with 94% efficiency

March 14, 2024

University of Waterloo researchers have created a new technology that can remove harmful nanoplastics from contaminated water with 94% efficiency. The study, "Utilization of epoxy thermoset waste to produce activated carbon for the remediation of nano-plastic contaminated wastewater," was published in the journal Separation and Purification Technology...

https://techxplore.com/news/2024-03-scientists-nanoplastics-efficiency.html


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Harmful 'forever chemicals' removed from water with new electrocatalysis method

March 5, 2024

https://phys.org/news/2024-03-chemicals-electrocatalysis-method.html

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Scientists are using bacteria to remove harmful contaminants from our water. Here's how.

January 10, 2019

https://www.ehn.org/scientists-are-using-bacteria-to-remove-harmful-contaminants-from-our-water-heres-how-2625517276.html

John Coates' laboratory at the University of California, Berkeley, hums with activity. Negative 80-degree freezers whirr, liquid nitrogen bubbles, grad students meticulously measure and mix complicated concoctions. But all of this is nothing compared with the commotion going on at a microscopic level.

The Coates lab is growing many different kinds of bacteria, multiplying in petri dishes at mind-boggling rates. But these bacteria aren't out to harm people or animals. In fact, quite the opposite — they're hard at work breaking down a dangerous chemical that pollutes waterways across the United States.

The chemical, called perchlorate, comes from rocket fuel, munitions and fireworks. It's dangerous to humans because it can impair thyroid function. It can also affect the thyroid in freshwater animals like fish and amphibians, even altering gonad development in some animals. But certain bacteria, including several species of Dechloromonasand Azospira, have evolved to use perchlorate to make energy-storing molecules. In the process, they turn it into harmless chloride and oxygen.

Coates is just one of many scientists across the globe who are working to harness the ability of various bacteria to remove harmful pollutants from water. This is no easy task. There are thousands of different pollutants — industrial chemicals, pesticides, herbicides, fertilizers, metals and more — and no one microbe can break down all. Also, because bacteria need special conditions to survive, it can be difficult to incorporate them into water treatment systems.

In spite of these challenges, Coates sees a future full of possibility. "It's really just a question of sitting down and spinning your brain around all the cool, novel aspects of these organisms and then asking where can we apply this?" he says.

Perchlorate decon

Perchlorate is mostly used in rocket fuels and munitions. Improper storage or disposal of rockets or debris may contaminate the environment. Through leaks or explosions, perchlorate can also pollute waterways near manufacturing plants. It's water soluble and chemically stable, so it can persist in ground and surface water for decades.

And that's bad news for people whose drinking water comes from contaminated sources, especially pregnant women and children. Perchlorate has been shown to impair thyroid function; proper thyroid function is essential for normal brain development during the prenatal period and during childhood.

When Coates submitted his first academic paper on perchlorate-degrading bacteria in 1998 (it was published in 1999), there were only a few bacterial species known to be capable of performing this feat. Coates wanted to see if there were more.

"It turns out that the microorganisms that use perchlorate are essentially ubiquitous — they're not difficult to find. And you can culture them fairly readily. To remediate perchlorate, you just needed to create specific conditions," he says.

The way to do this is to use something called a bioreactor — a home for bacteria that provides all the nutrients and minerals they need to thrive. It's similar to a fermenting tank for beer, except instead of yeast converting sugars into alcohol and carbon dioxide, perchlorate-destroying bacteria turn dangerous perchlorate into harmless chloride and oxygen. Contaminated ground or surface water gets pumped into the bioreactors, which are full of these bacteria. Once the bacteria have broken down the perchlorate, the water is filtered and sterilized to remove bacteria. The decontaminated water can then be sent to consumers or pumped back into the ground.

Thanks to discoveries made by Coates and a legion of other scientists, perchlorate-decontaminating bioreactors have been applied in the real world with great success. Large-scale perchlorate bioreactors are now at work cleaning contaminated water at several sites in California, Kansas, Texas and Utah. These bioreactors are astonishingly efficient: The bioreactor-based groundwater treatment plant in Rialto, California, for example, is capable or decontaminating 2,000 gallons (over 7,500 liters) of perchlorate-polluted water per minute — that's more than a billion gallons (over 3.7 billion liters) a year. In fact, Coates says that the bacterial removal of perchlorate represents one of the largest-scale bioremediation projects in the world.

Converting uranium

Implementing bioreactor technologies isn't always so straightforward, even when the bioreactor performs well in the lab. A bioreactor designed by Bruce Rittmann, the director of the Swette Center for Environmental Biotechnology at Arizona State University's Biodesign Institute, was initially used to remove water contaminants like perchlorate and trichloroethene, but can also be used to remove uranium and other metals from water. This kind of contamination can occur around uranium mines and mills, especially older abandoned ones. In people, drinking water contaminated with uranium can cause kidney damage; uranium is also toxic to fish, decreasing their reproductive success.

The bacteria in the bioreactor can't destroy the uranium, but they can convert it to a form that separates from water. Once the uranium comes out of the solution, it's much easier to remove —think about the difference between taking a sugar cube out of a glass of water and trying to remove the sugar once it's dissolved. In tests, Rittmann's bioreactor removed about 95 percent of the uranium from a contaminated water supply.

Rittmann says it would be relatively straightforward to construct a bioreactor system in currently operational mines that already have some sort of water treatment system in place. However, cleaning up abandoned mines would be more difficult, since they have no such infrastructure. There are about 4,000 abandoned uranium mines in America's western states.

This technology, Rittmann says, can be applied not just to water contaminated by uranium mines but also to wastewater from precious metal mines, including silver, gold and palladium. "In these cases, the materials that we produce — the solids these microbes remove from the water — are really valuable. We're working on the development of this technology not only to remove pollutants but to generate high value. It's a good deal," he says.

Beyond the bioreactor

What if we want to break down pollutants in places where building bioreactors isn't feasible, like in runoff from agricultural fields contaminated with pesticides? Colin Scott, head of the Biocatalysis & SynBio Team at Australia's Commonwealth Scientific and Industrial Research Organization (CSIRO), may have an answer.

Bacteria make enzymes, and it's these enzymes that do the dirty work of actually breaking down pollutants. So, Scott and his team are experimenting with bacterial enzymes to decontaminate water systems polluted with pesticides and herbicides. Enzymes aren't alive, so they don't need nutrients, which means they can be used in places that bacteria won't survive. They can't reproduce or adapt, so won't multiply and disturb delicate ecosystems.

"Enzymes themselves are terrific because they're really specific for the thing that you want them to do, so they don't have any other effects. And they're also biodegradable, so they don't persist in the environment," says Scott.

Such enzymes are not yet used on a large scale, but they've been successful in field tests. For example, a bacterial enzyme called OP-A is capable of breaking down organophosphate insecticides, which have been linked to deficits in attention, coordination and memory, especially in agricultural workers. In field trials, the OP-A enzyme reduced levels of the controversial pesticide chlorpyrifos — linked to impaired brain development in children — in contaminated field runoff by 99 percent in just eight hours. (Since these tests, the researchers say they have developed an improved version of OP-A, known as A900.)

The specificity of enzymes is both their brilliance and their downfall. On one hand, high specificity means that enzymes aren't likely to produce unwanted side effects, like harming plants or animals. On the other hand, there are thousands of different pollutants, which means we'll need a lot of different enzymes.

After an appropriate enzyme has been identified, scientists have to figure out how to cost-effectively mass produce it. Since enzymes usually biodegrade quickly, scientists have to make sure the enzyme stays intact long enough to do its job. They also have to run safety studies to make sure that whatever components the enzymes break the pollutant down into aren't also toxic.

A long way to go

There's still a lot of work to be done. At the science level, we need to identify and characterize bacteria that can break down specific pollutants. Although bacteria for degrading or removing contaminants like perchlorate, uranium and certain pesticides are well understood, as-yet undiscovered bacteria may be important in dealing with emerging water pollutants such as PFAS, which can cause immune system dysfunction and cancer, as well as pharmaceuticals, the effects of which are not yet fully understood.

Other hurdles are policy based. It's often not a question of whether to use bioremediation or alternative techniques, but whether to do anything at all. Many contaminants — including several pesticides, cyanotoxins and solvents — are monitored by the EPA, but not regulated. Without set limits for acceptable amounts of these chemicals in drinking water, there's no incentive for anyone to spend money to get rid of them. Even though bioremediation may be cheaper than the alternatives, in the short term, it's still more expensive than doing nothing. And for many pollutants — including many pesticides — there's currently a whole lot of nothing being done.

But with the continued work of scientists and stricter water quality standards, bacteria could be a public health game-changer.

"These bugs are amazing," says Coates. "What limits us is our imagination rather than the organisms' abilities."

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Optimized carbonization of coffee shell via response surface methodology: A circular economy approach for environmental remediation

2023

https://www.sciencedirect.com/science/article/abs/pii/S0269749123020201

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Coffee grounds modified zero-valent iron for efficient heavy metal removal

December 2023

https://www.researchgate.net/publication/376121030_Coffee_grounds_modified_zero-valent_iron_for_efficient_heavy_metal_removal

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Jack Bean Development in Multimetal Contaminated Soil Amended with Coffee Waste-Derived Biochars

2022

https://www.mdpi.com/2227-9717/10/10/2157

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How to Compost With Coffee Grounds to Benefit Your Garden

05/16/23

Using Coffee Grounds Directly in Soil vs. Composting Them

https://www.thespruce.com/coffee-grounds-compost-7495511

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The use of spent coffee grounds and spent green tea leaves for the removal of cationic dyes from aqueous solutions

May 2021

https://www.researchgate.net/publication/351356680_The_use_of_spent_coffee_grounds_and_spent_green_tea_leaves_for_the_removal_of_cationic_dyes_from_aqueous_solutions

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Environmental remediation by tea waste and its derivative products: A review on present status and technological advancements

2022 Apr 5

 Abstract

The rising consumption of the popular non-alcoholic beverage tea and its derivative products caused massive growth in worldwide tea production in the last decade, leading to the generation of huge quantities of waste tea residues every year. Most of these wastes are usually burnt or disposed in landfills without proper treatment which results in serious environmental issues by polluting water, air and soil. In the recent times, 'waste to wealth' is a fast-growing concept for environment friendly sustainable development. Utilization of the large amount of tea wastes for the production of low-cost adsorbents to reduce the expenses of water and wastewater treatment can be a sustainable way of management of these wastes which at the same time will improve circular economy also. This review endeavours to evaluate the potential of both raw and modified tea wastes towards the adsorption of pollutants from wastewater. The production of various adsorptive materials such as biochar, activated carbon, nanocomposites, hydrogels, nanoparticles from tea wastes are summarized. The advancements in their applications for the removal of different emerging contaminants from wastewater as well as potable water, air and soil are exhaustively reviewed. The outcome of the present review reveals that tea waste and its derivatives are appropriate candidates to be used as adsorbents that show tremendous effectiveness in cleaning the environment. This article will provide the readers with an in-depth knowledge on the sustainable utilization of tea waste as adsorbent materials and will assist them to explore this abundant cheap waste biomass for environmental remediation.


https://pubmed.ncbi.nlm.nih.gov/35395270/

 

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Analysis of Nicotine in Mushrooms

https://eurl-pesticides.eu/library/docs/srm/meth_NicotineMushrooms_CrlFvCrlSrm.pdf


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Food wastes clean water wastes: melon peel peroxidase isolation and immobilization onto magnetite nanoparticles for phenol removal

30 October 2023

 

Abstract

 

In this study, melon peel waste was utilized to isolate peroxidase enzyme through three-phase portioning (TPP) and subsequently immobilized onto magnetite nanoparticles for effective bioremediation of phenol pollutants from water. The optimization of TPP parameters ensured maximum activity recovery and enzyme purity. Magnetite nanoparticles were synthesized and used as a substrate for immobilizing the isolated peroxidase, achieving an activity recovery of 157% and a purification fold of 5.2. Protein homogeneity testing confirmed the purity of the peroxidase enzyme. The magnetite nanoparticles had an average diameter of 62 nm, and the immobilization efficiency reached 93% at pH 8 with an enzyme/nanoparticles v/v ratio of 1:9. The immobilized peroxidase demonstrated the ability to degrade 57% of phenol within 3 h and retained 30% relative activity even after five catalytic cycles. This immobilized melon peel peroxidase on magnetite nanoparticles proves to be a robust, enduring, and reusable biocatalyst with potential for various applications, especially in bioremediation processes.

https://chembioagro.springeropen.com/articles/10.1186/s40538-023-00494-5

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Evaluation of orange peel for biosurfactant production by Bacillus licheniformis and their ability to degrade naphthalene and crude oil

2016 Feb 4

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4742421/

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Activated carbon derived from waste orange and lemon peels for the adsorption of methyl orange and methylene blue dyes from wastewater

2022 Jul 10

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9363969/

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Orange Peels as a Sustainable Material for Treating Water Polluted with Antimony

Feb 2021

https://www.researchgate.net/publication/348938610_Orange_Peels_as_a_Sustainable_Material_for_Treating_Water_Polluted_with_Antimony

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7 Easy Ways To Use Orange Citrus Peels For Cleaning

7 Easy Ways to Harness the Power of Orange Citrus Peels for Cleaning

    1. All-Purpose Cleaner
    2. Garbage Disposal Freshener
    3. Microwave Cleaner
    4. Stovetop Cleaner
    5. Air Freshener
    6. Refrigerator Deodorizer
    7. Chrome and Metal Polish

https://alisonsnotebook.com/orange-citrus-peels-for-cleaning/

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Modification of Poly(lactic acid) with Orange Peel Powder as Biodegradable Composite

2022

https://www.mdpi.com/2073-4360/14/19/4126

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Modified Orange Peel Waste as a Sustainable Material for Adsorption of Contaminants

2023 Jan 27

https://ncbi.nlm.nih.gov/pmc/articles/PMC9922011/

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A critical review with emphasis on recent pieces of evidence of Moringa oleifera biosorption in water and wastewater treatment

2022 May 18.

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9252946/

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Bioremediation of Waters Contaminated with Heavy Metals Using Moringa oleifera Seeds as Biosorbent

2013

https://www.intechopen.com/chapters/45214

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Bioremediation of Turbid Surface Water Using Seed Extract from Moringa oleifera Lam. (Drumstick) Tree

15 February 2010

https://currentprotocols.onlinelibrary.wiley.com/doi/10.1002/9780471729259.mc01g02s16

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Assessing the Usefulness of Moringa oleifera Leaf Extract as a Biostimulant to Supplement Synthetic Fertilizers: A Review

2022 Aug 26

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9459878/

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A comprehensive review on Moringa oleifera nanoparticles: importance of polyphenols in nanoparticle synthesis, nanoparticle efficacy and their applications

19 February 2024

https://jnanobiotechnology.biomedcentral.com/articles/10.1186/s12951-024-02332-8

 
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A novel approach for removing microplastics from water

September 12, 2023

Texas A&M AgriLife study shows fungal isolates can remediate potentially harmful microplastics in aqueous environment

https://agrilifetoday.tamu.edu/2023/09/12/a-novel-approach-for-removing-microplastics-from-water/

 

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Pollution Solution: New Device Can Capture 99.9% of Microplastics in Water Using Wood Dust

August 21, 2023

https://scitechdaily.com/pollution-solution-new-device-can-capture-99-9-of-microplastics-in-water-using-wood-dust/

 
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NUS physicists utilise hair fluorescence to repurpose human hair waste

30 June 2023

Activating the fluorescent properties of our hair using heat could convert human hair waste into a functional material for steganography and pollution detection

https://news.nus.edu.sg/utilising-fluorescence-to-repurpose-hair-waste/

 
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Researchers gain ground on turning chicken feathers into water filters

Technology boosts potential for low-cost, sustainable solution to contaminated water.

July 10, 2023

https://www.feedstuffs.com/nutrition-and-health/researchers-gain-ground-on-turning-chicken-feathers-into-water-filters

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Scientists Use Chicken Feathers To Generate Clean Energy

October 20, 2023

Researchers are using chicken feathers to make fuel cells more cost-​effective and sustainable.

https://www.technologynetworks.com/applied-sciences/news/scientists-use-chicken-feathers-to-generate-clean-energy-380131

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Adding crushed rock to farmland pulls carbon out of the air, field test shows

25 October 2023

https://techandsciencepost.com/news/earth/adding-crushed-rock-to-farmland-pulls-carbon-out-of-the-air-field-test-shows/

 
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Korean Nanomaterial Could Enable Eco-Friendly Fine Dust Reduction

November 20, 2023

https://www.letstalkmaterials.com/in-the-news/korean-researchers-develop-nanomaterial-to-enable-eco-friendly-removal-of-fine-dust-precursors/

 

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Soil Xenobiotics and Their Phyto-chemical Remediation

 16 February 2017

https://link.springer.com/chapter/10.1007/978-3-319-47744-2_18 

 

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Overview of Soil Xenobiotics and their Biological Remediation Strategies

January 2024

https://www.researchgate.net/publication/377547029_Overview_of_Soil_Xenobiotics_and_their_Biological_Remediation_Strategies

 

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Rhizoremediation of Heavy Metal- and Xenobiotic-Contaminated Soil: An Eco-Friendly Approach

2020

https://link.springer.com/chapter/10.1007/978-981-15-5901-3_5

 

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Recent Strategies for Bioremediation of Emerging Pollutants: A Review for a Green and Sustainable Environment

2022 Aug 19

Abstract

Environmental pollution brought on by xenobiotics and other related recalcitrant compounds have recently been identified as a major risk to both human health and the natural environment. Due to their toxicity and non-biodegradability, a wide range of pollutants, such as heavy metals, polychlorinated biphenyls, plastics, and various agrochemicals are present in the environment. Bioremediation is an effective cleaning technique for removing toxic waste from polluted environments that is gaining popularity. Various microorganisms, including aerobes and anaerobes, are used in bioremediation to treat contaminated sites. Microorganisms play a major role in bioremediation, given that it is a process in which hazardous wastes and pollutants are eliminated, degraded, detoxified, and immobilized. Pollutants are degraded and converted to less toxic forms, which is a primary goal of bioremediation. Ex situ or in situ bioremediation can be used, depending on a variety of factors, such as cost, pollutant types, and concentration. As a result, a suitable bioremediation method has been chosen. This review focuses on the most recent developments in bioremediation techniques, how microorganisms break down different pollutants, and what the future holds for bioremediation in order to reduce the amount of pollution in the world.

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9413587/

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Green Remediation Best Management Practices: Bioremediation

2021

https://www.epa.gov/system/files/documents/2022-04/gr_factsheet_bioremediation.pdf

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Chapter 1 - Bioremediation: A green technology for environmental cleanup

2023

https://www.sciencedirect.com/science/article/abs/pii/B9780323961134000044

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Bioremediation: a tool for cleaning polluted environments

2008

https://www.academia.edu/31189522/Bioremediation_a_tool_for_cleaning_polluted_environments

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Bioremediation techniques–classification based on site of application: principles, advantages, limitations and prospects

2016 Sep 16

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5026719/

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Phytoremediation, Bioaugmentation, and the Plant Microbiome

November 18, 2022

https://pubs.acs.org/doi/10.1021/acs.est.2c05970

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Bioremediation of contaminated soils

2021

https://www.sciencedirect.com/science/article/abs/pii/B9780128202029000228

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Cleaning up with genomics: applying molecular biology to bioremediation

01 October 2003

https://www.nature.com/articles/nrmicro731

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Genetically Modified Organisms for Bioremediation: Current Research and Advancements

12 December 2021

https://link.springer.com/chapter/10.1007/978-3-030-86169-8_7

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Biological remediation of acid mine drainage: Review of past trends and current outlook

2020

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9488087/

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Bioremediation: an emerging effective approach towards environment restoration

28 February 2020

https://link.springer.com/article/10.1007/s42398-020-00099-w

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Bioremediation – Definition, Types, Application

July 8, 2023

https://microbiologynote.com/bioremediation/

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BOX 2-1 KEY TERMS FOR UNDERSTANDING BIOREMEDIATION

Microorganism: An organism of microscopic size that is capable of growth and reproduction through biodegradation of "food sources," which can include hazardous contaminants.

Microbe: The shortened term for microorganism.

Oxidize: The transfer of electrons away from a compound, such as an organic contaminant. The coupling of oxidation to reduction (see below) usually supplies energy that microorganisms use for growth and reproduction. Often (but not always), oxidation results in the addition of an oxygen atom and/or the loss of a hydrogen atom.

Reduce: The transfer of electrons to a compound, such as oxygen, that occurs when another compound is oxidized.

Electron acceptor: The compound that receives electrons (and therefore is reduced) in the energy-producing oxidation-reduction reactions that are essential for the growth of microorganisms and bioremediation. Common electron acceptors in bioremediation are oxygen, nitrate, sulfate, and iron.

Electron donor: The compound that donates electrons (and therefore is oxidized). In bioremediation the organic contaminant often serves as an electron donor.

Primary substrates: The electron donor and electron acceptor that are essential to ensure the growth of microorganisms. These compounds can be viewed as analogous to the food and oxygen that are required for human growth and reproduction.

Aerobic respiration: The process whereby microorganisms use oxygen as an electron acceptor.

Anaerobic respiration: The process whereby microorganisms use a chemical other than oxygen as an electron acceptor. Common "substitutes" for oxygen are nitrate, sulfate, and iron.

Fermentation: The process whereby microorganisms use an organic compound as both electron donor and electron acceptor, converting the compound to fermentation products such as organic acids, alcohols, hydrogen, and carbon dioxide.

Cometabolism: A variation on biodegradation in which microbes transform a contaminant even though the contaminant cannot serve as the primary energy source for the organisms. To degrade the contaminant, the microbes require the presence of other compounds (primary substrates) that can support their growth.

Reductive dehalogenation: A variation on biodegradation in which microbially catalyzed reactions cause the replacement of a halogen atom on an organic compound with a hydrogen atom. The reactions result in the net addition of two electrons to the organic compound.

Intrinsic bioremediation: A type of bioremediation that manages the innate capabilities of naturally occurring microbes to degrade contaminants without taking any engineering steps to enhance the process.

Engineered bioremediation: A type of remediation that increases the growth and degradative activity of microorganisms by using engineered systems that supply nutrients, electron acceptors, and/or other growth-stimulating materials.

Variations on Basic Metabolism

In addition to microbes that transform contaminants through aerobic respiration, organisms that use variations on this basic process have evolved over time. These variations allow the organisms to thrive in unusual environments, such as the underground, and to degrade compounds that are toxic or not beneficial to other organisms.

Anaerobic Respiration. Many microorganisms can exist without oxygen, using a process called anaerobic respiration. In anaerobic respiration, nitrate (NO3-), sulfate (SO42-), metals such as iron (Fe3+) and manganese (Mn4+), or even CO2 can play the role of oxygen, accepting electrons from the degraded contaminant. Thus, anaerobic respiration uses inorganic chemicals as electron acceptors. In addition to new cell matter, the byproducts of anaerobic respiration may include nitrogen gas (N2), hydrogen sulfide (H2S), reduced forms of metals, and methane (CH4), depending on the electron acceptor.
National Academies of Sciences, Engineering, and Medicine. 1993. In Situ Bioremediation: When Does it Work?. Washington, DC: The National Academies Press. https://doi.org/10.17226/2131.

https://nap.nationalacademies.org/read/2131/chapter/4#20

 

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Current and Future Bioremediation Applications : Bioremediation from a Practical and Regulatory Perspective

04 August 2016

References

https://link.springer.com/chapter/10.1007/978-3-662-49875-0_22

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Principles of Phytoremediation

20 March 2020

Abstract

Phytoremediation, a form of bioremediation, is one viable option for removing pollution from contaminated soil and water. Bioremediation was developed as an inexpensive, environmentally friendly, and sustainable alternative to traditional chemical and physical pollution remediation methods. Bioremediation began with the use of bacteria and later other microorganisms, to extract or degrade inorganic and organic contaminants in soil and water in situ. It then evolved to other applications in combination with traditional chemical and physical remediation methods. Phytoremediation was came about from basic research studies on the physiology of halophytic and hyperaccumulating plants. At first, plants provided successful for extracting salts, metals, and radionuclides from soil and water. Further, studies discovered that plant roots and the rhizosphere were capable of extracting or degrading organic pollutants such as pesticides and petrochemicals. The in situ case studies showcased in this book demonstrate how phytoremediation is a sustainable means of pollution remediation in economically emerging countries and is consistent with the United Nations Sustainable Development Goals.

https://link.springer.com/chapter/10.1007/978-3-030-00099-8_1

 

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Soil and Groundwater Remediation Technologies: A Practical Guide

April 2020

https://www.researchgate.net/publication/339938808_Soil_and_Groundwater_Remediation_Technologies_A_Practical_Guide

 

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Five ways scientists can make soil less dirty

 May 23, 2016

https://www.anl.gov/article/five-ways-scientists-can-make-soil-less-dirty

It may be hard to imagine, but soil gets dirty. Soil can become contaminated with oil, grease, heavy metals or pesticides through urban and agricultural runoff as well as industrial spills or precipitation.


The clean-up process involves more than a broom and a dust pan. Soil must undergo remediation — the process of removing pollutants and contaminants from the ground.

Several different remediation processes are available, varying in efficiency, cost and sustainability for specific site conditions. When officials suspect a site is contaminated, they conduct an assessment to determine the pollutant, the extent of contamination and the appropriate method to remediate the soil.

The Applied Geosciences and Environment Management Program at the U.S. Department of Energy’s Argonne National Laboratory evaluates potentially contaminated sites and applies remediation methods, such as those described below, that are both efficient and environmentally friendly by reducing secondary impacts — such as emissions from trucks that transport soil to a treatment facility.
Air Sparging

Air sparging, also referred to as soil venting, involves injecting air into the soil or groundwater. The air moves horizontally and vertically through the soil, causing the contaminants to evaporate into a gas. This method works best for contaminants that easily evaporate, such as crude oil.

Air sparging is an example of an in-situ remediation method, in which the contaminated soil does not need to be removed. In situ methods tend to be more environmentally friendly than those that are ex situ, where the soil is first removed and then treated at the surface, said Lorraine LaFreniere, an Argonne geological engineer who leads Argonne’s Applied Geosciences and Environment Management program.

“In in situ methods, you’re not bringing any of the contaminants to the surface,” LaFreniere said. ​“You have the advantage of not exposing anybody to the contamination or the remediation process itself.”
Air Stripping

Air stripping is an ex situ method specifically for water, in which contaminated groundwater is collected and filtered through a machine called an air stripper.

The groundwater goes into the top of the machine and cascades to the bottom as fine droplets, while air enters from the bottom and is forced upward. The air strips away the contaminants as it rises through the droplets and exits through an opening at the top.

Determining whether to use an in situ or ex situ process depends on how the contamination is distributed throughout the soil and to what depth, researchers said. For example, if the contaminated soil is buried under clean soil, the clean soil would have to first be removed.
Enhanced Biodegradation

Nature itself tries to help eliminate soil contaminants through a naturally occurring process called biodegradation. Certain microorganisms in the soil feed on contaminants, such as tar deposits.

Argonne researchers, in collaboration with other scientists, found that injecting zero-valent iron — iron in its elemental form — into the soil accelerates natural biodegradation.

“We injected slurry mixtures of zero-valent iron and organic matter into soils and observed that it speeds up the process considerably,” LaFreniere said.
Phytoremediation

Trees offer shade on a sunny day, but they can also remove contaminants from soil through phytoremediation. Trees and other deep-rooted plants absorb contaminants in soil and incorporate the contaminants into their tissues; plants also ​“breathe” volatile contaminants to the atmosphere, where they dissipate.

“Plants process a lot of water during photosynthesis to get the nutrients they need,” said Cristina Negri, an Argonne agronomist and environmental engineer in the Energy Systems Division. ​“What we’re doing is exploiting this natural process and using plants as pumps to remove contaminants.”

Plant-based remediation is good for contaminants, such as carbon tetrachloride, a chemical that was primarily used as a fumigant and dry cleaning agent until it was banned in the 1970s as harmful to human health.

Argonne researchers are also using trees to monitor their progress when using phytoremediation. The scientists measure the amount of contaminants in samples of branches and tree cores to assess how much has been removed.
Soil Vapor Extraction

Sometimes, all you need is a really big vacuum.

The soil vapor extraction method applies a vacuum to the soil to induce air flow and get soil vapors moving. Researchers collect the contaminated vapors in extraction wells and treat them above ground.

This is a useful remediation method when the contaminants are already in a vaporous state or are liquids that readily evaporate, such as methane and propane. These vapors can make their way into homes and businesses and may cause people to become ill.

“We’re trying to develop new testing and treatment techniques to best remove contaminants and keep people safe,” LaFreniere said. ​“As we’re remediating, we’re also assessing the methods and technologies that we’re using.”

Funding for LaFreniere and Negri’s research comes from the U.S. Department of Energy’s Office of Environmental Management, the Commodity Credit Corporation and the U.S. Department of Agriculture.

 

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Recent Developments in Microbe–Plant-Based Bioremediation for Tackling Heavy Metal-Polluted Soils

2021 Dec 23

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC8733405/

Plant-Based Bioremediation

Plants are used for bioremediation either alone or in combination with microbes (Ramos et al., 2005) instead of depending on microbes and their efficacy in achieving bioremediation of any contaminated medium. The application of green plants to clean up any contaminated medium or surface is not a novel concept. Plants were proposed for treating the wastewater around 300 years ago (Hartman, 1975). Presently a number of plant species such as Amaranthus spinosus, A. hypochondriacus Chrysopogon zizanioides, Brassica juncea, Ricinus communis, Chromolaena odorata, Ageratum conyzoides, Ipomoea carnea, Prosopis juliflora, Lantana camara, Parthenium hysterophorus, Fagopyrum esculentum, Odontarrhena chalcidica, Tagetes patula, T. erecta, and Odontarrhena chalcidica, have been identified which helpremediate HM contaminated soil (Bauddh and Singh, 2012; Bauddh and Singh, 2015; Huang et al., 2019; Chen et al., 2020a; Raza et al., 2020; Biswal et al., 2021; Cui et al., 2021; Gonzaga et al., 2021; Nugroho et al., 2021; Singh et al., 2021). In addition, plants like Nicotiana tabacum, Arabidopsis thaliana, Beta vulgaris and Sedum alfredii have been genetically modified with suitable bacterial genes from Caenorhabditis elegans, Saccharomyces cerevisiae, Streptococcus thermophilus, Pseudomonas fuorescens and employed for remediating the targeted contaminants (Daghan et al., 2013; Liu et al., 2015a; Wang et al., 2019; Nedjimi, 2021). For instance, mercury (Hg) reductase bacterial genes, e.g., merA and merB have been applied in plants for the detoxification of methyl-Hg (Li et al., 2020a). In addition, various biostimulators, such as manure and organic amendments (e.g., various plant biochar, biosolids, and litter) are used in this plant-based bioremediation. Use of different chelators such as citric acid, ethylene diamine tetraacetic acid (EDTA), [S,S]-ethylenediaminedisuccinic acid (EDDS), ethylenediamine-di-o-hydroxyphenylacetic acid (EDDHA), diethylenetriaminepentaacetic acid (DTPA), ethylene glycol tetraeacitic acid (AGTA), nhydroxyethylenediaminetriacetic acid (HEDTA), fulvic acids, salicyclic acid, and tartaric acid control metal sorption, and precipitation through the formation of metal chelate complexes, which consequently enhance the bioavailability of these metals and also improve phytoextraction efficiency (Caporale and Violante, 2016; Acuña et al., 2020; Saleem et al., 2020). The addition of chelates in soils can move more metals into soil solution via the suspension of precipitated compounds and desorption of sorbed species. Plants can also naturally produce various phytosiderophores, organic acids, and carboxylates, which can enhance metal mobility, solubility, and bioavailability in soils, thus increasing the phytoremediation potential of plants (Vithanage et al., 2012; Gupta and Singh, 2017). For instance, Miscanthus sinensis can detoxify Al by producing various phytosiderophores such as citric acid, malic acid, and chlorogenic acid and stored the metal in cell walls (Haruma et al., 2019).

Plant-based bioremediation is considered a potential tool for the accumulation, transformation, and immobilization of a low level of contaminants (Rayu et al., 2012). The mechanisms behind plants facilitate the reclamation of the polluted soils and groundwater are presented in Table 1. The approach of plant-based bioremediation has several merits such as cost-effectiveness, public acceptance, and the ability to remove inorganic and organic contaminants simultaneously. In a study, mixed mercury-trichloroethylene (Hg-TCE) pollutants are removed by transgenic alfalfa plants pKHCG co-expressing human P450 2E1 (CYP2E1) genes and glutathione S-transferase (GST; Zhang et al., 2013). A major synergistic effect caused by simultaneous expression of CYP2E1 and GST leads to increased accumulation and resistance of heavy metal–organic complex pollutants. Another study by Tammam et al. (2021) found that the plant Glebionis coronaria can eliminate Pb from the contaminated soil. It is also recorded that the foliar spray of Indole-3-acetic acid (IAA) and gibberellic acid (GA3) enhanced the growth significantly and increase the phytostabilization capacity of the studied plant. The application of bamboo biochar with the Salix psammophila to remediate the multi-metal contaminated soil, enhance the translocation factor (TF) and bioconcentration factors (BCF) of Cd, Cu and Zn (Li et al., 2021a). The higher TF for Zn (TF > 1) and BCF for Cd (BCF > 1) makes S. psammophila a potential candidate for the phytoremediation in BBC amendment soil. Recently several studies found that the application of nanoparticles such as Ag nanoparticles (AgNPs), nano-TiO2 particles, nanoscale zero-valent iron (nZVI), salicylic acid nanoparticles (SANPs) and magnesium oxide (MgO) nanoparticles along with plants Zea mays, Glycine max, Isatis cappadocica, Lolium perenne, Boehmeria nivea and Raphanus sativus enhance the growth and phytoextraction of HMs Cd and Pb (Khan and Bano, 2016; Singh and Lee, 2016; Gong et al., 2017; Souri et al., 2017; Huang et al., 2018; Hussain et al., 2019).

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Soil washing for the remediation of dioxin-contaminated soil: A review

2021

https://www.sciencedirect.com/science/article/abs/pii/S0304389421017325

Introduction

Sites contaminated with polychlorinated aromatic compounds are a worldwide problem. One of the most noticeable group of soil contaminants is polychlorinated dibenzo-p-dioxins and dibenzofurans (or PCDD/Fs or dioxins) (Kulkarni et al., 2008, Haglund, 2007). In fact, PCDD/Fs, which are compounds of similar physico-chemical properties and molecular structures, are one of the most toxic human-made chemicals (Alaee, 2016). Their stability, easy accumulation, and persistence in the environment along with their ability to cause adverse health effects, such as wasting syndrome (Seefeld et al., 1984), immunotoxicity (Rhile et al., 1996), teratogenicity (Mimura et al., 1997), dysfunctional immune and reproductive systems, and various types of cancers (Steenland et al., 2004), make them a potential threat to human wellbeing.

PCDD/Fs’ biodegradation is slow, and their half-life in soil is estimated to be ten years (Habe et al., 2002, Lin et al., 2018). They also have very low vapor pressure, making them hardly evaporate into the air (Eitzer and Hites, 1988). The water solubility of PCDD/Fs is very low (e.g. 1.93 × 10−3 and 0.75 × 10−7 mg/L for 2,3,7,8-tetrachlorodibenzo-p-dioxin (2,3,7,8-TCDD) and octachlorodibenzodioxin (OCDD) at 25 ℃, respectively) since they are non-polar and hydrophobic compounds with high octanol-water partitioning coefficients; therefore, mostly PCDD/Fs accumulate in soil particles (Atsushi and Yoshihisa, 2008). The hydrophobicity of dioxins is proportional to the number of chlorine atoms present on the molecule.

Currently, available remediation technologies for dioxin-contaminated soil can be classified as thermal (Lee et al., 2008), physical/chemical (Rathna et al., 2018), and biological remediation (Huang et al., 2018, Tran et al., 2020). The selection of a treatment for a specific site mostly depends on PCDD/F removal efficiency, soil detoxification, and cost. Soil washing/extraction is a physicochemical remediation process that has been widely studied in recent years due to its high removal efficiency, ease in operation, and cost-effectiveness. Soil washing uses physical forces (e.g., generated by propellers/impellers) and liquid solvents (chemical extraction) to remove contaminants from soil (Cheng et al., 2017). Physical separation in soil washing can help separate fine particles (clay and silt), which often have a larger surface area and thus higher PCDD/F concentrations, from coarse particles (sand and gravel) (Jonsson et al., 2010). When in contact with soil particles, physical forces can break them down, facilitating contaminant removal. Rotating mixer, ultrasonic basin, mechanical stirrer, and flotation machine are usually employed for physical separation. Physical separation can also be combined with chemical extraction to enhance the remediation efficiency for dioxin-contaminated soil.

Being hydrophobic makes PCDD/Fs more soluble in organic solvents than in water (Guemiza et al., 2017a), making organic solvents such as ethanol, 2-propanol, acetone were the earliest reagents used for extracting dioxins from the soil. The dioxin removal efficiencies range from 75% to 90% for ethanol (Jonsson et al., 2010, Meguro et al., 2008). For example, Jonsson et al. (2010) indicated that at high initial PCDD/F concentrations of 2300–8100 pg-Toxicity Equivalent (TEQ)/kg, the treatment efficiencies were 81–85% after 10 wash cycles with 75% ethanol. Recently, the use of surfactants or organic matters such as humic acid, compost, edible oils has shown to be feasible to extract hydrophobic compounds from soil (Guemiza et al., 2017a). These additives help increase the solubility of dioxins in the washing liquid. Surfactants such as Brij 35, Tween 80, Triton X100, and Sodium dodecyl sulfate (SDS) have been studied for PCDD/F soil washing (Reynier et al., 2014, Binh et al., 2016). At an initial PCDD/F concentration of 6289 ng-TEQ/kg, the obtained removal efficiencies were 25%, 72%, 70%, and 74% for Brij 35, SDS, Tween 80, and Triton X100, respectively. Also, Vu et al. (2017) reported 80–95% removal of dioxins from highly contaminated soil when it was washed by fish oil and compost tea.

Recently, two prominent review articles have been published on soil washing treatment of hydrophobic organic pollutants (Trellu et al., 2016, Mousset et al., 2014). Trellu et al. (2016) summarized soil washing/flushing technologies for soil contaminated with polychlorobiphenyls (PCB), polycyclic aromatic hydrocarbons (PAH), and petroleum hydrocarbons, as well as the treatment of the washed solution. This study, unlike many others, described the treatment of the washed solution in detail. Yet, soil washing was only briefly described. Mousset et al. (2014) reviewed the use of cyclodextrins in comparison with other surfactants, cosolvents and agents for the removal of hydrophobic pollutants from contaminated soil. This study mostly focused on cyclodextrins and its properties, advantages and uses in soil washing. Other solvents and surfactants were also involved but only for the comparison with the efficiency and outstanding properties of cyclodextrins. These studies, however, have indicated that soil washing technology is a robust and environmentally friendly treatment with ease in operation and maintenance. A review on PCDD/F soil washing has not existed. Also, a detailed summary of physical washing techniques has not been available in the literature. Further, the cost feasibility of soil washing has rarely been summarized. Our review article aimed at bridging these gaps.

In this review, a description of physical washing devices and chemical extraction processes (using solvents, surfactants and edible oils) for PCDD/F soil washing was provided. The advantages and limitations of each technology for PCDD/F soil washing were presented. Particularly, cost feasibility, one of the most crucial factors for upscaling a treatment technology, was given.

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Metal contamination and bioremediation of agricultural soils for food safety and sustainability

23 June 2020

https://www.nature.com/articles/s43017-020-0061-y

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The Environmental Remediation Site-Cleanup Process For Hazardous Waste Disposal

Jun 22, 2021

https://mcfenvironmental.com/the-environmental-remediation-site-cleanup-process-for-hazardous-waste-disposal/

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The Rundown: So you want to clean up a brownfield. Here's how.

Feb. 1, 2017

https://www.oregonmetro.gov/news/rundown-so-you-want-clean-brownfield-heres-what-do

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Soil and brownfield bioremediation

2017 Aug 22

Bioaugmentation

Introducing specific microorganisms to decontaminate the soils when indigenous microbes are not efficient is considered a more acceptable approach to remediate the contaminated soils. However, the strains for bioaugmentation should ideally have (i) superior ability to degrade the target contaminants, (ii) easy to cultivate, (iii) fast growth, (iv) tolerance to the high concentration of contaminant and (v) ability to survive in a wide range of environmental conditions/stressors. Bioaugmentation has been proven to be successful for a wide range of pollutants including pesticides such DDT, lindane, endosulfan, pentachlorophenol (PCP), polyaromatic hydrocarbons (PAHs) and total petroleum hydrocarbons (Abhilash et al., 2011; Saez et al., 2014; Wang et al., 2014; Chen et al., 2015; Kuppusamy et al., 2016a,b). However, predation, competition and toxins in soils can negatively affect the survival of introduced microbes. In such cases, bioaugmentation using immobilized cells in carrier materials or preadapted strains to the problem soil conditions may prove to be advantageous regarding enhancing their survival in soils.

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5609233/

 

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Sustainable remediation and redevelopment of brownfield sites

28 March 2023

https://www.nature.com/articles/s43017-023-00404-1

 
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Polycyclic Aromatic Hydrocarbons: Sources, Toxicity, and Remediation Approaches

2020 Nov 5

Abstract

Polycyclic aromatic hydrocarbons (PAHs) are widespread across the globe mainly due to long-term anthropogenic sources of pollution. The inherent properties of PAHs such as heterocyclic aromatic ring structures, hydrophobicity, and thermostability have made them recalcitrant and highly persistent in the environment. PAH pollutants have been determined to be highly toxic, mutagenic, carcinogenic, teratogenic, and immunotoxicogenic to various life forms. Therefore, this review discusses the primary sources of PAH emissions, exposure routes, and toxic effects on humans, in particular. This review briefly summarizes the physical and chemical PAH remediation approaches such as membrane filtration, soil washing, adsorption, electrokinetic, thermal, oxidation, and photocatalytic treatments. This review provides a detailed systematic compilation of the eco-friendly biological treatment solutions for remediation of PAHs such as microbial remediation approaches using bacteria, archaea, fungi, algae, and co-cultures. In situ and ex situ biological treatments such as land farming, biostimulation, bioaugmentation, phytoremediation, bioreactor, and vermiremediation approaches are discussed in detail, and a summary of the factors affecting and limiting PAH bioremediation is also discussed. An overview of emerging technologies employing multi-process combinatorial treatment approaches is given, and newer concepts on generation of value-added by-products during PAH remediation are highlighted in this review.

Microbial Remediation of Polycyclic Aromatic Hydrocarbon Pollution

As per Kuppusamy et al. (2017), biological methods have gained wide attentions for PAH remediation, followed by integrated methods, chemical oxidation, and physical methods. Among all biological methods for PAH remediation, usage frequency of natural attenuation, bioaugmentation, and biostimulation is highest (∼33%), followed by bioreactors (22%), phytoremediation/rhizoremediation (22%), composting (13%), biopiles (4%), enzyme-mediated bioremediation (2%), vermiremediation (2%), and others (2%) (Kuppusamy et al., 2017). Moreover, the second most attractive integrated methods are applied in the subsequent order, i.e., biological–biological (42%), chemical–biological (27%), physical–chemical (21%), physical–chemical–biological (5%), and thermal–chemical methods (5%) (Kuppusamy et al., 2017). Microbial PAH remediation (bioaugmentation and biostimulation) deals with separate or combined application of specific microbes such as bacteria, archaea, fungi, and algae. However, bacteria- and fungi-assisted degradation has been widely studied.

Bacteria

Bacteria have unique metabolic versatility for degradation of PAH pollutants (Ma and Zhai, 2012). During bacterial aerobic PAH degradation, the oxygen works as the final electron acceptor and also as a co-substrate for the hydroxylation and oxygen-mediated cleavage of the aromatic ring (Chen et al., 2016), whereas bacterial anaerobic PAH degradation utilizes an entirely diverse approach to break and open the aromatic ring depending on the reductive reaction type and alternative final electron acceptors (Ghosal et al., 2016; Dhar et al., 2020). Chiefly, the bacteria perform aerobic PAH degradation using oxygenase-facilitated metabolism (comprising monooxygenase and dioxygenase enzymes). The first step in the aerobic PAH degradation is the hydroxylation of the aromatic ring through dioxygenase enzymes and formation of the cis-dihydrodiol, which ultimately oxidized to diol intermediates with the help of dehydrogenase enzymes.

These diol intermediates finally break open through the action of intra diol or extra diol ring-breaking dioxygenases via either ortho-cleavage or meta-cleavage pathway, able to form intermediates such as catechol, gentisic acids, and protocatechuic acid, which finally transform to tricarboxylic acid (TCA) cycle intermediates (Mallick et al., 2011). Dioxygenase is the multi-enzyme complex usually comprising of reductase, ferredoxin, and terminal oxygenase subunits (Mallick et al., 2011; Ghosal et al., 2016; Wu et al., 2020). Bacteria also strategize PAH degradation by the cytochrome P450-assisted pathway with the formation of trans-dihydrodiols or anaerobically under nitrate- and sulfate-reducing conditions (Lu et al., 2011; Mallick et al., 2011; Yang et al., 2020). Although aerobic PAH degradation is conventional and preferable, anaerobic PAH degradation is gaining more attentions nowadays due to the presence of anoxic conditions in diverse environmental niches such as phreatic zone, deep aquatic sediment, and water-flooded soil (Ghosal et al., 2016; Dhar et al., 2020).

The aerobic and anaerobic bacterial species have been reported extensively in the literature for the degradation of LMW and HWM PAHs through pure cultures, consortia, and mixed bacterial culture approaches (Table 2). The enhanced or complete PAH degradation can be achieved by mixed bacterial cultures and bacterial consortia as results of collaborative catabolic activities of participants and possibly presence of diverse degradation pathways. Therefore, most of the recent studies emphasized on mixed bacterial culture- and consortia-assisted PAH degradation (Vaidya et al., 2018; Haleyur et al., 2019; Patel et al., 2019). Degradation by immobilized bacteria and genetically modified bacteria is also a considerable approach (Peng X. et al., 2018). One of the major difficulties for degradation in soil/sediment is a dispersion of inoculum; it is easy for surface soil, however, challenging for subsurface soil due to limited microbial transport as cells adhere strongly to soil organic matter.

TABLE 2

Polycyclic aromatic hydrocarbon biodegradation under aerobic and anaerobic conditions using bacteria, archaea, fungi, algae, and co-cultures.
Inoculum    PAHs used in the study    Degradation condition    Degradation (%)    References

Bacteria
 

Mixed bacterial cultures DAK11: Pseudomonas aeruginosa DAK11.1, Pseudomonas stutzeri DAK11.2, Achromobacter sp. DAK11.3, and Chelatococcus sp. DAK11.4    Naphthalene, Phenanthrene, Fluoranthene, and Pyrene    Liquid medium Aerobic    75, 86, 76, and 76    Patel et al., 2018
Immobilized Pseudomonas taiwanensis PYR1 and Acinetobacter baumannii INP1 on cinder beads    Pyrene and Indeno[1,2,3-cd]pyrene    Petroleum-contaminated soil Aerobic    71 and 81%    Huang et al., 2016
Bacterial community    16 Priority PAHs    In situ Windrows of 5,000 tons polluted soil Aerobic    85% total PAHs    Lors et al., 2012
Microbial community associated with anaerobic sediment    16 Priority PAHs (with nitrate and sulfate)    Sediment Anaerobic    37, 21, and 28%    Yang et al., 2020

Extremophiles

Halophilic consortia Qphe-SubIV Halomonas strain and unculturable strain belonging to the genus Marinobacter    Phenanthrene    Liquid medium (5% NaCl) Aerobic    >90%    Dastgheib et al., 2012
Acidophilic Stenotrophomonas maltophilia AJH1    Anthracene, Phenanthrene, Naphthalene, Fluorene, Pyrene, Benzo(e)pyrene, and Benzo(k)fluoranthene    Liquid medium (pH 2) Aerobic    91, 90, 96, 95, 86, 82, and 79%    Arulazhagan et al., 2017
Thermophilic Mix culture: Aeribacillus pallidus U2, Bacillus axarquiensis UCPD1, Bacillus siamensis GHP76, and Bacillus subtilis subsp. inaquosorum U277    Anthracene, Fluorene, Phenanthrene, and Pyrene    Liquid medium At 50°C Aerobic    96, 86, 54, and 71%    Mehetre et al., 2019

Archaea

Indigenous halophilic archaean Haloferax elongans, Halobacterium noricense, Haloferax larsenii, Halobacterium salinarum, and Halobacterium sp.    Phenanthrene    Soil and liquid medium Aerobic    28, 29, 28, 37, and 22%    Al-Mailem et al., 2017
Haloarchaea strains: Ten strains of Haloferax sp.    Naphthalene, Anthracene, Phenanthrene, Pyrene, and Benzo(a)anthracene    Hypersaline petroleum produced water (20% NaCl) Aerobic    20–80%    Bonfá et al., 2011

Ligninolytic fungi

Candida tropicalis NN4    Indeno[1,2,3-cd] pyrene    Liquid medium Aerobic    91%    Ojha et al., 2019
Fungal mycelia: Armillaria mellea, Pleurotus ostreatus, Pleurotus eryngii, and Stropharia ferii    Anthracene and Benzo(a)pyrene    Contaminated soil Aerobic    95 and 50%    Baldantoni et al., 2017

Non-ligninolytic fungi

Cladosporium sp. CBMAI 1237    Anthracene, Acenaphthene, Fluorene, Phenanthrene, Fluoranthene, and Pyrene    Liquid medium Aerobic    71, 78, 70, 47, 52, and 62%    Birolli et al., 2018
Lasiodiplodia theobromae    Benzo(a)pyrene    Garden soil Aerobic    92%    Wang et al., 2014

Algae

Selenastrum capricornutum and Scenedesmus acutus    Benzo(a)pyrene    Liquid medium Aerobic    99 and 95%    De Llasera et al., 2016
Rhodomonas baltica    Phenanthrene, Fluoranthene, and Pyrene    Liquid medium Aerobic    70%    Arias et al., 2017

Co-cultures

Bacterial–fungal consortium: Serratia marcescens L-11, Streptomyces rochei PAH-13, and Phanerochaete chrysosporium VV-18    Fluorene, Anthracene, Phenanthrene, and Pyrene    100 g soil in pot, Aerobic    98, 66, 90, and 55%    Sharma et al., 2016
Bacterial–algal synergy: Chlorella sp. MM3 and Rhodococcus wratislaviensis 9    Phenanthrene, Pyrene, and Benzo(a)pyrene    Soil slurry Aerobic    100%    Subashchandrabose et al., 2019
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The immobilization of delivering inoculum microbes can serve the solution by increasing shelf life and activities of microbes in the soil system (Mrozik and Piotrowska-Seget, 2010). Huang et al. (2016) reported enhanced pyrene and indeno[1,2,3-cd]pyrene degradation (71 and 81%) in petroleum-contaminated soil using immobilized Pseudomonas taiwanensis PYR1 and Acinetobacter baumannii INP1 on cinder beads. Immobilization provides biological stability to inoculum microbes, protection from suboptimum substandard environmental conditions, and reduced competition with indigenous microbes (Mrozik and Piotrowska-Seget, 2010). Apart from mesophilic bacteria, bacterial extremophiles such as halophilic, acidophilic, and thermophilic have also been reported for PAH degradation (Table 2). Application of thermotolerant and thermophilic bacteria for PAH degradation is beneficial, as elevated temperature causes increased diffusion of PAHs by decreasing viscosity, ultimately increasing the bioavailability of PAHs (Mehetre et al., 2019). Over the last decade, bacterial community analysis (Muangchinda et al., 2018; Yang et al., 2020), biochemical pathways in bacteria for PAH degradation (Chen et al., 2016; Vaidya et al., 2017), degradation-associated bacterial genes (Peng T. et al., 2018; Sangkharak et al., 2020), enzyme systems (Chen et al., 2016; Wu et al., 2020), and gene regulation of PAH degradation processes (Kan et al., 2020; Wu et al., 2020) have been researched enormously.

Archaea

Extreme environmental habitats, particularly saline regions, are most vulnerable to petroleum pollution due to their close connection with oil industries, which mostly release many pollutants, including PAHs, and demand extremophiles rather than conventional microorganisms for bioremediation (Dastgheib et al., 2012). Over the past few years, archaea have drawn the attention of researchers for PAH bioremediation, although few research studies have been reported (Table 2). The degradation pathways and mechanisms behind bioremediation via archaea have not been extensively studied like bacteria (Khemili-Talbi et al., 2015). Khemili-Talbi et al. (2015) isolated biosurfactant-producing halophilic arhaeon Natrialba sp. C21 from oil-polluted saline water for degradation of phenol, naphthalene, and pyrene at very high salinity conditions (25% NaCl). They also attempted to find the degradation pattern via enzyme assays such as catechol 1,2-dioxygenase, catechol 2,3-dioxygenase, protocatechol 3,4-dioxygenase, and protocatechol 4,5-dioxygenase. The maximum activity of catechol 1,2-dioxygenase indicated that degradation occurred via the ortho-cleavage pathway.

Fungi

Mycoremediation of PAHs has been widely reported in the past several years with numerous fungal species. Unlike bacteria, all fungi do not utilize PAHs as a sole source of carbon; rather, they co-metabolize the PAHs and generate a range of oxidized products including CO2. The fungi execute monooxygenase enzyme-mediated PAH degradation (Gupta and Pathak, 2020). Mainly two types, i.e., ligninolytic fungi (white-rot fungi) and non-ligninolytic fungi, have been reported in the literature for LMW and HMW PAH bioremediation (Table 2). Ligninolytic fungi produce enzymes such as lignin peroxidase, manganese peroxidase, and laccases for degradation of lignin present in the wood and simultaneously oxidize the PAHs and convert into diphenol intermediates that eventually oxidize into quinones (Aydin et al., 2017). Ligninolytic enzymes generate water-soluble polar products after catalytic cleavage of aromatic compounds, which are eventually available for fungal metabolism and soil microflora present in the vicinity (Gupta and Pathak, 2020).

On the other hand, non-ligninolytic fungi produce cytochrome P450 monooxygenase-like enzymes, which oxidize the PAHs and lead to form arene oxide and water; further, arene oxides through non-enzymatic rearrangement form phenols, which conjugate with xylose, gluconeric acid, and glucose (Cerniglia and Sutherland, 2010; Ghosal et al., 2016). Some fungal species are also capable of producing biosurfactants in order to overcome the hindrance of less soluble HMW PAHs, which resulted in better degradation (Ojha et al., 2019). Limited studies have been reported on the mechanisms and pathways involved in the breakdown of PAHs through mycoremediation (Aydin et al., 2017; Agrawal et al., 2018). Direct fungi application in the field has many limitations including inadequate biomass growth, huge biomass handling difficulties, lack of application methodologies, and bulk degrading enzyme production, which can be overcome by oxidative fungal enzyme-mediated PAH bioremediation (Harms et al., 2011).

Algae

Algae, the primary producers in coastline and estuarine ecosystems, may have a significant role in PAH bioremediation within aquatic ecosystems. Alga-mediated effective PAH removal occurs through cellular biodegradation and/or bioaccumulation (Ke et al., 2010). PAH biodegradation employs both monooxygenase and dioxygenase enzymatic pathways and produces hydroxylated and dihydroxylated intermediates, respectively, depending on the algal type (Chan et al., 2006). Microalgae (Cyanobacteria) are freshwater unicellular green alga, have gained huge attention for its ubiquitous occurrence, easy to propagate, and most prominent efficiency of degrading HMW PAHs (Ke et al., 2010; De Llasera et al., 2016). Few reports on alga-based PAH bioremediation are listed in Table 2. Many alga-based PAH removal studies at the laboratory or microcosm scale have been reported in the literature, although large- or field-scale alga-mediated PAH remediation remains to be uncovered and requires scientific attention to develop successful strategies.

Co-cultures

Co-culturing approaches such as bacterial–fungal co-cultures, fungal–algal synergy, and bacterial–algal synergy are proven as the most efficient bioremedial approaches at the laboratory as well as large-scale applications (Sharma et al., 2016; Subashchandrabose et al., 2019; Table 2). During aerobic degradation, algae supply oxygen to enhance degradation. The bacterial–algal synergy is more advantageous over bacterial consortia and bacterial–fungal co-cultures because algae provide various extra polymeric and lightweighted compounds (consist of lipids, proteins, nucleic acids, fermentation products, etc.), which promote bacterial and/or fungal growth and thus enhance PAH degradation (Kuppusamy et al., 2017).

Microbial Enzyme-Mediated Bioremediation

Microbial enzyme-mediated bioremediation involves the use of isolated enzymes from bacteria, fungi, and other living organisms for PAH removal. The enzymatic action is extremely efficient and selective due to higher reaction rates and the capability to catalyze reactions at a wide range of temperature and pH. Oxygenase, dehydrogenase, lignin peroxidase, manganese peroxidase, laccases, and phenoloxidases are enzymes responsible for PAH oxidation as mentioned in above subsections (Mohan et al., 2006). The oxidative enzymes from fungi are more efficient because they are less substrate-specific enzymes (Harms et al., 2011; Gupta and Pathak, 2020). Zhang et al. (2020) isolated novel manganese peroxidase gene from Cerrena unicolor BBP6 and cloned into Pichia pastoris, which had various dye-decolorizing ability along with 80 and 91% of fluorene and phenanthrene degradation activity within 24 h, and the highest recombinant enzyme expression was 154.5 Unit.L–1. The only drawback of this method is cost related to production, extraction, and purification of enzymes (Kuppusamy et al., 2017).

Strategies for Polycyclic Aromatic Hydrocarbon Bioremediation

Land farming is a cost-effective and safe treatment for polluted land, in which the native microbiome at a polluted site is stimulated for PAH degradation via improving aeration, moisture, and nutrient levels so that the connection of microbes is improved with pollutants and nutrients (Agnello et al., 2016; Kuppusamy et al., 2017). The reduction rate is much higher for LMW PAHs (2–3 rings) than HMW PAHs (4–6 rings), and this method is applied usually for a thin layer of land surface (Das and Das, 2015; Silva-Castro et al., 2015; García-Sánchez et al., 2018). This simple method requires less maintenance, nearly no cleanup obligations, and slight monitoring efforts. Limitations are slow degradation rate after initial rapid degradation rate due to the concentration gradient of pollutants, affected only superficial 10–35-cm accessible soil layer, and largely influenced by surrounding uncontrollable and unintentional conditions like heavy rainfall (Gan et al., 2009).

Natural attenuation method enhances the degradation capacities of innate microbiome by improving aeration, moisture, and nutrient levels. If natural attenuation is performed on polluted land, then it is a good example of land farming method. Chikere et al. (2017) reported 98% total petroleum hydrocarbon and 85% poly aromatic hydrocarbon degradation by enhanced natural attenuation in crude oil-polluted field-scale bioremediation after. The enhanced natural attenuation was processed by nutrient addition (N:P:K ratio 2:1:1), tilling, periodic water irrigation, and intermittent turning of soil to make sure there was uniform aeration (Chikere et al., 2017).

Biostimulation is a remediation method in which the activities of indigenous microbes can be encouraged by the addition of nutrients (N,P,S, and K), slow/fast releasing fertilizers, organic wastes, humic acid, and/or terminal electron acceptor. It is basically used to overcome limitations of microbial growth and activities. Different combinations of macro- and micro- nutrients are used to enhance PAH degradation (Das and Das, 2015). Patel et al. (2019) tested NPK fertilizer, urea fertilizer, and AS fertilizer as biostimulating agents to enhance phenanthrene and fluoranthene degradation by mixed bacterial cultures. Biostimulation can also be performed through an adaptation approach in which high pre-exposure of target pollutants are applied for adaptation of selective organisms having the capacity to survive and utilize target pollutants (Mohan et al., 2006).

A new era of nanobiotechnology leads to the development of a more competitive biostimulation approach for rapid PAH remediation based on the use of nanofertilizers and nanominerals, which enable broader distribution of nutrients in deeper soil (Kuppusamy et al., 2017). A time interval study conducted by Bianco et al. (2020) on the effects of anaerobic biostimulation such as digestate, fresh organic fraction of solid municipal waste, and combination of micro-/macronutrients (ratio of soil and biostimulants was 10:1) on the degradation of the four PAH mixture (200 mg.kg–1 of anthracene, phenanthrene, pyrene, and fluoranthene) in marine sediment at 37°C and 130 rpm confirmed biostimulation efficiency for PAH degradation (55%) compared to control without any supplementation (12%). The application of digestate and organic waste as biostimulants during degradation signifies the economic perspective as well as encourages the renewable remediation strategy (Bianco et al., 2020). Blood meal is a dark-colored complex non-toxic liquid of animal origin, which acts as a slow releasing fertilizer and is rich with lysine, valine, leucine, tryptophan, and histidine. Recently, biostimulation using blood meal along with weekly soil plowing was studied for in situ bioremediation of dichlorodiphenyltrichloroethane (DDT)- and PAH-polluted farmland soil (Wang et al., 2017).

Composting is one of the most preferable and cost-effective remediation methods for pollutant degradation in soil, which improves soil organic content and soil fertility, and it is one type of biostimulation in which organic content is added (Chen et al., 2015). Composting remediation is more successful for 3- and 4-ring PAHs than 5- and 6-ring PAHs, as higher ring PAHs may negatively affect the microbial activities of compost and their natural bioavailability was low (Gan et al., 2009; Guo et al., 2020). The compost bulking agents such as spent mushroom, soot waste, agricultural wastes, maple leaves, cow manure, pig manure, activated sludge, etc., can be used in PAH degradation that support the enhancement of microbial population and raise the required temperature for degradation (Mohan et al., 2006; Shah, 2014; Das and Das, 2015). Guo et al. (2020) studied biodegradation of PAHs in polluted sewage sludge by a co-composting method using green forest waste. The experiments were performed with three different rations of sewage sludge and green forest waste. PAH degradation (75.2%) was highest in ratio 3:2, followed by ratio 3:1 (70.7%) and ratio 3:3 (62.4%) after 50 days of composting in compost windrows (1.5 m width × 1.2 m height × 10 m length).

Bioaugmentation is the introduction of inoculum of pollutant-degrading single microorganisms or group of microorganisms to achieve optimum degradation and sometimes to improve the catabolic capacities of indigenous microbes (Das and Das, 2015). It is effective, rapid, easily publicly adaptable, easily applicable, and versatile alternative for PAH degradation; nevertheless, unpredictable (Kong et al., 2018). Application of the bioaugmentation strategy for PAH degradation may include bacteria, archaea, fungi, and algae as pure cultures as well as mixed cultures; detailed description is presented in the section Microbial Remediation of Polycyclic Aromatic Hydrocarbon Pollution (Ghosal et al., 2016). The degradation of PAHs by microorganisms occurs in the presence of oxygen and in the absence of oxygen, which are called aerobic degradation and anaerobic degradation, respectively. In anaerobic biodegradation, microbes use other substances such as nitrate, sulfate, iron, manganese, and carbon dioxide as electron exchanger during degradation and produce carbon dioxide and methane as the final products. Anaerobic biodegradation is helpful to remediate the deep underground soil where oxygen is absent or very low (Gan et al., 2009).

Bioreactor is an ex situ controlled system for efficient PAH degradation; addition of non-ionic surfactants, bioaugmentation with useful microbes, and/or biostimulation with additional nutrients enhance PAH bioremediation process in bioreactors (Mohan et al., 2006). Soil column and soil slurry bioreactors degrade effectively the soil-bound contaminants under controlled and optimized conditions. The continuous fed batch reactors (anaerobic-anoxic-aerobic, 5 L each) were proved to be potential for 300 mg.L–1 of naphthalene degradation (99%) in influent wastewater from coke oven industry along with sulfate and ammonical nitrogen as biostimulants and cow dung slurry as inoculum by Yadu et al. (2019). Forján et al. (2020) designed a pilot- scale soil slurry bioreactor for PAH-polluted factory soil in which dissolved oxygen (8 mg/L), pH (∼8), and temperature (28°C) probes were constantly controlled. Soil slurry bioreactor was prepared by combined approach of biostimulation (C:N:P ratio of 100:10:1) and bioaugmentation using Rhodococcus erythropolis, which reported 89.3, 79.7, 72.0, and 82.1% degradation of 2-ring, 3-ring, 4–6-ring, and total PAHs, respectively, after 15 days of bioreactor process (Forján et al., 2020).

Phytoremediation is an in situ method in which the plants are used to remove PAHs or to convert them into less harmful components in soil, sediment, surface water, and groundwater (Das and Das, 2015). Plants remediate the organic pollutants by different mechanisms such as phytoextraction (withdrawal of pollutants from soil), phytovolatilization (atmospheric release of volatile pollutants from soil via plant organs), and phytodegradation (degradation of pollutants by enzymes released from plant and/or plant-associated microbes) (García-Sánchez et al., 2018). Plants help in soil aeration by increasing permeability and by cracking soil masses, which favor PAH aerobic biodegradation (Gitipour et al., 2018).

During phytoremediation, plants resist easily a range of environmental assaults due to their sessile characteristic. Plants are selected ideally based on their quality to grow at a polluted site and growth time, biomass productivity, ability to support active soil microbial population, capability to degrade pollutants, and capability to adapt to environmental conditions (Cook and Hesterberg, 2013). Economic viewpoint suggests phytoremediation with grass is preferable due to less maintenance, low nutrient requirements, robust growth, tolerance for sought, acidic and, cold conditions, and their very fibrous root system, which may help enhance soil microbial activities (Gan et al., 2009; Cook and Hesterberg, 2013).

He and Chi (2019) investigated phytoremediation capabilities of two submerged aquatic plants, Vallisneria spiralis and Hydrilla verticillata, in PAH-polluted sediments at pilot scale. The experiment was conducted for 108 days, and results indicated that dissipation of phenanthrene and pyrene was highest in sediment planted with V. spiralis (85.9 and 79.1%), followed by sediment planted with H. verticillata (76.3 and 64.6%) and unplanted sediment (76.3 and 64.6%). Higher dissipation of phenanthrene and pyrene in planted sediments was due to plant-supported biodegradation and plant uptake (He and Chi, 2019). Phytoremediation of soil polluted by fly ash PAHs using willows of Salix × smithiana Willd (checked) was used to remove 50.9% PAHs after 3 years of treatment (checked), which was higher as compared to 9.9% ash PAH removal by natural attenuation in soil (Košnáø et al., 2020).

Rhizoremediation is one specific subset of phytoremediation, in which plant-associated rhizosphere microorganisms are used for treatment of polluted soils (Das and Das, 2015). Rhizoremediation is more intensive for PAH degradation and a key of successful rhizoremediation is dependent on the appropriate partnership of plant and microbes that have degradation capabilities (Agnello et al., 2016; Eskandary et al., 2017). Plants provide the huge root surface area for microbial growth and remediate pollutants approximately 10–15 m deep in the soil (Bisht et al., 2015). In rhizoremediation, plant roots supply the nutrients for growth and activities of PAH-degrading microbes in the form of carbohydrates, amino acids, flavonoids, and organic acids, whereas microbes compensate by supporting the plants to conquer against stress generated due to pollutants and reduce the phytotoxicity (Bisht et al., 2015; Eskandary et al., 2017). Kong et al. (2018) conducted field-scale PAH degradation study (3 m × 1.2 m, 0.4 m depth, and 5 tons soil) for 175 days in aged polluted soil of 50-year-old coking plants.

Comparison of four different methods indicated that microbe-associated phytoremediation (Rhodococcus ruber Em1 associated with Orychophragmus violaceus) was superlative among natural attenuation, bioaugmentation (Rhodococcus ruber Em1), and phytoremediation (Orychophragmus violaceus). R. ruber Em1 combined with O. violaceus significantly enhanced the removal of 16 PAHs, 54% as compared to 18, 30, and 36% in other methods. The removal of HMW PAHs with 4–6 rings were much greater by microbe-associated phytoremediation methods (55%) as compared to natural attenuation (10%) and phytoremediation (20%) (Kong et al., 2018). García-Sánchez et al. (2018) also compared four different PAH bioremediation approaches via pot experiments with 5 kg of aged polluted soil for 180 days. They found a microbe-associated phytoremediation approach using maize plants along with white rod fungi and indigenous microorganisms as the most beneficial for removal of LMW, HMW, and total 16 PAHs as compared to other approaches, i.e., natural attenuation, myco-augmentation using white rod fungi Crucibulum leave, and phytoremediation using maize plants (García-Sánchez et al., 2018).

The advantages of phytoremediation and rhizoremediation as compared with other approaches are that they preserve the natural conditions of the soil, energy is derived primarily from sunlight, high level of microbial biomass in the soil can be achieved, and both are cost-effective and environment-friendly methods. The major drawbacks of both methods are the site where plants cannot grow, large land requirement, limited remediation depth, only applicable for low-level polluted site (plant tolerance level), highly dependent on climate and seasonal conditions, disposal of accumulated PAHs from plant parts, unknown effects of biodegradation products, risk for pollutants to enter the food chain, and uncertainty in treatment duration prediction (Gan et al., 2009; Bisht et al., 2015; Gitipour et al., 2018).

Vermiremediation is used as individual and combined with microbes or plants for PAH removal from fine soil (pores size < 0.1 μm). PAHs in pores of fine soil are not bioavailable and bioaccessible for degrading bacteria (size 1–10 μm) and plant root hairs (size 15–17 μm). During vermiremediation, burrowing actions of earthworms enlarge the soil pore size; therefore, degrading microbes and plant root can penetrate into the soil, able to grow and finally able to degrade hidden PAHs (Kuppusamy et al., 2017). Earthworms also remove PAHs from the soil by either dermal absorption or intestinal digestion that biotransform or biodegrade into harmless compounds (Sinha et al., 2008). Benefits of vermiremediation include improvement of physical/biological soil quality, excretion of nutritive constituents as vermicasts, and proliferation of beneficial soil microorganisms (Rorat et al., 2017). Earthworms reproduce speedily using less or no energy, which possibly enhance PAH removal in a short time duration, proving vermiremediation to be very cost-effective, eco-friendly, and sustainable (Sinha et al., 2008). The addition of earthworms Eisenia andrei in sewage sludge bioreactor after precomposting had led to higher PAH removal (86, 58, and 62% under three different pre-composting processes) after 5 weeks (Rorat et al., 2017). The only drawback of vermiremediation is that it is applicable for low and medium polluted sites, where earthworms are able to survive and grow (Kuppusamy et al., 2017).

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7674206/

 
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A strategy to realize the efficient resonant absorption of guided water waves

2023

https://phys.org/news/2023-12-strategy-efficient-resonant-absorption.html

 

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Harnessing the oceans to 'bury' carbon has huge potential—and risk—so NZ needs to move with caution

2023

https://phys.org/news/2023-12-harnessing-oceans-carbon-huge-potentialand.html

 

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Chapter 6 - Potential of microbes for degradation of xenobiotics: With special focus on petroleum hydrocarbons

2022

https://www.sciencedirect.com/science/article/abs/pii/B9780323899376000152 

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Amphiphilic Magnetic Particles Dispersed in Water and Oil for the Removal of Hydrophilic and Hydrophobic Microplastics

April 10, 2024

https://pubs.acs.org/doi/10.1021/acsami.3c19398

 
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3° Oil Recovery: Fundamental Approaches and Principles of Microbially Enhanced Oil Recovery

https://link.springer.com/referenceworkentry/10.1007/978-3-540-77587-4_202

 

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Magnetic permanently confined micelle arrays for treating hydrophobic organic compound contamination

2008

https://pubmed.ncbi.nlm.nih.gov/19055347/

____________________________________


Controllable hydrophobicity of magnetoactive elastomer coatings

2017

https://www.sciencedirect.com/science/article/abs/pii/S0304885317321546

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Making a Frictionless Torpedo

2022

https://www.youtube.com/shorts/jcdzl8bXu_g

____________________________________


Hydrophobic and magnetic fabrication of hydroxyethyl cellulose-lignin aerogel through ultrasound enhancement for efficient oil/water separation

2023

https://www.sciencedirect.com/science/article/abs/pii/S221471442300020X

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Biodegradable aerogel: Airy cellulose from a 3D printer

April 4, 2024

https://phys.org/news/2024-04-biodegradable-aerogel-airy-cellulose-3d.html

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Controllable pore size of super-hydrophobic magnetic core-shell nanospheres with dendritic architecture and their pore-dependent performances in oil/water separation

2023

https://www.sciencedirect.com/science/article/abs/pii/S1383586623013424

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Superhydrophobic magnetic sorbent via surface modification of banded iron formation for oily water treatment

30 June 2022

https://www.nature.com/articles/s41598-022-15187-6

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High-performance hydrophobic magnetic hydrotalcite for selective treatment of oily wastewater

2021 Nov 29

https://pubmed.ncbi.nlm.nih.gov/34738879/

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High-speed magnetic control of water transport in superhydrophobic tubular actuators

21 October 2022

https://www.nature.com/articles/s41427-022-00431-2

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Droplet-based nanogenerators for energy harvesting and self-powered sensing

17th August 2021

https://pubs.rsc.org/en/content/articlehtml/2021/nr/d1nr05386h

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Magnetoswitchable Controlled Hydrophilicity/Hydrophobicity of Electrode Surfaces Using Alkyl-Chain-Functionalized Magnetic Particles:  Application for Switchable Electrochemistry

September 29, 2004

https://pubs.acs.org/doi/10.1021/la048476%2B

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Facile Surface Functionalization of Hydrophobic Magnetic Nanoparticles

August 20, 2014

https://pubs.acs.org/doi/10.1021/ja5060324

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Magnetic nanofluid based on hydrophobic deep eutectic solvent for efficient and rapid enrichment and subsequent determination of cinnamic acid in juice samples: Vortex-assisted liquid-phase microextraction

2023

https://www.sciencedirect.com/science/article/abs/pii/S0039914023003326


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Bifunctional hydrophobic deep eutectic solvents for selective recovery of Sm and Co from waste SmCo permanent magnets

2023

https://www.sciencedirect.com/science/article/abs/pii/S1226086X23005919

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Magnetic hydrophobic deep eutectic solvents for orbital shaker-assisted dispersive liquid-liquid microextraction (MAGDES-OS-DLLME) - Determination of nickel and copper in food and water samples by FAAS

2023

https://www.sciencedirect.com/science/article/abs/pii/S0889157523007172

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Aptamer functionalized magnetic hydrophobic polymer with synergetic effect for enhanced adsorption of alternariol from wheat

2023

https://www.sciencedirect.com/science/article/abs/pii/S030881462302174X

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Fundamentals of magnet-actuated droplet manipulation on an open hydrophobic surface

2009 Mar 9

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC2932710/

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Water droplets become hydrobots by adding magnetic beads

June 3, 2021

https://phys.org/news/2021-06-droplets-hydrobots-adding-magnetic-beads.html

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Hydrophobic Drug-Loaded PEGylated Magnetic Liposomes for Drug-Controlled Release

18 May 2017

https://link.springer.com/article/10.1186/s11671-017-2119-4

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Magnetically responsive hydrophobic pockets for on–off drug release

2021

https://www.sciencedirect.com/science/article/pii/S2468519421002822

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Hydrophobic magnetic nanoparticle assisted catanionic surfactant supramolecular solvent microextraction of multiresidue antibiotics in water samples

July 2021

https://www.researchgate.net/publication/352352082_Hydrophobic_magnetic_nanoparticle_assisted_catanionic_surfactant_supramolecular_solvent_microextraction_of_multiresidue_antibiotics_in_water_samples

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Liquid-liquid microextraction with hydrophobic deep eutectic solvent followed by magnetic phase separation for preconcentration of antibiotics

2022

https://www.sciencedirect.com/science/article/abs/pii/S0039914022006646

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An air-assisted dispersive liquid phase microextraction method based on a hydrophobic magnetic deep eutectic solvent for the extraction and preconcentration of melamine from milk and milk-based products

2023

https://www.sciencedirect.com/science/article/abs/pii/S0308814623011913

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Fabrication of hydrophobic and magnetic cellulose aerogel with high oil absorption capacity

2013

https://www.sciencedirect.com/science/article/abs/pii/S0167577X1301450X

____________________________________


Non-expensive hydrophobic and magnetic melamine sponges for the removal of hydrocarbons and oils from water

2019

https://www.sciencedirect.com/science/article/abs/pii/S1383586618338693


____________________________________


Rapid Magnetic Catch-and-Release Purification by Hydrophobic Interactions

July 2, 2009

https://pubs.acs.org/doi/10.1021/la901351s


____________________________________


Recovery of rare earth metal oxides from NdFeB magnet leachate by hydrophobic deep eutectic solvent extraction, oxalate stripping and calcination

2023

https://www.sciencedirect.com/science/article/abs/pii/S0304386X23001925

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Silica Removal Using Magnetic Iron-Aluminum Hybrid Nanomaterials: Measurements, Adsorption Mechanisms, and Implications for Silica Scaling in Reverse Osmosis

2019 Oct 29

https://pubmed.ncbi.nlm.nih.gov/31621307/

____________________________________


Magnetic nanoparticles draw solution for forward osmosis: Current status and future challenges in wastewater treatment

2022

https://www.sciencedirect.com/science/article/pii/S2213343722018280

____________________________________


Effectiveness and mechanisms of electromagnetic field on reverse osmosis membrane scaling control during brackish groundwater desalination

2021

https://www.sciencedirect.com/science/article/abs/pii/S1383586621015306

____________________________________


Desalination of saline water via forward osmosis using magnetic nanoparticles covalently functionalized with citrate ions as osmotic agent

2020 Dec 22

https://pubmed.ncbi.nlm.nih.gov/33332242/

____________________________________


Thermoresponsive Magnetic Nanoparticles for Seawater Desalination

October 17, 2013

https://pubs.acs.org/doi/10.1021/am403719s

____________________________________


Removal of microplastics from water by magnetic nano-Fe3O4

2021

https://www.sciencedirect.com/science/article/abs/pii/S0048969721049135

____________________________________


World's Strongest Magnet!

Mar 14, 2023

https://www.youtube.com/watch?v=g0amdIcZt5I

 
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Energy harvesting

 

https://en.wikipedia.org/wiki/Energy_harvesting


Energy harvesting (also known as power harvesting or energy scavenging) is the process by which energy is derived from external sources (e.g. solar power, thermal energy, wind energy, salinity gradients, and kinetic energy), captured, and stored for small, wireless autonomous devices, like those used in wearable electronics and wireless sensor networks.

Energy harvesters provide a very small amount of power for low-energy electronics. While the input fuel to some large-scale generation costs money (oil, coal, etc.), the energy source for energy harvesters is present as ambient background and is free. For example, temperature gradients exist from the operation of a combustion engine and in urban areas, there is a large amount of electromagnetic energy in the environment because of radio and television broadcasting.

Piezoelectric

The piezoelectric effect converts mechanical strain into electric current or voltage. This strain can come from many different sources. Human motion, low-frequency seismic vibrations, and acoustic noise are everyday examples. Except in rare instances the piezoelectric effect operates in AC requiring time-varying inputs at mechanical resonance to be efficient.
Most piezoelectric electricity sources produce power on the order of milliwatts, too small for system application, but enough for hand-held devices such as some commercially available self-winding wristwatches. One proposal is that they are used for micro-scale devices, such as in a device harvesting micro-hydraulic energy. In this device, the flow of pressurized hydraulic fluid drives a reciprocating piston supported by three piezoelectric elements which convert the pressure fluctuations into an alternating current.

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Preparation on transparent flexible piezoelectric energy harvester based on PZT films by laser lift-off process

 

 http://www.sciencedirect.com/science/article/pii/S0924424712006516

 

 The piezoelectric energy generation properties of transparent flexible devices (TFD) based on PbZr_0.52Ti_0.48O₃ (PZT) films, which were fabricated by laser lift-off (LLO) process, were studied for a piezoelectric energy harvester. Through the introduction of indium-tin-oxide (ITO) and polyethylene terephthalate (PET) substrates, TFDs were implemented, respectively. The TFDs based on PZT films generated an AC-type output signal and output power of 8.4 nW/cm², at periodically bending and releasing motion. In addition, inverted output signals were observed when the manufactured TFDs were connected to the measuring equipment in reverse and were bended to the reverse direction, demonstrating that the generating signals originated from the piezoelectric effect of TFDs. The experimental results clearly showed that the TFDs based PZT film have potential for use in next generation of electronic devices applications such as flexible devices, transparent electronics, and energy harvester.

 

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Scientists use shape-fixing nanoreactor to make a better fuel cell catalyst

 

May 11, 2015

 http://phys.org/news/2015-05-scientists-shape-fixing-nanoreactor-fuel-cell.html?utm_source=menu&utm_medium=link&utm_campaign=item-menu

 

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Laser-machined piezoelectric cantilevers for mechanical energy harvesting

 In this study, we report results on a piezoelectric- material-based mechanical energy-harvesting device that was fabricated by combining laser machining with microelectronics packaging technology. It was found that the laser-machining process did not have significant effect on the electrical properties of piezoelectric material. The fabricated device was tested in the low-frequency regime of 50 to 1000 Hz at constant force of 8 g (where g = 9.8 m/s²). The device was found to generate continuous power of 1.13 muW at 870 Hz across a 288.5 kOmega load with a power density of 301.3 muW/cm³.


 http://ieeexplore.ieee.org/xpl/login.jsp?tp=&arnumber=4626918&url=http%3A%2F%2Fieeexplore.ieee.org%2Fiel5%2F58%2F4626908%2F04626918.pdf%3Farnumber%3D4626918

 
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Bismuth-Ferrite Piezoelectric Material Opens New Roads for Energy Generation

November 15, 2009

 http://www.greenoptimistic.com/bismuth-ferrite-piezoelectric-material-opens-new-roads-for-energy-generation-20091115/#.VSIYCeG-2zk


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Chinese Scientists Find Alternative to Lead-Containing Mainstream Piezoelectric Material

 

April 2, 2012

http://www.greenoptimistic.com/zinc-oxide-vanadium-piezoelectric-20120402/#.VSIYEOG-2zk
 

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Energy-Saving Thermoelectric Material Made From Dirt

November 29, 2012

A team of researchers at Michigan State University have developed a new type of thermoelectric material by using common materials found in dirt. The researchers developed this material using what they know about tetrahedrites, one of the most abundant minerals on Earth.

MSU Professor of Chemical Engineering, Donald Morelli, and his team figured out how to synthesize compounds that have the same chemical composition as natural minerals and closely mimic tetrahedrites. By modifying the composition, researchers have been able produce even more efficient thermoelectric material.

Why is this important? Themoelectric energy needs to be more efficient to be a viable energy source. For example, if thermoelectric was more efficient, the heat generated by a car engine that travels through the tail pipe could then be converted into actual electricity. By tweaking the composition, researchers are coming closer to making this a reality.

 http://www.greenoptimistic.com/thermoelectric-material-dirt-20121129/

 

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Proof-of-Concept Piezoelectric Generators Used to Recover Energy from Wind

 

November 24, 2009

http://www.greenoptimistic.com/andreopoulos-piezoelectric-wind-power-20091124/#.VSIbWOG-2zk

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 Scientists harvest energy from beam's self-induced, self-sustaining vibrations in airflow

July 27, 2015

http://phys.org/news/2015-07-scientists-harvest-energy-self-induced-self-sustaining.html#jCp


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New Piezo Crystals Harness Sound Waves to Generate Hydrogen Fuel

 03/17/10

http://inhabitat.com/new-piezo-crystals-harness-sound-waves-to-generate-hydrogen-fuel/



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Fuel-free nanomotor is powered by ultrasound and magnetic fields

 

Jun 26, 2015

 Nanoscale motors, like their macroscale counterparts, can be built to run on a variety of chemical fuels, such as hydrogen peroxide and others. But unlike macroscale motors, some nanomotors can also run without fuel, instead being powered by either magnetic or acoustic fields. In a new paper, researchers for the first time have demonstrated a nanomotor that can run on both magnetic and acoustic fields, making it the first magneto-acoustic hybrid fuel-free nanomotor.


 http://phys.org/news/2015-06-fuel-free-nanomotor-powered-ultrasound-magnetic.html?utm_source=menu&utm_medium=link&utm_campaign=item-menu

 

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Ear-Piercing Sounds Harvested for Energy

Dec 6, 2013

http://news.discovery.com/tech/alternative-power-sources/ear-piercing-sounds-harvested-for-energy-131206.htm

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Engineering students use sound waves to put out fires

 

Mar 26, 2015

 

 http://phys.org/news/2015-03-students.html

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German student creates electromagnetic harvester that gathers free electricity from thin air

February 12, 2013 


 A German student has built an electromagnetic harvester that recharges an AA battery by soaking up ambient, environmental radiation. These harvesters can gather free electricity from just about anything, including overhead power lines, coffee machines, refrigerators, or even the emissions from your WiFi router or smartphone.

 http://www.extremetech.com/extreme/148247-german-student-creates-electromagnetic-harvester-that-gathers-free-electricity-from-thin-air


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New technique for generating electricity from mechanical vibrations

 

Nov 12, 2014

http://www.gizmag.com/mechanical-vibration-generate-electricity/34701/


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New Cell Phone Charging System Harvests Energy from Vibrations

02/28/14

 http://inhabitat.com/university-of-wisconsin-develops-cell-phone-charging-system-that-harvests-energy-from-vibrations/


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Pavegen looking to harness energy from pedestrian footsteps

 

May 28th, 2015

 http://phys.org/news/2015-05-pavegen-harness-energy-pedestrian-footsteps.html#nRlv

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Portland to generate electricity within its own water pipes

 February 17, 2015

 http://www.gizmag.com/portland-lucidpipe-power-system/36130/

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Shape-shifting nanoprobes report on internal body conditions using magnetic fields

 

 April 5, 2015

 

 Scientists at the National Institute of Standards and Technology (NIST) and the National Institutes of Health (NIH) have developed a new type of shape-shifting nanoprobe that can perform high-resolution remote biological sensing not possible with current technology. Around one-tenth the size of a single red blood cell, the nanoprobes are designed to provide feedback on internal body conditions by altering their magnetic fields in response to their environment. The researchers predict wide-spread applications for the nanoprobes in the fields of chemistry, biology, engineering and, one day, to aid physicians in high-accuracy clinical diagnostics.

http://www.gizmag.com/nanoprobes-nist-gem-biosensing-magnetic-fields/36803/


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Study Confirms Magnetic Properties of Silicon Nano-Ribbons

 

October 24, 2012

 

 http://www.bangscience.org/2012/10/study-confirms-magnetic-properties-of-silicon-nano-ribbons/

____________________________________

Heat makes electrons spin in magnetic superconductors

 

4/24/2015

http://article.wn.com/view/2015/04/24/Heat_makes_electrons_spin_in_magnetic_superconductors_Univer/

 

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 Scientists fabricate hexagonal silicon, potentially leading to light-emitting semiconductors

August 18, 2015

 Virtually all semiconductors used in today's electronic devices are made of silicon having a cubic crystal structure, as silicon naturally crystallizes in the cubic form. In a new study, researchers have fabricated silicon in a hexagonal crystal structure, which is expected to exhibit novel optical, electrical, superconducting, and mechanical properties compared with cubic silicon.

 http://phys.org/news/2015-08-scientists-fabricate-hexagonal-silicon-potentially.html#jCp

 

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Researchers prove magnetism can control heat, sound

 

 May 28th, 2015

 http://phys.org/news/2015-05-magnetism.html

 

____________________________________

Ultrafast heat conduction can manipulate nanoscale magnets

 

 June/8/2015

 Researchers at the University of Illinois at Urbana-Champaign have uncovered physical mechanisms allowing the manipulation of magnetic information with heat. These new phenomena rely on the transport of thermal energy, in contrast to the conventional application of magnetic fields, providing a new, and highly desirable way to manipulate magnetization at the nanoscale.

 http://phys.org/news/2015-06-ultrafast-nanoscale-magnets.html#jCp

 

____________________________________

Magnetostrictive resonators as sensors and actuators

http://www.sciencedirect.com/science/article/pii/S0924424712007509

Two types of magnetostrictive resonators – magnetostrictive microcantilever (MSMC) and magnetostrictive particle (MSP) – have been introduced as sensor platforms. Their principles and advantages as sensor platforms are discussed along with the materials selection. A detailed and complete comparison between the MSMC and MSP is given. It is concluded that for the resonators with the same size, an MSP exhibits a higher sensitivity and has a much higher resonant frequency. For the resonators with the same resonant frequency, MSMCs exhibit a much higher sensitivity and have a much smaller size than MSPs. Using antibody as the sensing element, MSP biosensors for in situ detection of Escherichia coli and Listeria monocytogenes are developed and characterized. These biosensors exhibit a high performance. For example, the MSP-antibody biosensors of 1 mm × 0.3 mm × 15 μm exhibit a detection limit less than 100 cfu/ml for in situ detection of bacterial cell in water. A new type actuator is introduced using MSPs. The MSP actuator is operated using AC magnetic field with a frequency close to, but different than, its resonant frequency. The MSP actuator exhibits an unlimited displacement, and its moving direction is controlled by the operating frequency used.



____________________________________

Levitating Magnet May Yield New Approach to Clean Energy

 

 http://engineering.columbia.edu/levitating-magnet-may-yield-new-approach-clean-energy

 

 Achieving nuclear fusion in the laboratory has been a cherished goal of physicists and energy researchers for more than 50 years. That’s because it offers the possibility of nearly endless supplies of energy with no carbon emissions and far less radioactive waste than that produced by today’s nuclear plants, which are based on fission, the splitting of atoms (the opposite of fusion, which involves fusing two atoms together). But developing a fusion reactor that produces a net output of energy has proved to be more challenging than initially thought.

____________________________________

Cleaner Fuel Cells on the Way from Moscow

  

January 1, 2016

 A European research team has been working on ion-exchange membranes that convert energy created by chemical reactions. These membranes are based on amphiphilic compounds, and are synthetic. This has great implications for the use of clean fuel cells.
The team, comprised of Russian, French and German scientists, have been collaborating to create this process that can be possibly used in fuel cells. The study was conducted at the Moscow Institute of Physics and Technology, at the Laboratory of Functional Organic and Hybrid materials.
Batteries produce energy by utilizing the reaction of oxidizing and reducing agents. The batteries’ lifespan is complete when both the agents are consumed. When an accumulator is used, electric energy can be stored in packets.


 http://www.greenoptimistic.com/moscow-clean-fuel-cells/

____________________________________


A new idea for rapid generation of strong magnetic fields using laser pulses

March 25, 2020

https://phys.org/news/2020-03-idea-rapid-strong-magnetic-fields.html

____________________________________


Coherent ultrafast magnetism induced by femtosecond laser pulses

31 May 2009

https://www.nature.com/articles/nphys1285


____________________________________


Space-confined fabrication of hydrophobic magnetic carbon nanofibers for lightweight and enhanced microwave absorption

2022

https://www.sciencedirect.com/science/article/abs/pii/S0008622322004316

____________________________________


Exploiting disorder to harvest heat energy: The potentialities of 2D magnets for thermoelectric applications

April 30, 2024

https://phys.org/news/2024-04-exploiting-disorder-harvest-energy-potentialities.html

 
____________________________________

 

MilliMobile is a tiny, self-driving robot powered only by light and radio waves

September 27, 2023

https://techxplore.com/news/2023-09-millimobile-tiny-self-driving-robot-powered.html

 

____________________________________


New compact chips can convert light into microwaves

March 6, 2024

https://techxplore.com/news/2024-03-compact-chips-microwaves.html

____________________________________


How light can vaporize water without the need for heat

April 23, 2024

Surprising “photomolecular effect” discovered by MIT researchers could affect calculations of climate change and may lead to improved desalination and drying processes.

https://news.mit.edu/2024/how-light-can-vaporize-water-without-heat-0423

____________________________________


Singularity vs 100,000 Lumens

2022

https://www.youtube.com/shorts/AA-vYH3TqG4

 

____________________________________ 

 

The Whitest Thing In The Universe

July 1, 2021

https://www.youtube.com/shorts/yoWnoWylpZI

 

____________________________________

 

Ultrablack thin-film coating could make next-gen telescopes even better

March 12, 2024

https://phys.org/news/2024-03-ultrablack-thin-coating-gen-telescopes.html

____________________________________


Sunrise to sunset, a new window coating blocks heat, not view

April 2, 2024

https://techxplore.com/news/2024-04-sunrise-sunset-window-coating-blocks.html

 

____________________________________

 

Turning glass into a 'transparent' light-energy harvester

January 26, 2024

https://phys.org/news/2024-01-glass-transparent-energy-harvester.html

 

____________________________________


How to make bright quantum dots even brighter

January 31, 2024

https://phys.org/news/2024-01-bright-quantum-dots-brighter.html

 
____________________________________

 

New techniques for making qubits out of erbium

February 8, 2024

Qubits are the building block for quantum technology, and finding or building qubits that are stable and easily manipulated is one of the central goals of quantum technology research. Scientists have found that an atom of erbium—a rare-earth metal sometimes used in lasers or to color glass—can be a very effective qubit.

https://phys.org/news/2024-02-techniques-qubits-erbium.html

 

____________________________________


Scientists use laser light to achieve quantum states at room temperature, a first

2024

https://www.msn.com/en-us/news/technology/scientists-use-laser-light-to-achieve-quantum-states-at-room-temperature-a-first/ar-BB1loFYH

____________________________________


Quantum behavior at room temperature: When laser light makes materials magnetic

April 10, 2024

https://phys.org/news/2024-04-quantum-behavior-room-temperature-laser.html

____________________________________


Quantum breakthrough when light makes materials magnetic

April 10, 2024

https://www.sciencedaily.com/releases/2024/04/240410112818.htm

____________________________________


Capturing greenhouse gases with the help of light

January 12, 2024

https://phys.org/news/2024-01-capturing-greenhouse-gases.html

____________________________________


Team develops light-powered catalyst to make hydrogen

January 10, 2024

https://phys.org/news/2024-01-team-powered-catalyst-hydrogen.html

______________

Phononic switching of magnetization by the ultrafast Barnett effect

10 April 2024

https://www.nature.com/articles/s41586-024-07200-x

____________________________________


Magnetic diffusion

Magnetic diffusion refers to the motion of magnetic fields, typically in the presence of a conducting solid or fluid such as a plasma. The motion of magnetic fields is described by the magnetic diffusion equation and is due primarily to induction and diffusion of magnetic fields through the material. The magnetic diffusion equation is a partial differential equation commonly used in physics. Understanding the phenomenon is essential to magnetohydrodynamics and has important consequences in astrophysics, geophysics, and electrical engineering.

https://en.wikipedia.org/wiki/Magnetic_diffusion

____________________________________


Lasers make magnets behave like fluids

April 18, 2019

https://phys.org/news/2019-04-lasers-magnets-fluids.html

____________________________________


Laser-assisted bending by magnetic force

24 July 2017

https://ietresearch.onlinelibrary.wiley.com/doi/10.1049/joe.2017.0145

____________________________________


Making a superconductor liquid–solid out of the vacuum with hundred-exatesla-strong magnetic fields

January 18, 2024

https://phys.org/news/2024-01-superconductor-liquidsolid-vacuum-exatesla-strong.html

 
____________________________________

A comparison of technologies for remediation of heavy metal contaminated soils

2016

https://www.sciencedirect.com/science/article/abs/pii/S0375674216303818

____________________________________


Remediation of metal contaminated soil with mineral-amended composts

2007

https://www.sciencedirect.com/science/article/abs/pii/S0269749107000772

 
____________________________________

 

Archaea

 

Archaea (/ɑːrˈkiːə/ ^ⓘ ar-KEE-ə; sg.: archaeon /ɑːrˈkiːən/ ar-KEE-ən) is a domain of single-celled organisms. These microorganisms lack cell nuclei and are therefore prokaryotic. Archaea were initially classified as bacteria, receiving the name archaebacteria (in the Archaebacteria kingdom), but this term has fallen out of use.

 

Archaeal cells have unique properties separating them from the other two domains, Bacteria and Eukaryota. Archaea are further divided into multiple recognized phyla. Classification is difficult because most have not been isolated in a laboratory and have been detected only by their gene sequences in environmental samples. It is unknown if these are able to produce endospores.

https://en.wikipedia.org/wiki/Archaea

 

 
____________________________________

List of Archaea genera

Phylogeny

Phylum "Microcaldota"

Phylum "Undinarchaeota"

Phylum "Altarchaeota"

Phylum "Iainarchaeota"

Phylum "Micrarchaeota"

Phylum "Huberarchaeaota"

Phylum "Aenigmatarchaeota"

Phylum "Nanohalarchaeota"

Phylum "Nanoarchaeota"

Phylum "Asgardaeota"

Phylum "Thermoproteota"

Phylum "Hadarchaeota"

Phylum Methanobacteriota_B

Phylum "Hydrothermarchaeota"

Phylum "Methanobacteriota"

Phylum "Thermoplasmatota"

Phylum "Halobacteriota"

https://en.wikipedia.org/wiki/List_of_Archaea_genera

 


____________________________________




Monera

https://en.wikipedia.org/wiki/Monera

 

____________________________________


The growing tree of Archaea: new perspectives on their diversity, evolution and ecology

04 August 2017

https://www.nature.com/articles/ismej2017122

____________________________________


Archaea vs. Bacteria: What Are the Differences?

December 16, 2022

https://www.treehugger.com/archaea-vs-bacteria-5190902


____________________________________


Archaea as a Model System for Molecular Biology and Biotechnology

2023 Jan 6

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9855744/

____________________________________


BP's Archaea Energy achieves major milestone, brings online first of its kind renewable natural gas plant

Oct 4, 2023

https://finance.yahoo.com/news/bps-archaea-energy-achieves-major-130000104.html?guccounter=1&guce_referrer=aHR0cHM6Ly9kdWNrZHVja2dvLmNvbS8&guce_referrer_sig=AQAAAKvjmMsgxCilNc9fy2mDSKDR3zJ71SJoJLxxXYl2iSVB3BuGezbJ9-EmJHjr0BveB5Nma0YIu4aUtKg-FNA0JSxu9Pqy3Pj9mPw3UFYWuRzlkxIiYgsSgWmbVWyScjL-zVkui13fO1R7XsI0mGQSHR2f9fFUKRju94v7OW2vNW1l

____________________________________


Diversity and Niche of Archaea in Bioremediation

2018

https://downloads.hindawi.com/journals/archaea/2018/3194108.pdf

____________________________________


Archaea in artificial environments: Their presence in global spacecraft clean rooms and impact on planetary protection

2010 Aug 12

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3105705/

____________________________________

 

Archaea in biogeochemical cycles

2013 Jun 26

https://pubmed.ncbi.nlm.nih.gov/23808334/


____________________________________
 

Bioaugmentation with Mixed Hydrogen-Producing Acetogen Cultures Enhances Methane Production in Molasses Wastewater Treatment

01 August 2018

https://www.hindawi.com/journals/archaea/2018/4634898/

____________________________________


The Role of Methanogens in Waste Water Treatment

As one of the most diverse groups of Archaea known to date, the Methanogens represent the euryarchaeota order which gains energy via methane production. The methanogens utilize the metabolic process of methanogenesis, which is the methane production pathway that converts carbon dioxide and other bacterial waste products into methane. Methanogens have become the focus of recent literature due to their large contribution to global methane emissions as well as their role in wastewater treatment. Methane is a potent greenhouse gas that has a global warming potential of 25 in a 100 year time frame and is estimated to account for 20% of the total radiative forcing from all greenhouse gases (Wang et al., 2011). The recent increase in methane emissions, from natural systems such as wetlands as well as landfills and agricultural cattle, has made understanding methanogens crucial to global climate change. Although methane emissions have negative environmental impacts, the use of methanogens can be use in reducing wastewater and the pollution of water systems across the world. Methanogens help break down organic material that would otherwise pollute water sources and lead to environmental degradation. The construction of wetland systems in developing countries has been adopted as a low cost and highly effective method of reducing nutrient concentrations and degrading organic compounds in agricultural as well as urban wastewaters (Johansson, et al., 2004). The balance of these two impacts is vitally important for the future.

https://microbewiki.kenyon.edu/index.php/The_Role_of_Methanogens_in_Waste_Water_Treatment

 
____________________________________

ANME-1 archaea may drive methane accumulation and removal in estuarine sediments

2021 Jan 18

https://pubmed.ncbi.nlm.nih.gov/33462984/

____________________________________


Energy Metabolism during Anaerobic Methane Oxidation in ANME Archaea

2017 Mar 17

Abstract

Anaerobic methane oxidation in archaea is often presented to operate via a pathway of “reverse methanogenesis”. However, if the cumulative reactions of a methanogen are run in reverse there is no apparent way to conserve energy. Recent findings suggest that chemiosmotic coupling enzymes known from their use in methylotrophic and acetoclastic methanogens—in addition to unique terminal reductases—biochemically facilitate energy conservation during complete CH4 oxidation to CO2. The apparent enzyme modularity of these organisms highlights how microbes can arrange their energy metabolisms to accommodate diverse chemical potentials in various ecological niches, even in the extreme case of utilizing “reverse” thermodynamic potentials.

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5371075/

____________________________________


UASB performance and electron competition between methane-producing archaea and sulfate-reducing bacteria in treating sulfate-rich wastewater containing ethanol and acetate

2013

https://www.sciencedirect.com/science/article/abs/pii/S0960852413005233

____________________________________


Methanogenic archaea: ecologically relevant differences in energy conservation

30 June 2008

https://www.nature.com/articles/nrmicro1931

____________________________________


Halophilic archaea and their potential to generate renewable fuels and chemicals

2020 Dec 16

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7897274/

____________________________________


Methane emission reduction oriented extracellular electron transfer and bioremediation of sediment microbial fuel cell: A review

2023

https://www.sciencedirect.com/science/article/abs/pii/S0048969723011245

____________________________________


Methanotrophs: Methane Mitigation, Denitrification and Bioremediation

16 February 2017

Abstract

Methanotrophs are bacteria capable of using methane as a carbon source. They can lower atmospheric methane emissions, remove N in environmental and wastewater treatment systems and even transform organic pollutants in soils. Methanotrophic methane mitigation technologies have been demonstrated beyond the laboratories as adaptable field-scale systems that may be engineered to meet site-specific climatic variations and ensure minimal atmospheric methane emission. In agricultural sediments and soils, methanotrophs sequester methane but are affected by fertiliser applications, while in wastewater treatment systems they can lower the costs associated with N removal. Finally, the methanotrophs are particularly appealing as bioremediation agents in methane-containing environments, as their primary enzymes have a broad substrate range that can transform various hydrocarbons, including aromatic compounds and halogenated aliphatics. These diverse bacteria are an important global methane sink and this importance is set to increase as anthropogenic emissions increase over the coming decades.

https://link.springer.com/chapter/10.1007/978-3-319-49727-3_2

____________________________________


A microbe that uses crude oil to make methane

22 December 2021

A microorganism that dwells in an underground oil reservoir has been found to degrade various petroleum compounds and use them to produce methane through a previously unreported biochemical pathway.

https://www.nature.com/articles/d41586-021-03729-3

____________________________________


Genome sequencing of rumen bacteria and archaea and its application to methane mitigation strategies

2013

https://pubmed.ncbi.nlm.nih.gov/23739466/

____________________________________


Functions of bacteria and archaea participating in the bioconversion of organic waste for methane production

2020

https://www.sciencedirect.com/science/article/abs/pii/S0048969720365372

____________________________________


Diversity and Evolution of Methane-Related Pathways in Archaea

June 27, 2022

https://www.annualreviews.org/content/journals/10.1146/annurev-micro-041020-024935

____________________________________


Wide diversity of methane and short-chain alkane metabolisms in uncultured archaea

04 March 2019

https://www.nature.com/articles/s41564-019-0363-3

____________________________________


A mixed consortium of methanotrophic archaea and bacteria boosts methane-dependent selenate reduction

2020

https://www.sciencedirect.com/science/article/abs/pii/S0048969720328278

____________________________________


Role and regulation of anaerobic methane oxidation catalyzed by NC10 bacteria and ANME-2d archaea in various ecosystems

2022

https://www.sciencedirect.com/science/article/abs/pii/S0013935122025014

____________________________________


Diverse methylotrophic methanogenic archaea cause high methane emissions from seagrass meadows

February 14, 2022

https://www.pnas.org/doi/10.1073/pnas.2106628119

____________________________________


Biochar decreases methanogenic archaea abundance and methane emissions in a flooded paddy soil

2020

https://www.sciencedirect.com/science/article/abs/pii/S0048969720354875

____________________________________


Coal methanogenesis: a review of the need of complex microbial consortia and culture conditions for the effective bioconversion of coal into methane

10 February 2017

https://annalsmicrobiology.biomedcentral.com/articles/10.1007/s13213-017-1255-5

____________________________________


Methanogenic Archaea Can Produce Methane in Deliquescence-Driven Mars Analog Environments

08 January 2020

https://www.nature.com/articles/s41598-019-56267-4

____________________________________


Anaerobic Oxidation of Methane Coupled with Dissimilatory Nitrate Reduction to Ammonium Fuels Anaerobic Ammonium Oxidation

November 13, 2020

https://pubs.acs.org/doi/10.1021/acs.est.0c02664

 
____________________________________

 

Archaea and the nitrogen cycle

08 August 2017

https://microbiologysociety.org/publication/past-issues/archaea/article/archaea-and-the-nitrogen-cycle.html

____________________________________


Ammonia-oxidizing archaea involved in nitrogen removal

2009

https://www.sciencedirect.com/science/article/abs/pii/S0043135409000499

 
____________________________________

 

Study Forecasts Tile Drainage and Crop Rotation Changes for Nitrogen Loss

    University of Illinois Urbana-Champaign

    02 March 2023

https://www.enn.com/articles/72081-study-forecasts-tile-drainage-and-crop-rotation-changes-for-nitrogen-loss

 

____________________________________


Ammonia-oxidizing archaea are integral to nitrogen cycling in a highly fertile agricultural soil

01 June 2021

https://www.nature.com/articles/s43705-021-00020-4

 

____________________________________

 


Non-negligible roles of archaea in coastal carbon biogeochemical cycling

2022

https://www.sciencedirect.com/science/article/abs/pii/S0966842X2200316X

 

____________________________________



Catalytic combo converts CO₂ to solid carbon nanofibers while offsetting emissions

January 11, 2024

Scientists at the U.S. Department of Energy's (DOE) Brookhaven National Laboratory and Columbia University have developed a way to convert carbon dioxide (CO2), a potent greenhouse gas, into carbon nanofibers, materials with a wide range of unique properties and many potential long-term uses. Their strategy uses tandem electrochemical and thermochemical reactions run at relatively low temperatures and ambient pressure.

As the scientists describe in the journal Nature Catalysis, this approach could successfully lock carbon away in a useful solid form to offset or even achieve negative carbon emissions.

"You can put the carbon nanofibers into cement to strengthen the cement," said Jingguang Chen, a professor of chemical engineering at Columbia with a joint appointment at Brookhaven Lab who led the research. "That would lock the carbon away in concrete for at least 50 years, potentially longer. By then, the world should be shifted to primarily renewable energy sources that don't emit carbon."

As a bonus, the process also produces hydrogen gas (H2), a promising alternative fuel that, when used, creates zero emissions.

https://techxplore.com/news/2024-01-catalytic-combo-solid-carbon-nanofibers.html

____________________________________


Florida researchers are studying 'plant diamond' for carbon capture secrets

December 14, 2023

https://phys.org/news/2023-12-florida-diamond-carbon-capture-secrets.html

____________________________________


Curved carbon nanotubes enhance electrocatalysts for carbon neutrality

February 7, 2024

https://phys.org/news/2024-02-carbon-nanotubes-electrocatalysts-neutrality.html


____________________________________


Finding new chemistry to capture double the carbon

April 8, 2024

https://phys.org/news/2024-04-chemistry-capture-carbon.html

____________________________________

 

Nuclear Fusion Breakthrough; Powering Electric Vehicles; Carbon Capture | 60 Minutes Full Episodes

Jul 22, 2023

Scott Pelley's January report on the breakthrough in nuclear fusion made by scientists at the National Ignition Facility; From May, Bill Whitaker's story on how companies are developing lithium extraction for electric car batteries in California’s Imperial Valley. And from April, Whitaker's visit to Iceland, where carbon dioxide is captured from the air and buried underground as part of groundbreaking new technology to slow climate change.

https://www.youtube.com/watch?v=7ZejZxjvFng

 
____________________________________

 

Research lights up process for turning CO₂ into sustainable fuel

March 25, 2024

Researchers have successfully transformed CO2 into methanol by shining sunlight on single atoms of copper deposited on a light-activated material, a discovery that paves the way for creating new green fuels.

https://techxplore.com/news/2024-03-co8322-sustainable-fuel.html#google_vignette

 

____________________________________

 

Copper-based catalysts efficiently turn carbon dioxide into methane

September 25, 2023

https://phys.org/news/2023-09-copper-based-catalysts-efficiently-carbon-dioxide.html

 

____________________________________

 


Why Solid Carbon is the Future of Energy Storage

Feb 22, 2024

Energy storage is a huge sector, and growing at a rapid pace - largely due to the mass rollout of renewable energy. Lithium-ion batteries have a part to play in all of this, but they come with their own set of problems, including cost and the use of rare earth materials. This is why I am so interested in thermal batteries - using heat to store energy instead of chemical bonds. Antora energy have an incredible new way of doing this with solid carbon blocks and thermo-photovoltaic panels. So, I got in contact with them!

https://www.youtube.com/watch?v=cwDly9pjSJg

____________________________________


Enhancing the CO2 capturing ability in leaf via xenobiotic auxin uptake

2020

https://www.sciencedirect.com/science/article/abs/pii/S0048969720345617

____________________________________


Researchers develop minimal nanozymes with carbon dioxide capture capacity

September 26, 2023

https://phys.org/news/2023-09-minimal-nanozymes-carbon-dioxide-capture.html

____________________________________



A catalyst for converting carbon dioxide, the main cause of global warming, into ethylene using vitamin C

March 29, 2024

https://phys.org/news/2024-03-catalyst-carbon-dioxide-main-global.html#google_vignette



____________________________________

 

Research highlights a dangerous overreliance on future CO₂ removal

February 1st, 2024

https://phys.org/news/2024-02-highlights-dangerous-overreliance-future.html

 

____________________________________
 

Improved remediation of co‑contaminated soils by heavy metals and PAHs with biosurfactant‑enhanced soil washing

2022

https://www.nature.com/articles/s41598-022-07577-7.pdf

____________________________________


Remediation techniques for elimination of heavy metal pollutants from soil: A review

2022

https://www.sciencedirect.com/science/article/abs/pii/S0013935122012452

____________________________________


A review of green remediation strategies for heavy metal contaminated soil

25 November 2020

Abstract

Heavy metals and metalloids can accumulate in soil, with potentially toxic effects to
human health and ecosystems, threatening the sustainable use and management of soil
resources. Although a number of remediation technologies, such as Solidification/
Stabilization (S/S), soil washing, electrokinetic remediation and chemical oxidation/
reduction can be applied for the immobilization, removal or detoxification of heavy
metals in soil, the environmental, social and economic impacts associated with these
conventional approaches hinder their overall sustainability. More attempts have been
made to maximize the ‘net environmental benefit’ in various ways, including recov-
ering resources, embracing nature-based solutions (NBS), and saving energy with
the emergence and development of the ‘green and sustainable remediation’ (GSR)
movement. This review critically discusses these green remediation strategies, and
the novel soil amendments being utilized in these sustainable approaches. Iron-
based amendments are the most promising candidates in green remediation due to
the highest stabilization performances for both oxyanions and metallic cations as
well as relatively low disturbance to soil. In comparison, waste-derived materials
suffer from risks of contaminant release in the long run, reducing the overall sustain-
ability despite their low costs. It has been found that phytoremediation and green
amendment- based S/S are typically the ‘greenest’ remediation strategies, but wise
decisions should be made on the basis of case-specific sustainability assessment re-
sults. Finally, it is proposed that integration of several green remediation techniques
may have a synergistic effect on remediation efficiency.

https://bsssjournals.onlinelibrary.wiley.com/doi/pdf/10.1111/sum.12717

 

____________________________________


Heavy Metals in Contaminated Soils: A Review of Sources, Chemistry, Risks and Best Available Strategies for Remediation

2011

https://www.hindawi.com/journals/isrn/2011/402647/

____________________________________


Remediation of metal contaminated soil with mineral-amended composts

2007

https://www.sciencedirect.com/science/article/abs/pii/S0269749107000772

____________________________________

Organic Acids for the In Situ Remediation of Soils Polluted by Heavy Metals: Soil Flushing in Columns

April 2001

 

Abstract

 

To compare the soil remediation effectiveness of saltsof weak organic acids with strongchelating agents, three soils of different textures,all polluted by heavy metals, were washed in a column,at optimum pH, with salts of weak organic acids,namely, citrate, tartarate or oxalate + citrate orchelating agents (EDTA or DTPA). For the clay loam,Cr, Mn, Hg and Pb were removed by citrate andtartarate at levels of 43 to 45, 37 to 41, 91 to 92and 75%, respectively. EDTA and DTPA effectivelyleached only Pb after 20 pore volumes. For the loam,citrate leached 98 and 89% of Cd and Pb after 20 porevolumes, respectively, while tartarate leached out 91and 87% of Cd and Pb. EDTA and DTPA removed 93 to97% of these metals after 20 pore volumes. For thesandy clay loam, 84 to 91, 73 to 84, 56 to 70 and 72to 81% of Cd, Cu, Pb and Zn were removedrespectively, by citrate and tartarate. EDTA and DTPAremoved 93 to 97% of these metals after 20 porevolumes. An in situ soil remediation simulation wasalso tested using the sandy clay loam in a tub. After 12 hr of retention, the citrate solution washed 81, 82,73 and 90%, of Cd, Cu, Pb and Zn, respectively, aftersix pore volumes. EDTA and DTPA effectively removedall heavy metals, except for Hg, but also extractedlarge quantities of soil nutrients and pollute thesoil by being adsorbed on the soil particles. Thesalts of citrate and tartarate effectively removed theheavy metals from the three polluted soils whileleaching little macro-nutrients and improving soilstructure. Each soil reached C and B levels ofsoil-clean-up criteria after 10 to 20 pore volumes andwithin 10 to 15 hr of flushing.

https://link.springer.com/article/10.1023/A:1005251915165

____________________________________


Remediation of Heavy Metal-Contaminated Soils with Soil Washing: A Review

2022

https://www.mdpi.com/2071-1050/14/20/13058

____________________________________



A critical review on soil washing during soil remediation for heavy metals and organic pollutants

03 February 2021

Abbreviations

2,4-D:

2,4-Dichlorophenoxyacetic acid

ADBAC:

Alkyl dimethyl benzyl ammonium chloride

As:

Arsenic

Brij-35:

Poly(oxyethylene)₂₃ dodecyl ether

Cd:

Cadmium

CETSA:

Carboxyalkylthiosuccinic acid

CMC:

Critical micelle concentration

CMCD:

Carboxymethyl-β-cyclodextrin

Co:

Cobalt

COCs:

Chlorinated organic compounds

CPC:

Cetylpyridinium chloride

Cr:

Chromium

Cs:

Cesium

CTAB:

Cetyltrimethylammonium bromide

Cu:

Copper

EDDS:

[S,S]-ethylenediaminedisuccinic acid

EDTA:

Ethylenediaminetetraacetic acid

EDTMP:

Ethylenediamine tetra (methylene phosphonic acid)

GCA:

Glucomonocarbonic acid

GLDA:

N,N-Bis(carboxymethyl)-l-glutamic acid

HAs:

Humic acids

Hg:

Mercury

HIDs:

3-Hydroxy-2,2′-iminodisuccinic acid

HOCs:

Hydrophobic organic contaminants

LMMOAs:

Low molecular mass organic acids

ISA:

Iminodisuccinic acid

MA/AA:

Copolymer of maleic and acylic acid

NAPLs:

Nonaqueous phase liquids

Ni:

Nickel

NTA:

Nitilotriacetic acid

OCPs:

Organochlorine pesticides

PAA:

Polyacrylic acid

PAHs:

Polycyclic aromatic hydrocarbons

PASP:

Polyaspartic acid

Pb:

Lead

PCBs:

Polychlorinated biphenyls

POPs:

Persistent organic pollutants

SDBS:

Sodium dodecyl benzene sulfonate

SDS:

Sodium dodecyl sulfate

TPHs:

Total petroleum hydrocarbons

Tween-80:

Polyoxyethylene sorbitan monooleate

TX-100:

Triton X-100

V:

Vanadium

VFAs:

Volatile fatty acids

Zn:

Zinc

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https://link.springer.com/article/10.1007/s13762-021-03144-1

 

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Soil remediation time to achieve clean-up goals II: Influence of natural organic matter and water contents

2006 Jan 9

 

Abstract

 

This work reports a relatively rapid procedure for the forecasting of the remediation time (RT) of sandy soils contaminated with cyclohexane using vapour extraction. The RT estimated through the mathematical fitting of experimental results was compared with that of real soils. The main objectives were: (i) to predict the RT of soils with natural organic matter (NOM) and water contents different from those used in experiments; and (ii) to analyse the time and efficiency of remediation, and the distribution of contaminants into the soil matrix after the remediation process, according to the soil contents of: (ii1) NOM; and (ii2) water. For sandy soils with negligible clay contents, artificially contaminated with cyclohexane before vapour extraction, it was concluded that: (i) if the NOM and water contents belonged to the range of the prepared soils, the RT of real soils could be predicted with relative differences not higher than 12%; (ii1) the increase of NOM content from 0% to 7.5% increased the RT (1.8-13 h) and decreased the remediation efficiency (RE) (99-90%) and (ii2) the increase of soil water content from 0% to 6% increased the RT (1.8-4.9 h) and decreased the RE (99-97%). NOM increases the monolayer capacity leading to a higher sorption into the solid phase. Increasing of soil water content reduces the mass transfer coefficient between phases. Concluding, NOM and water contents influence negatively the remediation process, turning it less efficient and more time consuming, and consequently more expensive. 

https://pubmed.ncbi.nlm.nih.gov/16406487/

 

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Combined technologies for the remediation of soils contaminated by organic pollutants. A review

11 February 2022

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https://link.springer.com/article/10.1007/s10311-022-01407-y

 

 
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Soil Reclamation and Remediation of Disturbed Lands

https://geo.libretexts.org/Bookshelves/Soil_Science/Digging_into_Canadian_Soils%3A_An_Introduction_to_Soil_Science/03%3A_Digging_Deeper/3.03%3A_Soil_Reclamation_and_Remediation_of_Disturbed_Lands


Remediation Strategies

Remediation strategies for contaminated soil can be broadly classified as biological, chemical, or physical (Table 16.2). Many are a combination of more than one type, and can be applied either ex situ or in situ. Ex situ methods involve excavating the soil from the impacted zone and treating the soil either on or off site. In situ methods treat the contaminated soil in place. Contaminated sites often have contaminated surface and ground waters that may require different or complementary remediation strategies.

Table 16.2. Common remediation strategies for contaminated soils

Type     Category     Common contaminants     Location

Biological     Bioremediation, land farming, engineered biopiles or windrows     Petroleum hydrocarbons 

        Bioventing     Petroleum hydrocarbons     In situ

      Phytoremediation (rhizodegradation, phytoextraction, phytodegradation, phytostabilization, phytoextraction)     Petroleum hydrocarbons, other organic contaminants, metals     Generally in situ
      Slurry phase reactors or lagoons     Various organics     Ex situ
                   
Chemical     Chemical oxidation / reduction     Organics, inorganics     Either
      Neutralization     Acids, bases     Either
                   
Physical     Soil vapour extraction (SVE)     Volatile organics (gasoline)     In situ
      Soil flushing, soil washing, dual phase extraction in ground water     Organics, inorganics     Either
      Solidification, stabilization     Organics, inorganics     Either
      Electrokinetic separation     Organics, inorganics     Either
      Thermal desorption     Organics     Either
      Incineration     Organics     Ex situ
      Vitrification     Organics, inorganics     Either

Bioremediation is a biological treatment that uses soil microorganisms to treat contaminants. It can use natural biodegradation processes, or enhance them by adding commercial or other microbial preparations (bioaugmentation), or adding nutrients such as nitrogen or phosphorus and/or electron acceptors such as oxygen (biostimulation). Bioremediation strategies focus on microbial degradation of organic contaminants, although microbial induced chemical changes of inorganic chemicals can be considered bioremediation, such as converting more toxic chromium to the less toxic chromium.

Bioremediation can be applied in various technologies, such as landfarms, biopiles, or engineered reactors. Bioventing is an in situ treatment that enhances microbial degradation of contaminants through enhanced aeration in the contaminated zone. Use of plants to remove (phytoextraction), stabilize (phytostabilization), or destroy (phytodegradation) contaminants is a biological treatment called phytoremediation. Rhizosphere bacteria can play an important role in biodegradation of organic contaminants during phytoremediation (rhizodegradation).

Chemical treatments can be used to convert contaminants to non-hazardous or less toxic chemicals, or to forms which are less mobile, more stable, or inert. Chemical oxidation using hydrogen peroxide, ozone, or permanganate can destroy compounds such PAHs, and is best for liquids such as ground water or soil slurries. Chemical reduction can convert toxic chromium to less toxic chromium and degrade some chlorinated organic solvents such as trichlorothene. Neutralization involves adding materials to adjust the pH of highly acidic or caustic soil.

Physical treatments use properties of the contaminant or contaminated medium to separate or immobilize the contaminant. Chemical additives can improve removal efficiencies. In situ, soil vapour extraction creates a vacuum in the vadose zone, draws vapours into an extraction well, then treats or destroys them above ground. Soil flushing occurs in situ, where the contaminated zone is treated with a solution, and mobilized contaminants are brought to the surface for disposal, treatment, or re-circulation. Treatment solutions can be water, basic, acidic, chelating or complexing, reducing, co-solvents, or surfactants. Dual phase extraction involves installation of piping to ground water and vacuum extraction of water and organic contaminants such as petroleum hydrocarbons. Soil washing is done ex situ and may involve separating soil fines (silt, clay) from coarse material thereby reducing the total mass and volume that needs to be treated.

Solidification and stabilization prevent or slow release of contaminants from soil by treatment with binding agents such as cement or asphalt. The soil may be treated with a material that will reduce contaminant solubility and mobility. For example, phosphate based materials often reduce mobility of lead, by converting lead into insoluble lead phosphate compounds. Hydrogen sulphide can convert many metals into insoluble respective pyrites.

Electrokinetic separation sends a low intensity direct current through the soil to separate metals, radionuclides, and organic contaminants. Positively charged species migrate to the cathode, and negatively charged species, such as inorganic and organic anions, migrate to the anode.

Thermal treatments are mainly used to remediate organic contaminants. Thermal desorption is typically ex situ, with heat applied to soil to evaporate or vapourize contaminants which are collected, treated, or destroyed. Temperatures of 90 to 320°C are required to treat volatile organic contaminants such as fuel components, 320 to 540°C to treat semi-volatile organics such as PAHs, PCBs, and lubricants. Incineration involves heating soil ex situ to 870 to 1370°C to destroy organic contaminants. Vitrification heats soil to 1400 to 2000°C to melt silica and convert it to stable glass and crystalline solids. Heat may be generated by electrodes and electrical resistance or plasma arc technology. Organic contaminants are volatilized, trapped, and treated or destroyed and inorganic contaminants, including radionuclides, are encased.


____________________________________


Soil Cleanup Criteria

https://dep.nj.gov/srp/guidance/scc/

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How Heat Can Enhance In-Situ Soil and Aquifer Remediation

1997

https://www.epa.gov/remedytech/how-heat-can-enhance-situ-soil-and-aquifer-remediation

____________________________________


Bioaugmentation as a strategy for cleaning up of soils contaminated with aromatic compounds

2009

Summary

The contamination of soil with aromatic compounds is of particular environmental concern as they exhibit carcinogenic and mutagenic properties. One of the methods of their removal from soil is bioaugmentation, defined as a technique for improvement of the degradative capacity of contaminated areas by introduction of specific competent strains or consortia of microorganisms. The efficiency of bioaugmentation is determined by many abiotic and biotic factors discussed in this paper. The first include chemical structure, concentration and availability of pollutants as well as physico-chemical properties of soil. In turn, among biotic factors the most important is the selection of proper microorganisms that can not only degrade contaminants but can also successfully compete with indigenous microflora.

Several strategies are being developed to make augmentation a successful technology particularly in soils without degrading indigenous microorganisms. These approaches involve the use of genetically engineered microorganisms and gene bioaugmentation. The enhancement of bioaugmentation may be also achieved by delivering suitable microorganisms immobilized on various carriers or use of activated soil.

Introduction

Industrial production of chemicals as well as their inappropriate use, improper disposal and accidental leakage has resulted in contamination of many areas. Among man-made substances that cause ecotoxicological problems are a variety of aromatic compounds such as halogenated aromatic compounds, polycyclic aromatic hydrocarbons (PAHs) and BTEX compounds (benzene, ethylbenzene, toluene and three isomers of xylene). The main sources of these toxic substances are oil refineries, gas stations, use of wood preservatives and agrochemicals, petrochemical and pharmaceutical industries. The presence of these chemicals in the environment poses serious risks to human health due to their toxicity, mutagenic and carcinogenetic properties and ability to accumulate through the food chain. Most aromatic compounds are recalcitrant, persistent and remain in the environment for long periods of time (Budavari 1996).

There are many methods for the removal of these pollutants from soils. They involve both physico-chemical and biological approaches. Although the first ones are more effective than biological methods they are expensive and require high energy demand and consumption of many chemical reagents. This is a reason why use of microorganisms capable of degrading toxic compounds known as bioremediation has become an attractive technology (Hamdi et al. 2007). One of the in situ bioremediation strategies is bioaugmentation, which improves the biodegradative capacities of contaminated sites by introduction of single strains or consortia of microorganisms with desired catalytic capabilities. Moreover, genetically engineered microorganisms (GEMs) exhibiting enhanced degradative capabilities encompassing a wide range of aromatic hydrocarbons have also potential for soil bioaugmentation. Its place among bioremediation categories is depicted in Figure 1.


Table 3. Carriers used for delivering of microorganisms to soil for bioaugmentation purposes.
Carriers    Microorganisms    Pollutants degraded    References
κ-Carrageenan    Pseudomonas sp. UG30    Pentachlorophenol    Cassidy et al. (1997)
κ-Carrageenan/gelatin gel    Microbial consortium    2,4,6-Trichlorophenol    Gardin and Pauss (2001)
Polyvinyl alcohol    Hydrocarbon-degrading bacteria    Diesel oil    Cunningham et al. (2004)
Polyurethane foam    Rhodococcus sp. F92    Various petroleum products    Quek et al. (2006)
Chitin, chitosan    Hydrocarbon-degrading strain    Crude oil    Gentili et al. (2006)
Chitosan    Pseudomonas putida BCRc14349    Phenol, trichloroethane    Chen et al. (2007)
Alginate, agar, polyacrylamide    Pseudomonas fluorescens-CS2    Ethylbenzene    Parameswarappa et al. (2008)
Zeolite, activated carbon    Hydrocarbon-degrading microbial consortium    Crude oil    Liang et al. (2009)

https://www.sciencedirect.com/science/article/pii/S0944501309000585

 

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A new approach to cleaning heavy metals out of soil

June 4, 2019

https://engineering.stanford.edu/magazine/article/new-approach-cleaning-heavy-metals-out-soil

When poisonous heavy metals like lead and cadmium escape from factories or mines, they can pollute the nearby soil.

With no easy ways to remove these contaminants, fields must be cordoned off to prevent these toxins from entering the food chain where they threaten human and animal health.

According to the Environmental Protection Agency, heavy metals have been found at thousands of locations nationwide. While some have been cleaned up through a combination of federal, state and private efforts, the need remains for new technologies to address heavy metal contamination

Now a research team led by Stanford materials scientist Yi Cui

 has invented a way to wash heavy metals from contaminated soils using a chemical process that’s a bit like brewing coffee.

As they describe

in Nature Communications, the researchers started by rinsing contaminated soil with a mixture of water and a chemical that attracts heavy metals. When that mixture percolates through the soil, the chemical pulls heavy metals loose. The team members then collected this toxic brew and ran it through an electrochemical filter that captured the heavy metals out of the water. In this way they cleansed the soil of heavy metals and recycled the water and chemical mixture to percolate through more contaminated ground.

“This is a new approach to soil cleanup,” said Cui, who is a professor of materials science and engineering and photon science. “Our next step is a pilot test to make sure that what works in the lab is practical in the field, and to figure out how much this process will cost.”

So far, his team has cleansed soils contaminated with lead and cadmium, two prevalent and dangerous toxins, as well as with copper, which is only dangerous in high concentrations. Cui believes this process of chemical cleansing and electrochemical filtering will work with other dangerous heavy metals like mercury and chromium, but further lab experiments are needed to demonstrate that.

____________________________________

 


Remediation Technologies for Cleaning Up Contaminated Sites

 
2021

https://19january2021snapshot.epa.gov/remedytech/remediation-technologies-cleaning-contaminated-sites_.html


____________________________________


Use of surfactants for the remediation of contaminated soils: A review

2014

https://www.sciencedirect.com/science/article/abs/pii/S0304389414009911

____________________________________



Remediation of hexavalent chromium contaminated soil by biochar-supported zero-valent iron nanoparticles

2016

 

Abstract

 

In this study, a kind of high-efficiency and low-cost biochar-supported zero-valent iron nanoparticles (nZVI@BC) was synthesised and used in the remediation of Cr(VI)-contaminated soil. The remediation tests indicated that the immobilisation efficiency of Cr(VI) and Cr_total was 100% and 91.94%, respectively, by 8 g nZVI@BC per kg soil for 15 d of remediation. Further investigations showed that exchangeable Cr was almost completely converted to Fe-Mn oxides and organic matter. Moreover, nZVI@BC could effectively improve soil fertility and reduce the leachability of Fe caused by nZVI. At the same time, the cabbage mustard growth experiments indicated that the phytotoxicity of Cr(VI) and Fe in the seedlings was effectively decreased by nZVI@BC treatment, and that the cabbage mustard growth was enhanced.

https://www.sciencedirect.com/science/article/abs/pii/S0304389416306719

 

____________________________________


Review of Remediation Technologies for Cadmium in soil

2021

https://www.researchgate.net/publication/348810635_Review_of_Remediation_Technologies_for_Cadmium_in_soil


____________________________________


Remediation Technology for Copper Contaminated Soil: A Review

2018

https://www.researchgate.net/publication/337610519_Remediation_Technology_for_Copper_Contaminated_Soil_A_Review


____________________________________

 


A review on remediation technologies for nickel-contaminated soil

2019

https://www.researchgate.net/publication/330504565_A_review_on_remediation_technologies_for_nickel-contaminated_soil

 

____________________________________

 


Remediation of cadmium-contaminated soil: GLDA-assisted extraction and sequential FeCl3–CaO-based post-stabilization

2023

 

Abstract

 

Cadmium (Cd) contamination of farmland soils is a growing concern because of its highly toxic impact on ecosystems and human health. Chelator-assisted washing and chemical immobilization are effective remediation strategies for Cd-contaminated soils. Ethylenediaminetetraacetic acid (EDTA) has traditionally been used for soil washing, but its persistence in the environment and subsequent toxicity have raised significant ecological concerns. Consequently, biodegradable chelators have gained increasing attention as eco-friendly alternatives to the persistent chelator, EDTA. Therefore, this study evaluated the performance and efficacy of three biodegradable chelators: L-glutamate-N,N′-diacetic acid (GLDA), methylglycine-diacetic acid (MGDA), and 3-hydroxy-2,2′-iminodisuccinic acid (HIDS) in comparison to EDTA for remediating a real Cd-contaminated agricultural soil. The influence of treatment parameters, including chelator variants, washing time, chelator concentration, solution pH, and liquid-to-soil ratio (L/S) on Cd extraction was studied and optimized to attain the maximum removal rate. Following chelator-assisted washing, the efficacy of a stabilization preference combining FeCl₃ and CaO in reducing the leaching potential of residual Cd in chelator-washed soil residues was also investigated. GLDA demonstrated comparable Cd extraction efficiency to EDTA, and the Cd extraction efficiency was found to be positively correlated with the soil washing parameters. However, under the optimized conditions (chelator concentration: 10 mmol L⁻¹; washing time: 3 h; solution pH: 3; L/S ratio: 10:1), GLDA exhibited a higher Cd extraction rate than EDTA or the other chelators. Furthermore, a post-treatment process incorporating FeCl₃ and CaO substantially diminished the water-leachable Cd content in the resultant soil residues. The proposed remediation strategy, which combines chemically assisted washing and stabilization, could be a practical option for extracting bulk Cd from soil and reducing the leaching potential of residual Cd.

https://www.sciencedirect.com/science/article/pii/S0045653523028242

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Remediation of Lead Contaminated Soils by Stabilization/Solidification

January 2002

https://link.springer.com/article/10.1023/A:1012977829536

 

____________________________________

 


Remediation of lead-contaminated soil by washing with choline chloride-based deep eutectic solvents

2022

Introduction

Lead-contaminated soil has attracted much attention as a typical heavy metal contaminated soil (Landrot and Khaokaew, 2018, Sun et al., 2019). And the formation of lead-contaminated soil was mainly attributed from natural (Zhang et al., 2020, Zhang et al., 2020) and human activities (Wu et al., 2016, Yoo et al., 2016). Lead compounds will exist in the soil for a long time, and cause serious harm to human health (Wei and Yang, 2010). Lead poisoning in particular affects the normal development of children (Mathee et al., 2018). Therefore, the research on the lead-contaminated soil remediation methods is of great significance to human and environment (Huang et al., 2021).

 

The main remediation methods for heavy mental-contaminated soil mainly include engineering methods (Li et al., 2020), physical and chemical methods (Zeng et al., 2020, Zhao et al., 2020), and biological methods (Gidudu and Chirwa, 2020). Engineering methods mainly refer to the application of machinery to cover up or transfer contaminated soil to achieve the purposes of soil remediation. Engineering measures mainly include soil dumping, soil replacement, top soil removal, additional soil and deep ploughing, which are characterized by being relatively simple and stable, and especially widely used in the soil remediation. However, the use of engineering measures can result in the physicochemical changes in the soil (Zhang et al., 2020, Zhang et al., 2020). The physi-chemical remediation methods refer to the soil remediation by combining physics and chemistry (Zhao et al., 2021). And the physi-chemical remediation technologies mainly include electrokinetic remediation (Nasiri et al., 2020, Xu et al., 2020), solidification/stabilization (Han et al., 2020), soil improvement (Lu et al., 2020), and washing technologies (Park et al., 2021, Peng et al., 2021, Zhu et al., 2015). Although these technologies are simple and effective, they tend to be costly and can result in secondary pollution (Bolan et al., 2014). Chemical washing is also used for remediate contaminated soil with heavy metals. The inorganic acid (Luo et al., 2018, Xing et al., 2021) chelating agents, surfactants (Mao et al., 2015), organic acid (Cheng et al., 2020) and inorganic salts were used as chemical agents. And they were usually applied to remediate contaminated soil by heavy metals (Dermont et al., 2008, Hu et al., 2021). However, there is still a need to determine an effective and environmentally friendly chemical reagents for soil remediation (Ke et al., 2020, Li et al., 2021, Wan et al., 2021). Citric acid, oxalic acid and tartaric acid were usually combined with EDTA (Gluhar et al., 2020), ethylenediamine tetra (methylene phosphonic acid) and polyacrylic acid (Feng et al., 2020) used to extract heavy metals from the contaminated soil.

 

Deep eutectic solvents (DESs) are a novel liquid similar with ionic liquid synthesized by two or more compounds with different melting points (Almeida et al., 2020, Hayyan et al., 2010). Usually it can be synthesized by mixing hydrogen bond donor (HBA) with hydrogen bond acceptor (HBD) (Bi et al., 2020, Hayyan et al., 2013a). The functional DESs obtained through the mixing natural plant derivatives (citric acid, glucose and fructose) with choline chloride has been investigated previously (Hayyan et al., 2012, Hayyan et al., 2013b). And DESs are also considered to be a novel and green solvents due to their excellent properties negligible volatility, non-flammability, nontoxicity, biodegradability, and thermal stability (Tome et al., 2018, Warminska et al., 2021). Hydrogen bonding is a key process for the formation of DESs and allows the creation of supramolecular structures between components identified from nuclear magnetic resonance (NMR) analysis. DESs have been widely used in electrochemistry (Li et al., 2016), sewage treatment (Soylak and Koksal, 2019), dissolving metal salts (Habibi et al., 2013), and separating harmful metals from various substances (Altunay et al., 2020, Bakkar, 2014, Mukhopadhyay et al., 2016a), due to its low toxicity, biodegradability, simple preparation and low price (Abbott et al., 2007). Recent studies have found that DESs had achieved good results in remediating soil contaminated by heavy metals (Habibollahi et al., 2019, Matong et al., 2017, Mukhopadhyay et al., 2016a). DESs are easily degraded by environmental factors when they are in the natural environment (Tang et al., 2021, Warminska et al., 2021). However, DESs are with high viscosity, which results in that it is very difficult to be recycled after remediation. In our previous research, choline chloride with ethylene glycol and water to synthesize diluted DESs and combining with EDTA-2Na can remove more than 95% of lead from lead-contaminated soil (Huang et al., 2021). However, DESs are seldom directly used for the decontamination of polluted soil.

 

The present research synthesized DESs through the mixing of HBDs such as ethylene glycol, urea, propylene glycol, glycerin, and malonic acid with the HBA choline chloride. These DESs were used in the present research for the lead-contaminated soil remediation. The optimal HBD was determined by comparing Pb extraction rate among the different DESs used. In addition, the effects of influence factors such as temperature, liquid-solid (L/S) ratio, water-DESs volume ratio, stirring speed, and choline chloride-malonic acid (Ch-M) molar ratio on Pb extraction were investigated and response surface analysis was also conducted. Moreover, the analysis of the DESs and soil were conducted before and after remediation to characterize the reaction mechanism. Finally, in order to illustrate the practical feasibility of the proposed remediation technique, the cost and application in real contaminated soil had been analyzed.

Section snippets

Sample preparation and regents

Soil samples were taken from the top soil of cultivated in Shanghai, China (31°12′N, 121°39′E). The soil samples were naturally dried and passed through a 0.18 mm sieve before being stored. Determination of lead content of soil samples was 22.87 mg·kg⁻¹ (CHN, Ministry of Ecology and Environment, 2017). Then, 23.98 g Pb(NO₃)₂ was dissolved in water and mixed with 1 kg soil samples to prepare lead-contaminated soil. After 60 days of solidification, the Pb concentration in the simulated

DESs screening

 

Th Ch-M and soil reaction system was the lowest pH values among all the evaluated DESs of 1.32 (Table S2). In Fig. 2, the five DESs (Ch-U, Ch-E, Ch-P, Ch-M, and Ch-G) were diluted with water and the solutions were used as washing agents for screening. Besides for Ch-M, the other DESs have little effect on the removal of Pb from the contaminated soil. This result can be attributed to the fact that the extraction of Pb from soil is strongly dependent on the pH (Table S2) of a solution 

 

Conclusions

 

The current research has confirmed that diluted DESs (Ch-M) can be used for lead-contaminated soil remediation. The viscosity and cost of Ch-M could be reduced though diluted with water, and FT-IR analysis confirmed the effectiveness of the method. According to the FT-IR and HRMS analysis indicated that the carboxyl groups and hydrogen bonds in Ch-M chelate, resulting in the dissolving of Pb(NO₃)₂ and the formation of [Pb‧Chcl‧COOH], [Ch‧Pb], and other complex ions. Extraction temperature, L/S

https://www.sciencedirect.com/science/article/abs/pii/S0957582022000441

 

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Remediation of mercury contaminated soil, water, and air: A review of emerging materials and innovative technologies

2019

Abstract

Mercury contamination in soil, water and air is associated with potential toxicity to humans and ecosystems. Industrial activities such as coal combustion have led to increased mercury (Hg) concentrations in different environmental media. This review critically evaluates recent developments in technological approaches for the remediation of Hg contaminated soil, water and air, with a focus on emerging materials and innovative technologies. Extensive research on various nanomaterials, such as carbon nanotubes (CNTs), nanosheets and magnetic nanocomposites, for mercury removal are investigated. This paper also examines other emerging materials and their characteristics, including graphene, biochar, metal organic frameworks (MOFs), covalent organic frameworks (COFs), layered double hydroxides (LDHs) as well as other materials such as clay minerals and manganese oxides. Based on approaches including adsorption/desorption, oxidation/reduction and stabilization/containment, the performances of innovative technologies with the aid of these materials were examined. In addition, technologies involving organisms, such as phytoremediation, algae-based mercury removal, microbial reduction and constructed wetlands, were also reviewed, and the role of organisms, especially microorganisms, in these techniques are illustrated.

https://www.sciencedirect.com/science/article/pii/S0160412019324754

 

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Versatile Process for the Preparation of Nanocomposite Sorbents: Phosphorus and Arsenic Removal

June 2020

https://www.researchgate.net/publication/342187173_Versatile_Process_for_the_Preparation_of_Nanocomposite_Sorbents_Phosphorus_and_Arsenic_Removal

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Advanced techniques to remove phosphates and nitrates from waters: a review

13 April 2021

Abstract

At high levels, phosphates and nitrates from mineral fertilizers and wastewaters are contaminating natural waters, leading, for example, to eutrophication and death of many living species. This requires remediation techniques such as physical, chemical, biological methods, and nano-techniques. For instance, microbes such as Bacillus subtilis, Pseudomonas, Achromobacter, Spirulina platensis and Chlorella vulgaris allow denitrification and can remove 55% of phosphates. Removal can be done also using adsorbents produced from wastes and bio-sorbents. Here we compare the methods to remove phosphates and nitrates in waters.

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https://link.springer.com/article/10.1007/s10311-021-01239-2

 

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Asymmetrical alternating current electrochemically-mediated washing method for sustainable remediation of Cr(VI)-contaminated soil

2022 May 6

 Abstract

The demands for genuine remediation of heavy metal contaminated soil have triggered extensive studies in the soil washing method. However, numerous soil washing methods show poor sustainability for target soil, due to the tremendous cost, hidden secondary pollution and severe soil deterioration. Here, an asymmetrical alternating current electrochemically-mediated remediation platform (ACRP) is developed by fabricating an amidoxime-functionalized electrode (Ami-electrode). The real soil contaminated with 1200 mg/kg Cr(VI) is remediated efficiently to less than safety level (30 mg/kg), meanwhile no exorbitant soil nutrient loss is observed and no secondary pollution occurs. Furthermore, the consumption of washing effluents for the ACRP method is 24 times lower than the traditional washing method. Ami-electrode with asymmetrical alternating current promote the electrocatalytic efficiency by inhibiting the Coulomb repulsion between Cr(VI) species and cathode. With the aid of Ami-electrode and positive bias, Cr(VI) species in effluents are adsorbed on chelating site. By subsequent negative bias, Cr element is reduced and recycled in the less hazardous form of amorphous Cr(III) hydroxide, and effluents are regenerate concurrently in a cyclic system. Durability experiment and cost calculation verify the exceptional sustainability and feasibility for remediation practices. This work provides a sustainable remediation method for Cr(VI)-contaminated soil, and then paves the way to develop electrochemically soil remediation platform for practical applications.

https://pubmed.ncbi.nlm.nih.gov/35716559/

 

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Remediation of heavy metal contaminated soil by asymmetrical alternating current electrochemistry

04 June 2019

https://www.nature.com/articles/s41467-019-10472-x

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Remediation of soils contaminated by hydrophobic organic compounds: How to recover extracting agents from soil washing solutions?

2020

https://www.sciencedirect.com/science/article/abs/pii/S0304389420321270

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Soil washing for the remediation of dioxin-contaminated soil: A review

2021 Jul 30

https://pubmed.ncbi.nlm.nih.gov/34396961/

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Application of biochar-based materials for remediation of arsenic contaminated soil and water: Preparation, modification, and mechanisms

2022

https://www.sciencedirect.com/science/article/abs/pii/S2213343722011654

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Arsenic immobilization through regulated ferrolysis in paddy field amendment with bismuth impregnated biochar

2018

https://www.sciencedirect.com/science/article/abs/pii/S0048969718331589

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Synthesis and characterization of a novel magnetic calcium-rich nanocomposite and its remediation behaviour for As(III) and Pb(II) co-contamination in aqueous systems

2019

https://www.sciencedirect.com/science/article/abs/pii/S0048969719351149

 

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Removal of heavy metal ions from wastewater: a comprehensive and critical review

08 July 2021

Magnetic adsorbents

Magnetic adsorbents are a specific material matrix that hosts iron particles (usually magnetic nanoparticles, such as Fe₃O₄). The base material could be carbon, CS, polymers, starch, or biomass. As illustrated in Fig. 2, the adsorption process is affected by the magnetic field, surface charge, and redox activity characteristics. They showed low-cost, easy-synthesis, extraordinary surface charge, and reusability. Many magnetic adsorbents were proposed in the literature, such as zero-valent iron nanoparticles (ZVI NPs), iron oxides (hematite (α-Fe₂O₃), maghemite (γ-Fe₂O₃), magnetite (Fe₃O₄)), and spinel ferrites. The mechanism and kinetics of the sorption process rely on several parameters, such as surface morphology and adsorbent magnetic behavior. They are also affected by experimental conditions such as pH, irradiation time, adsorbent concentration, wastewater temperature, and the initial dosage of pollutants. The presence of iron particles in adsorbent is very efficient in metal ions removal from effluent.

Some studies have focused on coating Fe₃O₄ particles for removing heavy metal ions. Co-precipitation, high-gravity technology, and grafting are the most commonly used methods. The grafting method was considered a preferable choice because it is flexible and straightforward. However, it strongly depends on the active hydroxyl on the surface of Fe₃O₄ particles and the number of active functional groups. The produced adsorbents were not adequately cyclic stable, which is a barrier facing the commercialization of this method. Additional details about different magnetic adsorbents can be found in Supplementary Table 5.

Biosorbents

The most recent research studies in using biosorption for wastewater treatment are listed in Supplementary Table 6. The presence of numerous functional groups (i.e., carboxyl, amino, hydroxyl, phosphate, thiol, etc.) on the surface expedite the biosorption process. Generally, the interaction between pollutants and the surface of biosorbent can occur through electrostatic interaction, aggregation, complexation/coordination, microprecipitation, ion exchange, reduction, or oxidation. The solution pH affects the biosorbent surface charge density and ionization of functional groups located on the biosorbent surface. When pH is low, cations are almost stable and can be bonded to the biosorbent surface. On the other hand, at higher pH values, the solubility of metal cations decreases with the possibility of a precipitation phenomenon.

 

The biosorbent amount is a vital factor affecting the removal efficiency due to offering more vacant biosorption sites. The biosorbent capacity could increase at higher temperatures due to decreased solution viscosity, reduction in Gibb’s free energy, and bond rupturing. These reasons increase the collision frequency (mobility and kinetic energy) between biosorbent and metal ions and enhance the biosorbent active sites, leading to a higher affinity. In turn, the bonding force between biosorbent and pollutants could decline at higher temperatures, and thus the biosorbent sorption uptake reduces. It was elucidated that the removal efficiency increases as the mixing agitation rate increases.

Metal-organic frameworks adsorbents

Metal-organic frameworks (MOFs) are generally synthesized via reticular synthesis in which metal ions are strongly bonded to organic linkers. Researchers proposed thousands of MOFs. It was noticed that most of the organic ligands used to form many MOFs are very expensive and toxic. Zirconium-MOFs family (such as UiO-66) is promising nanostructure materials for sorption applications due to the easy incorporation of functional groups and hydrolytic-thermal stability such as amine, carboxylic, hydroxyl, and oxygen or by using the cross-linking method. Composite-based MOF adsorbents could obtain further enhancement in the adsorption capacity of MOFs. Supplementary Table 7 lists the uptake of different MOFs towards several heavy metal ions in wastewater.

Despite the exciting features of MOFs and their good capability to remove heavy metal ions, they have micropores (i.e., tiny pores) inaccessible for some target metals. Also, most of them have low stability in water. Mn, Fe, and Cu have been used to form MOFs, but most of them resulted in poor chemical stability. Therefore, further research is still needed to tune the MOFs’ structure and scale up these materials to implement them into industrial wastewater applications. Moreover, different functionalization methods should be proposed and applied to enhance MOFs’ stability and sorption kinetics.

Membrane-based filtration and separation

Over the years, technological advancement in membrane development has led to an increase in the use of membranes for filtration and extraction of heavy metal ions from wastewater. A simplified schematics for different membrane-based filtration processes is illustrated in Fig. 3a–c, while Fig. 3d demonstrates various pollutants that can be separated by different membrane techniques.


Ultrafiltration

Ultrafiltration (UF) is used at low transmembrane operating pressure (TMP). Because UF membrane pores may be larger than the heavy metal ions, additives may be bonded to metal ions to enlarge the size of the metal ions. Therefore, micellar enhanced ultrafiltration (MEUF) and polymer enhanced ultrafiltration (PEUF) are proposed.

MEUF is formed by bonding UF and surfactant. MEUF has high flux and high selectivity, leading to low-energy consumption, high removal efficiency, and less space demand. MEUF is most suitable for wastewater whose heavy metals are in low concentrations. In MEUF, a surfactant is mixed with wastewater in a concentration above the critical micellar concentration (CMC). Beyond CMC, surfactant monomers assemble and increase the creation of some micelles in the solution. The surfactant contains a hydrophobic tail and a hydrophilic head. The inner hydrophobic core of the micelles could solubilize organic matters (having low molecular weight) as a solubilizate, while the surface adsorbs counter metal ions on their surface due to electrostatic interactions. Surfactants, whose electric charge is the opposite of the metal ions, usually attain the highest retentions. In this regard, polyelectrolytes (PE), cationic surfactants, and anionic surfactants (e.g., sodium dodecyl sulfate (SDS)) are used for effective heavy metals extraction.

A summary of different studies on the MEUF process is given in Supplementary Table 8. The performance of MEUF depends on several factors, including the added solutes, type of surfactant, operating conditions, and kind of membrane used.

PEUF is formed through the integration of UF and binding polymers. The functional groups of the bonding polymers could be sulfonate, phosphonic, carboxylated, or amine, and they are bonded via chelating or ionic bonds58. PEUF are also known as polymer-supported, complexation, polymer-assisted, size enhanced, and complexation enhanced ultra-filtrations. While permitting water and un-complexed components to permeate the membrane pores, the PEUF process blocks and extracts polymer-bonded metal ions.

A summary of studies conducted on PEUF is presented in Supplementary Table 9. PEUF shows effective polymer bonding, effective extraction, ability to recover and reuse complexation polymer of retentate, low-energy demands, and low-cost operation. However, the choice of appropriate water-soluble polymer macro-ligands remains the main challenge of developing this technology.

Nanofiltration


Nanofiltration (NF) is used to concentrate constituents whose molecular weight is >1000 Da and remove solutes whose size of 0.0005–0.007 μm with molecular weights >200 Da. Thus, the operating range of NF is between UF and reverse osmosis (RO) processes. The NF membranes are composed of polymer composites of multiple-layer thin-film of negatively charged chemical groups. Anti-fouling NF membranes containing CeO₂/Ce₇O₁₂ and PES were synthesized through phase inversion and used to extract Fe³⁺, Al³⁺, Co²⁺, Cd²⁺, Cu²⁺, and humic acid from wastewater and reached extraction efficiency between 94 and 98%. Other studies are presented in Supplementary Table 10.

 

Microfiltration

 

Microfiltration (MF) employs a microporous membrane to remove micron-sized particles, bacteria, viruses, protozoa, contaminants, pollutants, etc., from a solvent/fluid/solution60. MF process is also a low pressure-driven membrane process, whose membrane pores are in the range of 0.1–10 μm60. Some of the MF membranes are made of silica, ceramics, zirconia, alumina, PVC, polysulfone, PTFE, polypropylene, PVDF, polyamides, polycarbonate, cellulose acetate, cellulose esters, or composite materials. The commercial application of MF is widely found in pharmaceutical and biological industries. However, the application of the MF system may be found in particle removal of the rinse water in the semiconductor industry, sterilization of beer and wine, other juices and cider clarification, and wastewater treatment60. The application of MF in heavy metal removal has not drawn enough attention because of its low removal ability. However, it has been used by modifying membrane or chemical pre-treatment of the feed solution. Depending on the mode of application, the MF process is available in two main configurations: crossflow and dead-end. Some studies on MF are summarized in Supplementary Table 11.

Reverse osmosis

RO is a pressure-driven separation process that employs a semi-permeable membrane (pore size 0.5–1.5 nm) to allow only smaller molecules to pass. RO process reverses the normal osmosis process by applying pressure (20–70 bar) >the osmotic pressure of the feed solution. The molecular size of the solutes blocked is usually in the range of 0.00025–0.003 μm60. RO process could extract 95–99% of inorganic salts and charged organics60. RO process is compact and attained high rejection efficiency. However, membrane fouling and degrading are the major drawback of RO systems60. The RO separation process was used to extract heavy metal ions, including Ni2+, Cr6+, and Cu2+ from electroplating wastewater, with a removal efficiency of >98.7562. Recently, RO has been used to purify industrial wastewaters from coster-field mining operations located in Victoria-Australia with mean extraction efficiency of 10%, 48%, 82%, 66%, and 95% for Fe3+, Zn2+, Ni2+, As3+, and Sb3+ respectively63. Other studies on RO heavy metals removal are summarized in Supplementary Table 12.

Forward osmosis

Forward osmosis (FO) is an osmosis process that requires a membrane to balance selectivity and permeated water flux51. In FO, a semi-permeable membrane separates a feed solution from the draw solution, as shown in Fig. 3b. The draw solution is usually at a higher osmotic pressure compared to the feed solution. Due to the osmotic pressure difference between the feed and draw solutions, water transports from the feed solution to the draw solution, thereby keeping the rejected solutes on the feed side and treated water on the draw solution64. FO does not require hydraulic pressure; thus, it is energy-saving. FO process is also environmentally friendly, easy cleaning, and low fouling; therefore, it is widely used in wastewater treatment64. Nevertheless, FO has limitations, such as draw solution re-concentration, membrane selection challenges, internal and external concentration polarization65. Supplementary Table 13 summarizes the use of FO, including thin-film membranes.

Electrodialysis

Electrodialysis (ED) is used to separates ions at the expense of electric potential difference. ED uses a series of cation exchange membranes (CEM) and anion exchange membranes (AEM), alternatively arranged in parallel, to separate ionic solutes51. In the ED process, the anions pass through AEM, while cations pass through CEM. In such a case, the treated stream (diluate) is produced from half of the ED stack channels, while the concentrated stream is expelled from the other half, as shown in Fig. 3c. ED offers high water recovery, no phase change, no reaction, or chemical involvement66, and can operate over a wide range of pH values. However, ED also exhibits membrane fouling, high cost of membranes, and demand for electric potential.

ED has been used to separate Ni²⁺, Pb^2+, and K⁺ from synthetic solution through a novel ED heterogeneous CEM (consisting of 2-acrylamido-2-methyl propane sulfonic acid-based hydrogel and PVC) to attain extraction efficiency of 96.9%, 99.9%, and 99.9% for Ni²⁺, Pb^2+, and K⁺, respectively. A batch ED process was employed to recover Pb²⁺ and reached a maximum separation efficiency of ~100%. A pilot-scale ED system has also been used to extract Cu²⁺, Ni²⁺, and traces of Cd²⁺, Fe³⁺, Cr^6+, and Zn²⁺, and exceeded 90% removal rate. As³⁺ and As⁵⁺ were removed from metallurgical effluent by ED and attained a removal efficiency of 91.38%.

Other membrane-based methods


Chemical-based separation

Chemical methods for removing heavy metals from wastewater are mature and used early. In this section, the chemical-based methods will be discussed, including precipitation, coagulation-flocculation, and flotation.

Membrane distillation (MD) and liquid membrane (LM) are also used for wastewater treatment. MD is a hybrid thermally driven membrane separation process that consists of cold and hot compartments separated by a microporous hydrophobic membrane. MD allows only vapor to permeate its pores while blocking other molecules. MD exists in four configurations: direct contact MD, air gap MD, sweeping gas MD, and vacuum MD. MD process has been reported to achieve over 96% removal of Ca²⁺, Mg²⁺, Fe³⁺, and Fe²⁺, and more than 99% for As³⁺ and As⁵⁺.

 

On the other side, LM is made of a liquid phase or thin-layer organic phase, which acts as a barrier between two aqueous phases. LM is immiscible to the feed solution and retentate solution, and combined stripping and extraction processes in a single stage. LM is highly selective, relatively efficient, and can achieve specific molecular recognition. However, the membrane’s long-term stability is poor. LM process exists as a supported liquid membrane (SLM), emulsion liquid membrane (ELM), bulk liquid membrane (BLM), and polymer inclusion membrane (PIM). Among these types, the SLM process is an attractive alternative to traditional solvent extraction for heavy metal removal. SLM achieved a removal efficiency of 89% for Zn²⁺, Cd²⁺, Cu²⁺, and Fe³⁺.

 

Precipitation

Chemical precipitation (the so-called coagulation precipitation) is broadly used in industries and is considered one of the most effective and mature methods. It changes the form of dissolved metal ions into solid particles to facilitate their sedimentation. The reagent coagulation (coagulant) precipitates metal ions by changing pH, electro-oxidizing potential, or co-precipitation76. It is usually followed by the removal of sediments. A simple schematic of the chemical precipitation process is depicted in Fig. 4.

Hydroxide precipitation is broadly used due to its relatively inexpensive, simple, and tunable pH77. It is implemented by adding a hydroxide to the stirred wastewater to form insoluble metal hydroxide precipitates. For example, a metal ion could react with calcium hydroxide (lime) to produce metal hydroxide precipitates and calcium ions as:


It was found that pH values of 9–11 improved this process efficiency. However, a high pH value is considered a disadvantage of this method since it requires a large dosage of precipitates. One of the most effective hydroxide precipitates for treating inorganic effluents of heavy metal concentration of 1000 mg/L is lime (CaO or Ca(OH)₂). A summary of some hydroxide precipitation studies is presented in Supplementary Table 14. It can be seen that the majority of metals removed by this method are Zn²⁺, Cu²⁺, Ni²⁺, Pb²⁺, and Cr³⁺. In addition to the need for the high dosage to get optimal pH, there are some drawbacks, such as relatively large volumes of sludge leading to dewatering, disposal issues, amphoteric, and the inhabitation of metal hydroxide precipitation with the presence of complexing agents.

The sulfide participation method distinguishes itself by higher removal efficiency and lesser dissolved solids increment than the hydroxide method. This method was reported to treat toxic heavy metal ions80. Lower sulfide results in a higher zinc concentration in the effluent, while higher sulfide leads to a malodor problem due to high residual sulfide. Also, it could produce hydrogen sulfide gas which is malodorous and toxic. For these reasons, the sulfide precipitation is recommended to be executed at a neutral pH81. The metal sulfide precipitations could follow Eq. (2) reaction,


Supplementary Table 15 summarizes the metal ions removal using sulfite precipitations. The toxicity of sulfide and its high cost are the most shortcomings.

As an alternative method to hydroxide precipitation, carbonate precipitation shows good effectiveness and optimum precipitation at lower pH values82. It could be achieved using sodium carbonate or calcium carbonate. The classical carbonates can be formed based on Eq. (3 and 4):


It could have less sludge volume, but it could release CO2 bubbles and needs higher reagents for efficient precipitation83. Supplementary Table 16 lists some studies concerning carbonate precipitation. It can be seen that copper and manganese are the major metals removed by this technology. Zinc and lead could also be removed efficiently.

Fenton reaction is usually used to improve the removal efficiency of the chemical precipitation methods. The Fenton or Fenton-like oxidation is used for the de-complexation of heavy metal complexes. However, the pH is adjusted by the chemical precipitation mechanism (e.g., NaOH). Fenton chemistry is not straightforward, and it is performed through numerous reactions, depending upon various active intermediates, such as [Fe^IV O]²⁺ and hydroxyl radicals. The classical Fenton reaction is:

Fe³⁺-H₂O₂ (Fenton-like) and Fe⁰-H₂O₂ (advanced Fenton) are also represented as an alternative for Fe²⁺-H₂O₂. Additional detailed examples of using the Fenton-integrated chemical precipitation method are summarized in Supplementary Table 17.

 

Some metals are represented in small volumes in bulk wastewater, such as radionuclides. The removal of radioactive metals is listed in Supplementary Table 18.

 

Coagulation and flocculation

 

Coagulation is the destabilization of colloids by neutralizing the forces that keep them parted, while flocculation is the agglomeration of destabilized particles. Traditional coagulants are aluminum, ferrous sulfate, and ferric chloride, using to neutralization of ion charges. Flocculation bonds the particles forming large agglomerates with the help of a flocculant, such as polyaluminum chloride (PAC), polyferric sulfate (PFS), polyacrylamide (PAM), and other macromolecule flocculants. The PE were reported as one of the most practical flocculations, but the produced sludge might be toxic. The flocculants are generally not natural and non-biodegradable.

 

The process is illustrated in Fig. 5, including the sedimentation. Some weaknesses are toxicity and health hazardousness of inorganic coagulants, a large volume of sludge, selective for some metals and inefficient in emerging contaminants, increasingly effluent color, inefficient when using natural coagulants, and complex of scaling up. Supplementary Table 19 summarizes some of the studies conducted on coagulation-flocculation for heavy metal removal from different wastewater sources. The typical heavy metals removed by this method include Cu²⁺, Pb²⁺, and Ni²⁺. Other metals such as As²⁺, Se²⁺, Cr²⁺, Sb³⁺, Sb⁵⁺, Ag²⁺ could also be efficiently removed.

Flotation

Flotation is used to remove various metal ions. The general schematic of the flotation process is shown in Fig. 6. Dissolved air flotation, ion flotation, and precipitation flotation were extensively studied. In the dissolved air flotation, air (or gas) is fed to wastewater to generate micro-bubbles that could attach the metal ions, developing lower density agglomerates, leading to raising the flocs through the wastewater. The accumulated slug at the top surface can easily be removed.

Electric-based separation

In this section, different electrochemical methods (i.e., electrochemical reduction (ER), EC, electroflotation (EF), and electrooxidation (EO)), and ion exchange method are discussed.

Electrochemical treatment

In an electrochemical system, oxidation is performed at the anode (positive side), where electrons transfer to the cathode (negative side), at which the reduction process occurs. These two chemical reactions are called redox (reduction-oxidation), leading to water purification through metal removal. For example:

Ion exchange treatment

The ion exchange method is a reversible chemical reaction used to replace the undesirable metal ion with harmless and environmentally friendly ones. A heavy metal ion is removed from a wastewater solution by attaching it to an immobile solid particle as a replacement with the solid particle cation, as shown in Fig. 8. The material of solid ion-exchange particles could be either natural, e.g., inorganic zeolites, or synthetically produced, e.g., organic resins. The ion-exchange method can remove target (some or all) heavy metal ions, such as Pb²⁺, Hg²⁺, Cd²⁺, Ni²⁺, V⁴⁺, V⁵⁺, Cr³⁺, Cr⁴⁺, Cu²⁺, and Zn²⁺ from wastewater. The ion exchange mechanism for metal removals can be explained in the following reaction as the ion exchange particle having ion exchanger of M⁻EC⁺ (M⁻ is the fixed anion and EC⁺ is the exchange cation; Na⁺ and H⁺ are frequently used as exchange cations) to exchange its cation (EC⁺) with the wastewater cation (WC⁺).

Photocatalytic-based separation

The photocatalytic process was reported as a simple process for wastewater treatment that uses light and semiconductors, such as titanium dioxide (TiO₂). Three key steps are taken in this process: charged carrier photogeneration, charged carrier separation and diffusion to the photocatalyst surface, and redox reaction on the photocatalyst surface. The effluents of real soil washing wastewater were treated using an outdoor dual solar photocatalytic process of flat plate collector for the removal of 93.5% Cu²⁺, 99.6% Fe³⁺, and 99.4% Zn²⁺. A simulated ultraviolet (UV)–solar TiO₂ photocatalysis has been used for the removal of ethylenediamine-N, N′-disuccinic acid (EDDS), and Cu²⁺ from wastewater (0.2 mM EDDS and 0.2–1.4 mM CuSO₄) to obtain 100% conversion efficiency at 24% mineralization degree. In another study, maximum removal efficiencies of 41% Cu²⁺, 100% Fe³⁺, 100% Zn²⁺ and 100% EDDS were obtained from synthetic soil washing solution (3.6 × 10⁻¹ mM EDDS, 8.0 × 10⁻² mM Cu⁺², 1.0 × 10⁻¹ mM Fe⁺³ and 8.0 × 10⁻² mM Zn⁺²).

 

Using visible light irradiation, a synthesized rhodium/antimony co-doped TiO₂ nano-rod and titanate nanotube (RS-TONR/TNT) was used to extracts Pb²⁺, Cd²⁺, Cu²⁺, Zn²⁺, and organic pollutant from wastewater with 70 and 80% degradation efficiency for dye and Bisphenol A, respectively. The photocatalytic process using CeO₂/BiOIO₃ composites with Ce⁴⁺/Ce³⁺ redox centers was used to attain 86.53% Hg²⁺ removal efficiency under visible light absorption and photocatalytic activity. In an aqueous solution containing As⁵⁺ and Cr⁶⁺ (concentration of 0.10 mg/L), a synthesized 3D-Fe₂O₃ was used to achieve nearly 100% removal rates using solar light irradiation and photocatalytic activity. A fabricated CH-GEL/ZSPNC hybrid nanocomposite ion exchanger achieved 90% Ni²⁺, 94.9% Zn²⁺, 95% Mg²⁺, 100% Pb²⁺, 90.3% Cd²⁺, 88.9% Cu²⁺ and 84% Rhodamine-B (dye) extraction efficiencies using solar light.

 

A fabricated CS/silver bio-nano-composites (CS/PVDC/Ag) was utilized in photocatalytic oxidation process for 97% Cu²⁺, 88% Pb²⁺, 89% Cd²⁺ and 77% dye removal. Although this technology shows the in site generation of reactive radicals, no chemicals used, no sludge production, it has some drawbacks. It is still on a laboratory scale, low throughput, dependent on pH, and inefficient when different metals are present.

https://www.nature.com/articles/s41545-021-00127-0

 
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Remediation of ciprofloxacin in soil using peroxymonosulfate activated by ball-milled seaweed kelp biochar: Performance, mechanism, and phytotoxicity

April 2023


https://www.researchgate.net/publication/369952493_Remediation_of_ciprofloxacin_in_soil_using_peroxymonosulfate_activated_by_ball-milled_seaweed_kelp_biochar_Performance_mechanism_and_phytotoxicity

 
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Soilless remediation of the fine carbonate-rich gold-copper mine tailings

21 August 2023

 

Soil remediation with minimum amendments is a good strategy for tailings disposal. Carbonate-rich gold-copper mine tailings occurring alongside the Yangzi River, China, were employed as the objective in this study. They showed the characteristics of fine particles and alkaline pH with high density and low nutrition. The amendments including bacterial fertilizer (BF), polymer, peat, straw, and compound fertilizer (CF) were used for soilless remediation on the tailings. Soil quality index (SQI) involved in tailing properties and growth characteristics of ryegrass was used to optimize the combination of amendments. The results showed that the optimum amendment combination was 0.2% BF + 0.6% CF + 0.2% polymer + 10% peat and 2% straw. Tailing nutrients such as soil organic matter (5.56%), available nitrogen (93.6 mg kg⁻¹), available phosphorus (51.7 mg kg⁻¹), available potassium (711 mg kg⁻¹), and ryegrass exhibited the highest germination rate and biomass level under the optimal improvement conditions. Additional environmental assessments revealed that soilless treatment of the tailings helped to convert Cu, Zn, and As into residual forms. These findings show a good strategy for tailings soil improvement and provide a promising perspective of the soilless remediation for fine carbonate-rich metal tailings.

https://onlinelibrary.wiley.com/doi/10.1002/clen.202200337

 

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Soil Remediation by Agglomeration with Petroleum Coke

2004

Objective:

Contamination of soils with crude or refined oil products is a problem often associated with production, refining, and distribution of petroleum hydrocarbons. Excavation and incineration of the soil is an effective, but expensive, technology to remediate the contaminated soil.

Bioremediation is useful as a polishing step, but conventional manual and mechanical techniques must be used on heavy concentrations of oil. A hot water wash is practical only for coarse soil contaminated with light oils. This project proposes to use petroleum coke to remediate soil heavily contaminated with crude oil or other high molecular weight hydrocarbons. This project will treat oily soil with finely divided petroleum coke. The bridging liquid (oil) will be supplied by the contaminated soil. The agglomerated fine coke and contaminant oil will be floated and removed leaving an oil-free soil. Our studies to date using fine coal have shown this method capable of treating soils saturated with heavy hydrocarbons (crude oil) with oil recoveries as high as 99.9%.

The coal and oil were recovered as a high grade fuel. The Gulf Coast region, which has a large amount of oil contaminated soil, or has the potential to have large amounts of oil contaminated soil because of oil spills, does not have an abundant quantity of the type of coal best suited to soil remediation. Petroleum coke has this type surface and should be an excellent choice as a remediation agent. Finely divided coal or, as we hope, finely divided coke is a material that "scrubs" the oil from the soil and lends an adsorbent surface for the oil. The benefits of this project will be an economical and practical solution to a type of contamination common to the Gulf Coast with a readily available remediating agent. Because of previous work, The University of Alabama has a fully equipped soil remediation laboratory to carry out this investigation.
 
https://cfpub.epa.gov/ncer_abstracts/INDEX.cfm/fuseaction/display.abstractDetail/abstract_id/1162/report/0

 

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The use of zero-valent iron for groundwater remediation and wastewater treatment: A review

January 2014

https://www.researchgate.net/publication/259882215_The_use_of_zero-valent_iron_for_groundwater_remediation_and_wastewater_treatment_A_review

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Overview of chosen techniques and methods for soils remediation

2015

https://www.researchgate.net/publication/289193260_Overview_of_chosen_techniques_and_methods_for_soils_remediation

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The Use of Soil Amendments for Remediation, Revitalization, and Reuse

https://www.epa.gov/biosolids/use-soil-amendments-remediation-revitalization-and-reuse

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Microbial remediation of aromatics-contaminated soil

06 December 2016

https://link.springer.com/article/10.1007/s11783-017-0894-x

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Cleaning Up of Contaminated Soils by Using Microbial Remediation: A Review and Challenges to the Weaknesses

2019

https://biomedgrid.com/fulltext/volume2/cleaning-up-of-contaminated-soils-by-using-microbial-remediation.000589.php

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Microbial Cleaning for Removal of Surface Contamination

2013 Jun 3

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7151772/

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Soil bacteria can clean your drinking water

08. March 2013

Bacteria that occur naturally in soil can effectively reduce the amounts of the pesticide residue BAM in drinking water.

https://www.sciencenordic.com/biology-chemistry-denmark/soil-bacteria-can-clean-your-drinking-water/1383385

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Bioremediation of oil contaminated soil using agricultural wastes via microbial consortium

08 June 2020

https://www.nature.com/articles/s41598-020-66169-5

 
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Bioremediation of oil spills

https://en.wikipedia.org/wiki/Bioremediation_of_oil_spills

 

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Soil Remediation Through Microbes

03 November 2018

https://link.springer.com/chapter/10.1007/978-981-13-2420-8_6

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Remediation Methods of Crude Oil Contaminated Soil

March 2020

https://www.researchgate.net/publication/340061631_Remediation_Methods_of_Crude_Oil_Contaminated_Soil

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Remediation of soil contaminated with crude oil using supercritical CO2

January 2010

https://www.researchgate.net/publication/288126280_Remediation_of_soil_contaminated_with_crude_oil_using_supercritical_CO2

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Recent advancements in hydrocarbon bioremediation and future challenges: a review

23 May 2022

Abstract

Petrochemicals are important hydrocarbons, which are one of the major concerns when accidently escaped into the environment. On one hand, these cause soil and fresh water pollution on land due to their seepage and leakage from automobile and petrochemical industries. On the other hand, oil spills occur during the transport of crude oil or refined petroleum products in the oceans around the world. These hydrocarbon and petrochemical spills have not only posed a hazard to the environment and marine life, but also linked to numerous ailments like cancers and neural disorders. Therefore, it is very important to remove or degrade these pollutants before their hazardous effects deteriorate the environment. There are varieties of mechanical and chemical methods for removing hydrocarbons from polluted areas, but they are all ineffective and expensive. Bioremediation techniques provide an economical and eco-friendly mechanism for removing petrochemical and hydrocarbon residues from the affected sites. Bioremediation refers to the complete mineralization or transformation of complex organic pollutants into the simplest compounds by biological agents such as bacteria, fungi, etc. Many indigenous microbes present in nature are capable of detoxification of various hydrocarbons and their contaminants. This review presents an updated overview of recent advancements in various technologies used in the degradation and bioremediation of petroleum hydrocarbons, providing useful insights to manage such problems in an eco-friendly manner.

https://link.springer.com/article/10.1007/s13205-022-03199-y

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Researchers clean up petroleum spills with plants

August 2000

https://www.purdue.edu/uns/html4ever/0006.Schwab.phyto.html

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A comprehensive guide of remediation technologies for oil contaminated soil — Present works and future directions

2016

https://www.sciencedirect.com/science/article/abs/pii/S0025326X16302247

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Bioremediation of Total Petroleum Hydrocarbons (TPH) by Bioaugmentation and Biostimulation in Water with Floating Oil Spill Containment Booms as Bioreactor Basin

2021 Feb 24

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7956214/

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Comparative bioremediation of heavy metals and petroleum hydrocarbons co-contaminated soil by natural attenuation, phytoremediation, bioaugmentation and bioaugmentation-assisted phytoremediation

2015

https://www.sciencedirect.com/science/article/abs/pii/S0048969715308779

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The Use of Soil Amendments for Remediation, Revitalization, and Reuse

2007

https://www.epa.gov/remedytech/use-soil-amendments-remediation-revitalization-and-reuse

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Bioremediation: Factors, Types, Advantages, Disadvantages

August 3, 2023

https://microbenotes.com/bioremediation-types-factors/

Table of Contents

    Factors Affecting Bioremediation

        1. Concentration of the contaminant
        2. Nutrient availability
        3. Surfactants; enhancers of bioavailability
        4. Characteristics of the contaminated soil
    Types of Bioremediation
    In Situ Bioremediation
     In Situ Bioremediation Techniques
        Bioaugmentation
        Bio-stimulation
        Bio-slurping
        Bio-sparging
        Bioventing
        Phytoremediation
        Percolation
        Pump and Treat
    Ex-Situ Bioremediation
        Biofiltration
        Biopile
        Bioreactor
        Composting
        Land Farming
    Advantages of Bioremediation
    Disadvantages of Bioremediation
    References

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CONTAMINATED SOIL REMEDIATION BY SELF-CLEANING PROCESSES ACTIVATION

    September 2016

https://www.researchgate.net/publication/360320736_CONTAMINATED_SOIL_REMEDIATION_BY_SELF-CLEANING_PROCESSES_ACTIVATION

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Remediation of contaminated soils using supercritical fluid extraction: a review (1994-2004)

2005

https://pubmed.ncbi.nlm.nih.gov/16196410/

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High-temperature electrothermal remediation of multi-pollutants in soil

11 October 2023

https://www.nature.com/articles/s41467-023-41898-z

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Stanford develops an experimental process to rinse heavy metals from toxic soils

June 4, 2019

Poisonous heavy metals contaminating thousands of sites nationwide threaten to enter the food chain, and there’s been no easy way to remove them. An experimental chemical bath and electrochemical filter could now extract heavy metals from the soil and leave fields safe.

https://news.stanford.edu/2019/06/04/new-process-rinses-heavy-metals-toxic-soils/

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Sustainable soil remediation using mineral and hydrogel: field evidence for metalloid immobilization and soil health improvement

18 May 2023

https://link.springer.com/article/10.1007/s11368-023-03541-8

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Nanotechnology in soil remediation − applications vs. implications

2020

https://www.sciencedirect.com/science/article/abs/pii/S0147651320306540

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Soil Remediation Applications of Nanotechnology

June 2021

https://www.researchgate.net/publication/353142928_Soil_Remediation_Applications_of_Nanotechnology

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Sustainable environmental remediation via biomimetic multifunctional lignocellulosic nano-framework

28 July 2022

https://www.nature.com/articles/s41467-022-31881-5

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Nanobioremediation: A sustainable approach for the removal of toxic pollutants from the environment

2021

https://www.sciencedirect.com/science/article/abs/pii/S0304389421030028

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Role of biotechnology in phytoremediation

2022

https://www.sciencedirect.com/science/article/abs/pii/B9780323898744000212

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How to Neutralize Cat Feces in Soil: All You Need to Know


Natural Solutions to Neutralize Cat Feces in Soil

Here's how you can naturally neutralize cat feces in soil:

    Use earthworm composting bins to break down cat feces and organic matter quickly. The worms do the work and produce nutrient-rich castings.
    Compost the cat feces with other organic matter before applying it to the soil, but avoid fresh animal manure as it can have harmful bacteria and parasites. Use a larger compost bin for better breakdown.
    Balance the high carbon content of cat feces by adding extra nitrogen. This helps with efficient breakdown and prevents odors.
    Keep the compost pile wet to create the right environment for decomposition. Moisture is vital for the breakdown process.
    Let the composting process rest for at least two years before using it to ensure complete breakdown and eliminate potential pathogens.
    Properly composted cat feces can be excellent fertilizer for non-edible plants because of its high levels of nitrogen, phosphorus, and potassium.
    However, don't use cat feces on food plants or crops as it can lead to illness from parasites and pathogenic bacteria.
    To get rid of odor and bacteria in cat feces, mix lime, commercial enzymes, vinegar, or baking soda with water. These methods are effective.
    Make the soil less hospitable to bacteria by adding amendments like lime or sulfur. You can also use baking soda, coffee grounds, leaves, or acid-loving plants to neutralize odor.
    Be cautious when handling lime as it can pose health risks. Additionally, remember that cat feces might contain parasites that could contaminate gardens and cause illness. It takes about a year for cat feces to decompose, so dried feces may still attract bugs and emit unpleasant odors.

Remember to prioritize safety measures and proper composting techniques when dealing with cat feces in soil.

Now that you know how to naturally neutralize cat feces in soil, I want to address another concern: eliminating cat urine odor.

https://icareforcats.com/how-to-neutralize-cat-feces-in-soil/

 

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How to Neutralize Cat Urine in Soil? All You Need to Know

https://icareforcats.com/how-to-neutralize-cat-urine-in-soil/

Here's what you need to do:

    First things first, get rid of any visible cat urine. Grab some gloves or a paper towel and scoop up those urine-soaked areas. Make sure you dispose of it properly to avoid any more contamination.
    Next, flush the soil with water. This will dilute the urea and acid from the cat urine and restore your soil's goodness. Pour plenty of water over the affected spots, making sure it covers everything nicely.
    Give that soil a thorough rinse and let it drain and dry out. The rinsing will help get rid of any leftover residue, while drying it out helps with the smell. Just give it some time to air dry before moving on.
    If the smell is still lingering, you might want to think about repotting your plant or using cat deterrents you can find at the store. Sometimes pee goes deep into the soil, so repotting can refresh things. And those deterrents can keep those pesky cats away from that spot.
    Another trick is to mix vinegar or hydrogen peroxide with water. Spray this solution onto the stinky area and let it sit for a bit, then rinse it off. Both vinegar and hydrogen peroxide work wonders when it comes to neutralizing odors.

And hey, don't forget to clean up your tools properly after you're done.

We don't want any cross-contamination.

By following these steps, you'll say goodbye to that cat urine smell and make your plants happy again.

Main points I'll expand upon further down this article:

    Alkaline substances like baking soda can neutralize and eliminate cat urine odor.
    Baking soda can be mixed with water as a solution or spray.
    Sprinkling baking soda on affected areas and brushing it away is effective.
    Vinegar and hydrogen peroxide can be combined with baking soda for added odor reduction.
    Activated charcoal, enzymes, citrus peels, coffee grounds, and essential oils can also help neutralize odors.
    Cat urine increases soil acidity and urea content, harming plants and nutrient absorption.
    Excessive urine can cause salt build-up, making soil too alkaline for some plants.
    High nitrogen levels in cat urine lead to imbalances in soil nutrients.
    Prevention is key in avoiding soil contamination from repeated urination.
    Adding organic matter and planting deodorizing plants can help balance nutrients and absorb odors.

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Succession of biochar addition for soil amendment and contaminants remediation during co-composting: A state of art review

2023

Abstract

This paper aimed to highlight the succession of biochar addition for soil amendment and contaminants remediation during composting process. Biochar incorporated into the compost mixture promotes composting performance and enhances contaminants reduction. Co-composting with biochar for soil biota has been demonstrated via modified soil biological community abundance and diversity. On the other hand, adverse alterations to soil properties were noted, which had a negative impact on the communication of microbe-to-plant interactions within the rhizosphere. As a result, these changes influenced the competition between soilborne pathogens and beneficial soil microorganisms. Co-composting with biochar promoted the heavy metals (HMs) remediation efficiency in contaminated soils by around 66–95%. Notably, applying biochar during composting could improve nutrient retention and mitigate leaching. The adsorption of nutrients such as nitrogen and phosphorus compounds by biochar can be applied to manage environmental contamination and presents an excellent opportunity to enhance soil quality. Additionally, the various specific functional groups and large specific surface areas of biochar allow for excellent adsorption of persistent pollutants (e.g., pesticides, polychlorinated biphenyls (PCBs)) and emerging organic pollutants, such as microplastic, phthalate acid esters (PAEs) during co-composting. Finally, future perspectives, research gaps, and recommendations for further studies are highlighted, and potential opportunities are discussed.

https://www.sciencedirect.com/science/article/abs/pii/S0301479723009799

 

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How Hemp Can Heal Our Soil & Why It Matters To Consumers

February 24, 2024

Not only can you use hemp to make dozens of sustainable products, from clothing, skateboards to medicine, but it can also help heal the earth.

As the human population grows, so do our need for more land to grow the crops that keep us fed. But our dependence on fossil fuels and dirty industrial processes have left a lot of land too toxic to sustain life. That’s where the rapidly growing field of “bioremediation” can be vital. Bioremediation essentially means using living things to heal the soil, allowing us to clean and reclaim some of these polluted lands. While bacteria and other microorganisms can be used, phytoremediation, from the Greek word for plant, relies on crops like hemp.

Below, we’ll take a look at the reasons why hemp is such a promising plant for bioremediation. At the same time, we’ll also touch on the risks posed by heavy metals and toxins, which can inadvertently end up in hemp-based consumer products.

Hemp Soil Remediation VS The Chernobyl Nuclear Disaster

One of the most dramatic demonstrations of industrial hemp‘s potential was in Chernobyl, in the aftermath of the historic 1986 nuclear disaster which spewed radioactive waste across Eastern Europe. Over 100,000 square kilometers of Russia, Ukraine, and Belarus were inundated with radiation, rendering much of them unusable.

In the late 90s, a company called Phytotech began experimenting with industrial hemp in some polluted Ukrainian regions. The results were extremely promising.

“Phytoremediation can be used to remove radioactive elements from soil and water at former weapons producing facilities,” explained Elaine Charkowski for Central Oregon Green Pages in winter of 1998. “It can also be used to clean up metals, pesticides, solvents, explosives, crude oil, polyaromatic hydrocarbons, and toxins leaching from landfills.”

“Hemp is proving to be one of the best phyto-remediative plants we have been able to find,” Slavik Dushenkov, a research scientist with Phytotech, told Charkowski.

Beyond Radiation: From Cadmium to Oil Spills

In a paper published in September 2012 in Applied Biochemistry and Biotechnology, a team of five researchers in China reported on their successful experiments with hemp to absorb cadmium from the soil. Left untreated, cadmium in soil can enter the food chain, and consumption can cause severe joint and spinal pain. Too much exposure is known to even affect the kidneys and link to cancer.

The scientists experimented with 18 different varieties of hemp that are native to China. They identified 7 varieties which exhibited the highest concentrations of Cadmium (Cd) when grown in polluted soil.

https://ministryofhemp.com/hemp-soil-remediation/

 

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Alfalfa for Use in Phytoremediation of Soil Polluted with Total Petroleum Hydrocarbons

Oct 2018

https://www.researchgate.net/publication/329991317_of_Alfalfa_for_Use_in_Phytoremediation_of_Soil_Polluted_with_Total_Petroleum_Hydrocarbons

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Potential of alfalfa for use in chemically and biologically assisted phytoremediation of soil co-contaminated with petroleum hydrocarbons and metals

Dec 2014

https://www.researchgate.net/figure/6-Phytoremediation-experiments-with-alfalfa_tbl2_281185067

 
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PCB removal, soil enzyme activities, and microbial community structures during the phytoremediation by alfalfa in field soils

08 March 2011

https://link.springer.com/article/10.1007/s11368-011-0344-5

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Converging alfalfa (Medicago sativa L.) and petroleum hydrocarbon acclimated ACC-deaminase containing bacteria for phytoremediation of petroleum hydrocarbon contaminated soil

2022 Aug 2

https://pubmed.ncbi.nlm.nih.gov/35917513/

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Interaction between Azotobacter nigricans and Alfalfa Root in Systems Contaminated with Kerosene. Proceedings of the Ninth International In Situ and On-Site Bioremediation Symposium. In Situ and On-Site Bioremediation-2007.

May 2007

 

Abstract

 

The interaction at a root-hair level between Medicago sativa (alfalfa) and Azotobacter through the removal of kerosene hydrocarbons process was studied. The method of Farreus was used to grow Medicago sativa (alfalfa) plants in nitrogen-free Jensen’s medium added with kerosene (1% v/v), and in the presence of Azotobacter nigricans. Under this condition, the removal of kerosene hydrocarbons was 63.1 %, but plants growth was notably shorter than the controls grown without kerosene. Nevertheless, in both systems, a high population of Azotobacter was located in the tips of the roots hair. In the kerosene feed system, the hydrocarbons were observed as oil microscopic droplets adhered to the surface of the whole radical system; that is, in both the hair of the roots and in the principal root tissue. Notably, the major number of Azotobacter cells was concentrated in the droplets located on the surface of the roots hair. These results point out a symbiotic association between Azotobacter and alfalfa at the root-hair level that should be involved in the biochemical process for effective removal of the hydrocarbons.

https://www.researchgate.net/publication/357469178_Interaction_between_Azotobacter_nigricans_and_Alfalfa_Root_in_Systems_Contaminated_with_Kerosene_Proceedings_of_the_Ninth_International_In_Situ_and_On-Site_Bioremediation_Symposium_In_Situ_and_On-Site

 

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Potential bioremediation of lead and phenol by sunflower seed husk and rice straw-based biochar hybridized with bacterial consortium: a kinetic study

11 December 2023

https://www.nature.com/articles/s41598-023-49036-x

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Bioremediation of metribuzin-contaminated soil by corn straw biochar-immobilized Bacillus cereus N1

May 2023

https://www.semanticscholar.org/paper/Bioremediation-of-metribuzin-contaminated-soil-by-Xiao-Zheng/30729c86419fb7b38a458c34d36d41ea92b8b589#cited-papers

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Enrichment of the soil microbial community in the bioremediation of a petroleum-contaminated soil amended with rice straw or sawdust

2019

https://www.sciencedirect.com/science/article/abs/pii/S0045653519303728

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Bioremediation of the tobacco waste-contaminated soil by Pseudomonas sp. HF-1: nicotine degradation and microbial community analysis

29 September 2012

https://link.springer.com/article/10.1007/s00253-012-4433-1

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Effect of plant waste addition as exogenous nutrients on microbial remediation of petroleum-contaminated soil

19 June 2022

https://annalsmicrobiology.biomedcentral.com/articles/10.1186/s13213-022-01679-3

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Effective bioremediation of tobacco wastewater by microalgae at acidic pH for synergistic biomass and lipid accumulation

November 2021

https://www.researchgate.net/publication/356399609_Effective_bioremediation_of_tobacco_wastewater_by_microalgae_at_acidic_pH_for_synergistic_biomass_and_lipid_accumulation

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Microalgal Bioremediation: A Clean and Sustainable Approach for Controlling Environmental Pollution

17 May 2022

Abstract

Environmental pollution is a major global threat today, with widespread consequences. Industrial effluents, flue gases, automobile emissions, solid waste, agricultural runoff, amongst others, have loaded air, water, and soil with a plethora of undesirable substances harmful for humans and their surroundings. Common pollutants, such as exhaust gases, heavy metals, pesticides, pharmaceuticals, and many emerging organic and inorganic chemicals, are causing multitude of chronic illnesses. With growing population and rapid industrialization, it is becoming increasingly important to develop efficient, cheap, sustainable, and scalable processes to mitigate these life-threatening pollutants.

Conventional physiochemical methods used for the treatment of industrial, municipal, and agricultural wastewaters and emissions are effective, but they suffer serious drawbacks, such as sludge generation, membrane fouling, and high energy and reagent requirements. This has attracted the use of biological resources in development of sustainable and eco-friendly remediation processes. Microalgae particularly have emerged as a potential microorganism in bioremediation owing to their ability to adsorb, accumulate, and degrade many common pollutants using different mechanisms. Concomitant sequestration of carbon dioxide, generation of oxygen, and accumulation of lipids and carbohydrates with growth are however the real advantages of using microalgae in bioremediation. Moreover, simple and cheap nutritional and cultivation requirements of microalgae make it most suitable bioresource for mitigating pollution. The development of microalgae-based remediation processes is therefore an ambitious goal in environmental biotechnology. This chapter reviews important concepts, developments, challenges, and future prospects of microalgal bioremediation.

https://link.springer.com/chapter/10.1007/978-981-16-4445-0_13

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Horizontal ‘gene drives’ harness indigenous bacteria for bioremediation

15 September 2020

 

Engineering bacteria to clean-up oil spills is rapidly advancing but faces regulatory hurdles and environmental concerns. Here, we develop a new technology to harness indigenous soil microbial communities for bioremediation by flooding local populations with catabolic genes for petroleum hydrocarbon degradation. Overexpressing three enzymes (almA, xylE, p450cam) in Escherichia coli led to degradation of 60–99% of target hydrocarbon substrates. Mating experiments, fluorescence microscopy and TEM revealed indigenous bacteria could obtain these vectors from E. coli through several mechanisms of horizontal gene transfer (HGT), including conjugation and cytoplasmic exchange through nanotubes. Inoculating petroleum-polluted sediments with E. coli carrying the vector pSF-OXB15-p450camfusion showed that the E. coli cells died after five days but a variety of bacteria received and carried the vector for over 60 days after inoculation. Within 60 days, the total petroleum hydrocarbon content of the polluted soil was reduced by 46%. Pilot experiments show that vectors only persist in indigenous populations when under selection pressure, disappearing when this carbon source is removed. This approach to remediation could prime indigenous bacteria for degrading pollutants while providing minimal ecosystem disturbance.

https://www.nature.com/articles/s41598-020-72138-9

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Transgenic Tobacco for Phytoremediation of Metals and Metalloids

2019

https://www.sciencedirect.com/science/article/abs/pii/B9780128143896000134


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Pocket K No. 25: Biotech Plants for Bioremediation

Conventional Remediation Strategies

Conventional remediation for polluted sites typically involves the physical removal of contaminants, and their disposal in a designated site. Physical remediation strategies therefore do not eliminate the problem, they merely shift it. In addition, physical remediation strategies are also very expensive, disruptive to the environment, may temporarily increase exposure to chemicals, and often leave residual contamination.

Cadmium, Zinc, Lead, and Selenium

Toxic metals affect crop yields, soil biomass, and fertility, and accumulate in the food chain. Metal-tolerant species protect themselves from the toxicity of metal ions by binding metals ions with specific proteins that render them in a safer form. Three classes of proteins are important for metal detoxification in plants: metallothioneins, phytochelatins, and glutathione. The genes coding for these have been successfully used to improve phytoremediators through genetic engineering.

For example, shrub tobacco (Nicotiana glauca) transformed with the phytochelatin TaPCS1 shows very high levels of accumulation of zinc, lead, cadmium, nickel, and boron, and produces high biomass (3). In Arabidopsis, Indian mustard, and tobacco plants, improved metal tolerance was achieved through the over-expression of enzymes that induce the formation of phytochelatins (4, 5, and 6).

Plants naturally tolerant to heavy metals have also been used as a source of genes for phytoremediation. Transgenic Arabidopsis plants expressing a selenocysteine methyltransferase (SMTA) gene from the selenium hyperaccumulator Astralagus bisulcatus contain eight times more selenium in their biomass when grown on selenite compared to non-transgenic controls. Comparison of gene expression profiles between Arabidopsis thaliana and the closely related species A. hallerri, which is tolerant to cadmium and hyperaccumulates zinc, is also helping identify major genes required for metal tolerance.

Explosives

Millions of tons of explosives have been released into the environment, with the resulting pollution of vast expanses of land and water resources. RDX (Research Department Explosive) was the primary explosive used during World War II, and newer derivatives are extensively used to date. Explosives, and their degradation products, are extremely toxic and corrosive.

Tobacco plants engineered with the bacterial gene for a NADPH-dependent nitroreductase tolerate and degrade high levels of TNT (9), and Arabidopsis plants carrying the xplA gene from Rhodococcus bacteria are highly resistant to of RDX.

Landmines

Landmines affect millions of people, both combatants and civilians, in over 80 countries. Sixty to 70 million active landmines exist throughout the world, and these claim the lives and limbs of 50 people every day, and threaten the livelihood of many more by denying them access to humanitarian aid, agricultural land, and water resources. Efforts are underway to develop transgenic plants that can be used to warn civilians of the presence of landmines in a field. Arabidopsis whose roots change color when they come into contact with degradation products of landmines have been developed. Scientists are now working to allow the plant to transmit the signal to their leaves, to effect human-readable changes for a practical explosives detection system.

Mercury

Mercury is a highly toxic element found both naturally and as an introduced contaminant in the environment, and is a very serious global environmental problem. Organic mercury (organomercurials), the most toxic form to living organisms, is produced when bacteria in the water and soil convert elemental mercury into methylmercury. Methylmercury is easily absorbed and accumulates at high levels in the food chain. Mercury poisoning affects the immune system, damages the nervous system, and is harmful to developing fetuses.

Detoxification of organomercurials has been achieved in transgenic plants by transforming Arabidopsis, tobacco, poplar trees, Indian mustard, and eastern cotton wood with two bacterial genes, merA and merB. (5, 6, 7). The combined actions of merA and merB transform methylmercury to the volatile elemental form, which is 100 times less toxic, and is released by the plant to the atmosphere at non-toxic concentrations through transpiration.


Arsenic

Arsenic occurs naturally in rocks and soil, and is released into underground water. Consumption of contaminated drinking water leads to skin disorders, gangrene, and cancer of the kidneys and bladder. In addition, high levels of arsenic in agricultural land degrade soils, reduce crop yields, and introduce the pollutant to the food chain (8). Arsenic contamination threatens up to 40 million people in Bangladesh alone, a problem described by the World Health Organization (WHO) as “the largest poisoning of a population in history”.

Scientists have engineered Arabidopsis plants with arsenic tolerance by introducing two bacterial genes: arsC and y-ECS. arsC converts arsenate, the arsenic form absorbed by plants, to arsenite. Double transgenics are not only highly tolerant of arsenic, they also have improved cadmium tolerance, and a six-fold increase in the level of biomass compared to wild-type controls.

https://www.isaaa.org/resources/publications/pocketk/25/default.asp

 
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How plants can generate electricity to power LED light bulbs

December 12, 2018

https://www.sciencedaily.com/releases/2018/12/181212093308.htm
 

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Natural genetically modified crops: Grasses take evolutionary shortcut by borrowing genes from their neighbors

October 5, 2023

https://phys.org/news/2023-10-natural-genetically-crops-grasses-evolutionary.html

 

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Mindblowing Video of Plants Talking to Each Other In Real Time

Jan 20, 2024

https://www.youtube.com/watch?v=hd-h_y1X4oA

____________________________________


Xenobiotic sensing and signalling in higher plants

2012 Apr 6

https://pubmed.ncbi.nlm.nih.gov/22493519/

 

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Scientists Engineer Gorgeous Glowing Plants That Shine Bright Their Entire Life Cycle

27 April 2020

 

 
https://www.sciencealert.com/gorgeously-glowing-plants-shine-bright-throughout-their-life-cycle

 

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Creating a New Kind of Night Light: Glow-in-the-Dark Trees

2013

A group in California is starting to engineer plants that could one day replace streetlights

https://www.smithsonianmag.com/innovation/creating-a-new-kind-of-night-light-glow-in-the-dark-trees-9600277/

 

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Advances in development of transgenic plants for remediation of xenobiotic pollutants

2007 May 13

https://pubmed.ncbi.nlm.nih.gov/17553651/

 

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Photochemistry and a new catalyst could make fertilizer more sustainable

January 5, 2024

https://phys.org/news/2024-01-photochemistry-catalyst-fertilizer-sustainable.html
 

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Mushroom cultivation for soil amendment and bioremediation

2021

https://www.maxapress.com/article/doi/10.48130/CAS-2021-0011

 
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Application of mushrooms in the degradation of xenobiotic components and the reduction of pesticides

2022

https://www.taylorfrancis.com/chapters/edit/10.1201/9781003152583-19/application-mushrooms-degradation-xenobiotic-components-reduction-pesticides-karishma-joshi-anamika-das-gaurav-joshi-bibekananda-sarkar

 
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Enhanced Fenton Reaction for Xenobiotic Compounds and Lignin Degradation Fueled by Quinone Redox Cycling by Lytic Polysaccharide Monooxygenases

2021

Abstract

The Fenton reaction is considered to be of great significance in the initial attack of lignocellulose in wood-decaying fungi. Quinone redox cycling is the main way to induce the Fenton reaction in fungi. We show that lytic polysaccharide monooxygenases (LPMOs), through LPMO-catalyzed oxidation of hydroquinone, can efficiently cooperate with glucose dehydrogenase (GDH) to achieve quinone redox cycling. The LPMO/GDH system can enhance Fe3+-reducing activity, H2O2 production, and hydroxyl radical generation, resulting in a fueled Fenton reaction. The system-generated hydroxyl radicals exhibited a strong capacity to decolorize different synthetic dyes and degrade lignin. Our results reveal a potentially critical connection between LPMOs and the Fenton reaction, suggesting that LPMOs could be involved in xenobiotic compound and lignin degradation in fungi. This new role of LPMOs may be exploited for application in biorefineries.

https://pubs.acs.org/doi/10.1021/acs.jafc.1c01684

 

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White-Rot Fungi and their Enzymes as a Biotechnological Tool for Xenobiotic Bioremediation

19 October 2016

https://www.intechopen.com/chapters/51924

 

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A Xenobiotic Detoxification Pathway through Transcriptional Regulation in Filamentous Fungi

2018

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6050962/

 

____________________________________

 

Enzymes and operons mediating xenobiotic degradation in bacteria

2008

https://www.tandfonline.com/doi/abs/10.1080/20014091096729

 

____________________________________

 

Microbe and plant assisted-remediation of organic xenobiotics and its enhancement by genetically modified organisms and recombinant technology: A review

2018

https://www.sciencedirect.com/science/article/abs/pii/S004896971830425X

 

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Recent Advanced Technologies for the Characterization of Xenobiotic-Degrading Microorganisms and Microbial Communities

Feb 2021

https://www.researchgate.net/publication/349180024_Recent_Advanced_Technologies_for_the_Characterization_of_Xenobiotic-Degrading_Microorganisms_and_Microbial_Communities

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Resource Recycling, Recovery, and Xenobiotic Remediation from E-wastes Through Biofilm Technology: A Review

07 July 2022

https://link.springer.com/article/10.1007/s12010-022-04055-8


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Degradation of Xenobiotic Pollutants: An Environmentally Sustainable Approach

2022

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9505297/
 

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Incredible Discovery of an Entirely New Organelle That Fixes Nitrogen

Apr 22, 2024

https://www.youtube.com/watch?v=eGkV_k8IcQ0

 
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Ammonia-oxidizing archaea are integral to nitrogen cycling in a highly fertile agricultural soil

01 June 2021

https://www.nature.com/articles/s43705-021-00020-4

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Nitrate-dependent anaerobic methane oxidation (N-DAMO) as a bioremediation strategy for waters affected by agricultural runoff

11 May 2023

https://academic.oup.com/femsle/article/doi/10.1093/femsle/fnad041/7160451?login=false

____________________________________


Nitrification and beyond: metabolic versatility of ammonia oxidising archaea

14 July 2023

https://www.nature.com/articles/s41396-023-01467-0

____________________________________


How archaea toggle the nitrogen-uptake switch to avoid overeating

January 22, 2024

https://phys.org/news/2024-01-archaea-toggle-nitrogen-uptake-overeating.html

 
____________________________________

 

Archaea, tiny helpers of land plants

2020

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7516179/

____________________________________


How leafcutter ants cultivate a fungal garden to degrade plants could provide insights into future biofuels

February 1, 2024

https://phys.org/news/2024-02-leafcutter-ants-cultivate-fungal-garden.html

____________________________________


Non-syntrophic methanogenic hydrocarbon degradation by an archaeal species

22 December 2021

https://www.nature.com/articles/s41586-021-04235-2

____________________________________

 
Archaeas Role in Carbon Cycle

2016

https://www.the-scientist.com/archaeas-role-in-carbon-cycle-33248

____________________________________

 

These climate-friendly microbes recycle carbon without producing methane

May 6, 2021

Scientists found the newly discovered single-celled archaea living in hot spring sediments

https://www.sciencenews.org/article/climate-microbes-recycle-carbon-methane-archaea-microbiology

____________________________________


Autotrophic carbon fixation in archaea

10 May 2010

https://www.nature.com/articles/nrmicro2365

____________________________________


CO2 removal solutions: A buyer’s perspective

February 3, 2023

https://www.mckinsey.com/capabilities/sustainability/our-insights/co2-removal-solutions-a-buyers-perspective

____________________________________


Carbon monoxide-dependent energy metabolism in anaerobic bacteria and archaea

2008

https://www.deepdyve.com/lp/springer-journals/carbon-monoxide-dependent-energy-metabolism-in-anaerobic-bacteria-and-c7nASeiijt

____________________________________


Carbon monoxide-dependent energy metabolism in anaerobic bacteria and archaea.

2008

https://europepmc.org/article/MED/18575848#impact

____________________________________


Predominance of ammonia-oxidizing archaea on granular activated carbon used in a full-scale advanced drinking water treatment plant

2010

https://www.sciencedirect.com/science/article/abs/pii/S0043135410004835

____________________________________


Hydrogenogenic and sulfidogenic growth of Thermococcus archaea on carbon monoxide and formate

31 July 2016

https://link.springer.com/article/10.1134/S0026261716040135

____________________________________


Bioconversion of CO to formate by artificially designed carbon monoxide: formate oxidoreductase in hyperthermophilic archaea

03 June 2022

https://www.nature.com/articles/s42003-022-03513-7

____________________________________


High-Performance Recognition, Cell-Imaging, and Efficient Removal of Carbon Monoxide toward a Palladium-Mediated Fluorescent Sensing Platform

July 18, 2023

https://pubs.acs.org/doi/10.1021/acs.analchem.3c02050

____________________________________


The removal of carbon monoxide by iron oxide nanoparticles

2002

https://www.sciencedirect.com/science/article/abs/pii/S0926337302002977

____________________________________


Removal of Carbon Monoxide from Simulated Flue Gas Using Two New Fenton Systems: Mechanism and Kinetics

2019 Aug 20

https://pubmed.ncbi.nlm.nih.gov/31389232/

____________________________________


Complete removal of carbon monoxide in hydrogen-rich gas stream through methanation over supported metal catalysts

August 2004

https://www.semanticscholar.org/paper/Complete-removal-of-carbon-monoxide-in-gas-stream-Takenaka-Shimizu/b65a5ed98a0c664f19594cbb67566c5d2612f0ef

____________________________________


Energy Conservation and Hydrogenase Function in Methanogenic Archaea, in Particular the Genus Methanosarcina

2019 Sep 18

 

Summary

 

The biological production of methane is vital to the global carbon cycle and accounts for ca. 74% of total methane emissions. The organisms that facilitate this process, methanogenic archaea, belong to a large and phylogenetically diverse group that thrives in a wide range of anaerobic environments. Two main subgroups exist within methanogenic archaea: those with and those without cytochromes. Although a variety of metabolisms exist within this group, the reduction of growth substrates to methane using electrons from molecular hydrogen is, in a phylogenetic sense, the most widespread methanogenic pathway. Methanogens without cytochromes typically generate methane by the reduction of CO₂ with electrons derived from H₂, formate, or secondary alcohols, generating a transmembrane ion gradient for ATP production via an Na⁺-translocating methyltransferase (Mtr). These organisms also conserve energy with a novel flavin-based electron bifurcation mechanism, wherein the endergonic reduction of ferredoxin is facilitated by the exergonic reduction of a disulfide terminal electron acceptor coupled to either H₂ or formate oxidation. Methanogens that utilize cytochromes have a broader substrate range, and can convert acetate and methylated compounds to methane, in addition to the ability to reduce CO₂. Cytochrome-containing methanogens are able to supplement the ion motive force generated by Mtr with an H⁺-translocating electron transport system. In both groups, enzymes known as hydrogenases, which reversibly interconvert protons and electrons to molecular hydrogen, play a central role in the methanogenic process. This review discusses recent insight into methanogen metabolism and energy conservation mechanisms with a particular focus on the genus Methanosarcina.

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6759668/

 

____________________________________


Hydrogenotrophic methanogenesis in archaeal phylum Verstraetearchaeota reveals the shared ancestry of all methanogens

February 27, 2019

https://www.pnas.org/doi/full/10.1073/pnas.1815631116

____________________________________


Methanogenesis

Methanogenesis or biomethanation is the formation of methane coupled to energy conservation by microbes known as methanogens. Organisms capable of producing methane for energy conservation have been identified only from the domain Archaea, a group phylogenetically distinct from both eukaryotes and bacteria, although many live in close association with anaerobic bacteria. The production of methane is an important and widespread form of microbial metabolism. In anoxic environments, it is the final step in the decomposition of biomass. Methanogenesis is responsible for significant amounts of natural gas accumulations, the remainder being thermogenic.

https://en.wikipedia.org/wiki/Methanogenesis

____________________________________


The origin and evolution of methanogenesis and Archaea are intertwined

31 January 2023

 

Abstract

 

Methanogenesis has been widely accepted as an ancient metabolism, but the precise evolutionary trajectory remains hotly debated. Disparate theories exist regarding its emergence time, ancestral form, and relationship with homologous metabolisms. Here, we report the phylogenies of anabolism-involved proteins responsible for cofactor biosynthesis, providing new evidence for the antiquity of methanogenesis. Revisiting the phylogenies of key catabolism-involved proteins further suggests that the last Archaea common ancestor (LACA) was capable of versatile H₂-, CO₂-, and methanol-utilizing methanogenesis. Based on phylogenetic analyses of the methyl/alkyl-S-CoM reductase family, we propose that, in contrast to current paradigms, substrate-specific functions emerged through parallel evolution traced back to a nonspecific ancestor, which likely originated from protein-free reactions as predicted from autocatalytic experiments using cofactor F₄₃₀. After LACA, inheritance/loss/innovation centered around methanogenic lithoautotrophy coincided with ancient lifestyle divergence, which is clearly reflected by genomically predicted physiologies of extant archaea. Thus, methanogenesis is not only a hallmark metabolism of Archaea, but the key to resolve the enigmatic lifestyle that ancestral archaea took and the transition that led to physiologies prominent today.

https://academic.oup.com/pnasnexus/article/2/2/pgad023/7010768?login=false

____________________________________


Methanogenesis from Carbon Monoxide

13 March 2018

https://link.springer.com/referenceworkentry/10.1007/978-3-319-53114-4_4-1

____________________________________


Evidence for nontraditional mcr-containing archaea contributing to biological methanogenesis in geothermal springs

28 Jun 2023

https://www.science.org/doi/10.1126/sciadv.adg6004

____________________________________


Heterologous Production of an Energy-Conserving Carbon Monoxide Dehydrogenase Complex in the Hyperthermophile Pyrococcus furiosus

2016 Jan 29

 

Abstract

 

Carbon monoxide (CO) is an important intermediate in anaerobic carbon fixation pathways in acetogenesis and methanogenesis. In addition, some anaerobes can utilize CO as an energy source. In the hyperthermophilic archaeon Thermococcus onnurineus, which grows optimally at 80°C, CO oxidation and energy conservation is accomplished by a respiratory complex encoded by a 16-gene cluster containing a CO dehydrogenase, a membrane-bound [NiFe]-hydrogenase and a Na⁺/H⁺ antiporter module. This complex oxidizes CO, evolves CO₂ and H₂, and generates a Na⁺ motive force that is used to conserve energy by a Na⁺-dependent ATP synthase. Herein we used a bacterial artificial chromosome to insert the 13.2 kb gene cluster encoding the CO-oxidizing respiratory complex of T. onnurineus into the genome of the heterotrophic archaeon, Pyrococcus furiosus, which grows optimally at 100°C. P. furiosus is normally unable to utilize CO, however, the recombinant strain readily oxidized CO and generated H₂ at 80°C. Moreover, CO also served as an energy source and allowed the P. furiosus strain to grow with a limiting concentration of sugar or with peptides as the carbon source. Moreover, CO oxidation by P. furiosus was also coupled to the re-utilization, presumably for biosynthesis, of acetate generated by fermentation. The functional transfer of CO utilization between Thermococcus and Pyrococcus species demonstrated herein is representative of the horizontal gene transfer of an environmentally relevant metabolic capability. The transfer of CO utilizing, hydrogen-producing genetic modules also has applications for biohydrogen production and a CO-based industrial platform for various thermophilic organisms.

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4731540/

____________________________________


Ammonia-oxidising archaea living at low pH: Insights from comparative genomics

02 November 2017

https://enviromicro-journals.onlinelibrary.wiley.com/doi/full/10.1111/1462-2920.13971

____________________________________


Unifying the global phylogeny and environmental distribution of ammonia-oxidising archaea based on amoA genes

2018

https://pubmed.ncbi.nlm.nih.gov/29666365/

____________________________________


Unexpected Complexity of the Ammonia Monooxygenase in Archaea

April 06, 2022

https://www.biorxiv.org/content/10.1101/2022.04.06.487334v1

____________________________________


An evolving view of methane metabolism in the Archaea

21 January 2019

https://www.nature.com/articles/s41579-018-0136-7

____________________________________


Methanogenic archaea use a bacteria-like methyltransferase system to demethoxylate aromatic compounds

18 June 2021

https://www.nature.com/articles/s41396-021-01025-6

____________________________________


How Methanogenic Archaea Contribute to Climate Change

May 6, 2022

https://asm.org/Articles/2022/May/How-Methanogenic-Archaea-Contribute-to-Climate-Cha

____________________________________


Rapid microbial methanogenesis during CO2 storage in hydrocarbon reservoirs

22 December 2021

https://www.nature.com/articles/s41586-021-04153-3

____________________________________


Horizontal DNA transfer between bacteria in the environment

2003

https://pubmed.ncbi.nlm.nih.gov/14743976/

____________________________________

Scientists use spent brewer's yeast to filter out metal from waste streams

March 2024

https://phys.org/news/2024-03-scientists-spent-brewer-yeast-filter.html

 

____________________________________

 

Yeast uses plastic waste oils to make high-value chemicals

March 20, 2024

https://phys.org/news/2024-03-yeast-plastic-oils-high-chemicals.html

 

____________________________________

Scientists use food industry byproduct to recover gold from electronic waste

February 29, 2024

https://techxplore.com/news/2024-02-scientists-food-industry-byproduct-recover.html#google_vignette

____________________________________

 

Mechanistic insights into the success of xenobiotic degraders resolved from metagenomes of microbial enrichment cultures

2021 Jun 10

https://pubmed.ncbi.nlm.nih.gov/34329005/

 

____________________________________

 

Polymer science team develops additive that can 'upcycle' a wide range of plastics

Feb 2024

https://phys.org/news/2024-02-polymer-science-team-additive-upcycle.html

 

____________________________________

 

Plant-based material can remediate PFAS, new research suggests

2022

Combining plants and fungi, an NIEHS-funded technology presents an environmentally friendly approach to clean up the 'forever chemicals.

https://factor.niehs.nih.gov/2022/9/science-highlights/pfas-remediation

 

____________________________________

 

Is food waste the key to sustainable, plastic-free diapers and sanitary pads?

March 2024

https://phys.org/news/2024-03-food-key-sustainable-plastic-free.html

____________________________________

 

Scientists develop artificial worm gut to break down plastics

February 8, 2024

https://phys.org/news/2024-02-scientists-artificial-worm-gut-plastics.html
 

____________________________________

 

Metagenomic analysis reveals genetic insights on biogeochemical cycling, xenobiotic degradation, and stress resistance in mudflat microbiome

2021

Highlights

    
    Metagenomic profiling of mudflat microbiome was carried out from a coastal wetland.
    

    Bacterial and archaeal communities differed between mudflats and bulk sediments.
    

    pH, AP, TOC, salinity, and vegetation were major drivers of microbiome composition.
    

    Metagenome showed genetic potential for C, N, and S cycling, xenobiotic degradation.
    

    Mudflat metagenome also possessed genes involved in plant growth and development.

https://www.sciencedirect.com/science/article/abs/pii/S0301479721008008

____________________________________

 

New insights into xenobiotic tolerance of Antarctic bacteria: transcriptomic analysis of Pseudomonas sp. TNT3 during 2,4,6-trinitrotoluene biotransformation

10 February 2024

Abstract

The xenobiotic 2,4,6-trinitrotoluene (TNT) is a highly persistent environmental contaminant, whose biotransformation by microorganisms has attracted renewed attention. In previous research, we reported the discovery of Pseudomonas sp. TNT3, the first described Antarctic bacterium with the ability to biotransform TNT. Furthermore, through genomic analysis, we identified distinctive features in this isolate associated with the biotransformation of TNT and other xenobiotics. However, the metabolic pathways and genes active during TNT exposure in this bacterium remained unexplored. In the present transcriptomic study, we used RNA-sequencing to investigate gene expression changes in Pseudomonas sp. TNT3 exposed to 100 mg/L of TNT. The results showed differential expression of 194 genes (54 upregulated and 140 downregulated), mostly encoding hypothetical proteins. The most highly upregulated gene (> 1000-fold) encoded an azoreductase enzyme not previously described. Other significantly upregulated genes were associated with (nitro)aromatics detoxification, oxidative, thiol-specific, and nitrosative stress responses, and (nitro)aromatic xenobiotic tolerance via efflux pumps. Most of the downregulated genes were involved in the electron transport chain, pyrroloquinoline quinone (PQQ)-related alcohol oxidation, and motility. These findings highlight a complex cellular response to TNT exposure, with the azoreductase enzyme likely playing a crucial role in TNT biotransformation. Our study provides new insights into the molecular mechanisms of TNT biotransformation and aids in developing effective TNT bioremediation strategies. To the best of our knowledge, this report is the first transcriptomic response analysis of an Antarctic bacterium during TNT biotransformation.

https://link.springer.com/article/10.1007/s11356-024-32298-x

 

____________________________________

 

Basic knowledge and perspectives of bioelimination of xenobiotic compounds

1996

https://www.sciencedirect.com/science/article/abs/pii/S0168165696016082

 

____________________________________

 

An innovative approach of bioremediation in enzymatic degradation of xenobiotics

2022

https://pubmed.ncbi.nlm.nih.gov/35081881/

 

____________________________________

 

Degradation of Xenobiotic Pollutants: An Environmentally Sustainable Approach

2022

https://www.researchgate.net/publication/363135453_Degradation_of_Xenobiotic_Pollutants_An_Environmentally_Sustainable_Approach
 

____________________________________

Microbial Degradation of Xenobiotic Compounds

08 July 2021

https://link.springer.com/chapter/10.1007/978-981-16-0518-5_7

 

____________________________________

 

Special Issue: Microbial Degradation of Xenobiotics

2020

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7232483/

 

____________________________________


Remediation potential of mushrooms and their spent substrate against environmental contaminants: An overview

2022

https://www.sciencedirect.com/science/article/abs/pii/S1878818122000500

____________________________________


Method development and validation of ten pyrethroid insecticides in edible mushrooms by Modified QuEChERS and gas chromatography-tandem mass spectrometry

2020 Apr 27

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7184573/

____________________________________


Which Mushrooms Work As Pesticides

March 11, 2023

https://mushroomheadquarters.com/which-mushrooms-work-as-pesticides/

____________________________________


Mushroom-based biopesticides could cut environmental damage from synthetic chemicals

September 25, 2018

https://geneticliteracyproject.org/2018/09/25/mushroom-based-biopesticides-could-cut-environmental-damage-from-synthetic-chemicals/

____________________________________


New developments in integrated pest management for mushroom culture, challenges and opportunities in quality mushroom production

    January 2011

https://www.researchgate.net/publication/235763500_New_developments_in_integrated_pest_management_for_mushroom_culture_challenges_and_opportunities_in_quality_mushroom_production

____________________________________


Mushroom Based Pesticides to Revolutionize Farming

https://www.theeducationmagazine.com/mushroom-revolutionize-farming/

____________________________________


Mushrooms (basidiomycetes) as source of mosquito control agents

2023

https://www.sciencedirect.com/science/article/pii/S2773078623000250

____________________________________


Mycoremediation (Bioremediation with Fungi) – Growing Mushrooms to Clean the Earth. A mini-review.

July 7, 2014

https://www.resilience.org/stories/2014-07-07/mycoremediation-bioremediation-with-fungi-growing-mushrooms-to-clean-the-earth-a-mini-review/

____________________________________


Role of arbuscular mycorrhizal symbiosis in remediation of anthropogenic soil pollution

05 May 2021

https://link.springer.com/article/10.1007/s13199-021-00774-4

____________________________________

 

Biological removal of the xenobiotic trichloroethylene (TCE) through cometabolism in nitrifying systems, Bioresource Technology, 101, Issue: 1 430-433

October 2010

https://www.researchgate.net/publication/255990915_Biological_removal_of_the_xenobiotic_trichloroethylene_TCE_through_cometabolism_in_nitrifying_systems_Bioresource_Technology_101_Issue_1_430-433 

____________________________________


Opportunistic Pathogens of Recreational Waters with Emphasis on Antimicrobial Resistance—A Possible Subject of Human Health Concern

2022 Jun 14

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9224392/

 
____________________________________

 

Novel AI-powered method detects antimicrobial resistance within 30 minutes

Nov 22 2023

https://www.news-medical.net/news/20231122/Novel-AI-powered-method-detects-antimicrobial-resistance-within-30-minutes.aspx

 

____________________________________

 

Xenobiotic Effects on Intestinal Stem Cell Proliferation in Adult Honey Bee (Apis mellifera L) Workers

March 7, 2014

https://journals.plos.org/plosone/article?id=10.1371/journal.pone.0091180

 

____________________________________

 


Stomach bug cases increasing in Central Florida as CDC warns of a drug-resistant bacteria

March 2, 2023

https://health.wusf.usf.edu/health-news-florida/2023-03-02/stomach-bug-cases-increasing-in-central-florida-as-cdc-warns-of-a-drug-resistant-bacteria


____________________________________


Antibiotics as Major Disruptors of Gut Microbiota

2020 Nov 24

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7732679/

 
____________________________________

 

A compound from fruit flies could lead to new antibiotics

June 6, 2023

https://today.uic.edu/a-compound-from-fruit-flies-could-lead-to-new-antibiotics/

 

____________________________________


Contamination of Fresh Produce with Antibiotic-Resistant Bacteria and Associated Risks to Human Health: A Scoping Review

2021 Dec 30

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC8744955/


____________________________________


How dirty is your public gym? Study shows there can be harmful bacteria

Jun 12, 2019

https://www.fox4now.com/lifestyle/health/how-dirty-is-your-public-gym-study-shows-there-can-be-harmful-bacteria

____________________________________


Drug-Resistant Bacteria Outbreak In FL Linked To Eyedrops Spreads

Mar 8, 2023

Eye infections in 13 states, including FL, have been linked to artificial tears. One person has died and there are 8 reports of vision loss.

https://patch.com/florida/across-fl/deadly-drug-resistant-bacteria-outbreak-fl-linked-eyedrops-cdc

____________________________________


Florida woodrat nests are laced with antibiotic-producing bacteria

15 SEP 2020

New discovery could one day lead to new antibiotics for humans

https://www.science.org/content/article/florida-woodrat-nests-are-laced-antibiotic-producing-bacteria


____________________________________


Pseudomonas fluorescens

https://en.wikipedia.org/wiki/Pseudomonas_fluorescens

____________________________________


Potentially deadly fungus spreading rapidly in US health care facilities

March 21, 2023

Cases of Candida auris doubled in 2021, according to a new CDC report.

https://abcnews.go.com/Health/potentially-deadly-fungus-spreading-rapidly-us-health-care/story?id=98011655


____________________________________


Florida is swamped by disease outbreaks as quackery replaces science

2024

https://www.theguardian.com/us-news/2024/mar/03/florida-measles-outbreak-preventable


____________________________________


Are Dangerous Microbes Hiding In Your Makeup? New Study Says Yes.

Dec 2, 2019

https://www.forbes.com/sites/victoriaforster/2019/12/02/are-dangerous-microbes-hiding-in-your-makeup-new-study-says-yes/?sh=181426a37323

 
____________________________________

Archaea: current and potential biotechnological applications

2023 May 15

https://pubmed.ncbi.nlm.nih.gov/37196775/

____________________________________


Archaea in Wastewater Treatment: Current Research and Emerging Technology

2018

https://www.hindawi.com/journals/archaea/2018/6973294/


____________________________________


The more important role of archaea than bacteria in nitrification of wastewater treatment plants in cold season despite their numerical relationships

https://www.sciencedirect.com/science/article/abs/pii/S0043135418306961

 
____________________________________

 

Phytoremediation of Xenobiotics: Principles and Applications in Environmental Pollution Removal

2023

https://link.springer.com/chapter/10.1007/978-3-031-35775-6_13

 
____________________________________

Unveiling bacterial consortium for xenobiotic biodegradation from Pichavaram mangrove forest soil: a metagenomic approach

2023

https://link.springer.com/article/10.1007/s00203-023-03765-9

 
____________________________________

Xenobiotic pollution affects transcription of antibiotic resistance and virulence factors in aquatic microcosms

2022

https://pubmed.ncbi.nlm.nih.gov/35525510/

 
____________________________________

Recent advances in microbial engineering approaches for wastewater treatment: a review

2023 Jul 27

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10376923/

 
____________________________________

Bioelectrochemical technologies for removal of xenobiotics from wastewater

2021

https://www.sciencedirect.com/science/article/abs/pii/S2213138821006664

 

____________________________________


Diversity and Niche of Archaea in Bioremediation

2018 Sep 3

Abstract

Bioremediation is the use of microorganisms for the degradation or removal of contaminants. Most bioremediation research has focused on processes performed by the domain Bacteria; however, Archaea are known to play important roles in many situations. In extreme conditions, such as halophilic or acidophilic environments, Archaea are well suited for bioremediation. In other conditions, Archaea collaboratively work alongside Bacteria during biodegradation. In this review, the various roles that Archaea have in bioremediation is covered, including halophilic hydrocarbon degradation, acidophilic hydrocarbon degradation, hydrocarbon degradation in nonextreme environments such as soils and oceans, metal remediation, acid mine drainage, and dehalogenation. Research needs are addressed in these areas. Beyond bioremediation, these processes are important for wastewater treatment (particularly industrial wastewater treatment) and help in the understanding of the natural microbial ecology of several Archaea genera.

2. Archaea in the Degradation of Organics in Hypersaline Environments

Perhaps, the most developed research area that connects Archaea to bioremediation lies within the degradation of organics in hypersaline environments. Natural hypersaline environments include salterns, salt lakes, salt marshes, salt flats (sabkhas), and oil and gas production wastewaters. The contamination of these environments with crude oil is common, and about 5% of the chemical, pharmaceutical, and oil industries have highly saline wastewater effluents in need of treatment. Members of both Bacteria and Archaea are known to inhabit such environments and these are often referred to as “halobacteria” and “haloarchaea,” respectively. Recent reviews have focused on hydrocarbon degradation by halobacteria and haloarchaea, the biotechnological potential of the hydrolytic enzyme, the biodiversity of microbial communities in halophilic environments, the potential of haloarchaea in bioremediation processes, and the growing rate of research of haloarchaea in bioremediation. Recently, a new database—called HaloDom—has compiled all isolated halophilic species into a single online resource. Many Bacteria can degrade at salinities of up to 15% such as strains of the genera Ralstonia, Halomonas, Dietzia, and Alcanivorax. Here, an overview of the haloarchaeal strains isolated on the ability to degrade hydrocarbons, such as crude oil, is provided.

The haloarchaea cluster into a single class (the class Halobacteria) within the phylum Euryarchaeota. They are typically cultured at neutral pH and temperatures of 30-45°C, and they require high salinities of 1.8–5.0 M NaCl. Many strains have been traditionally isolated on a standard nutrient media that contains heterotrophic carbon and energy sources. Table 1 lists the strains associated with hydrocarbon degradation and their degradative abilities. Additionally, a phylogenetic tree of many of these strains (where nearly full-length 16S rRNA gene sequences were available), as well as other strains and phylogenetic groups discussed in this manuscript, is shown in Figure 1. The metabolic capabilities of haloarchaea for hydrocarbon degradation appear vast, and these Archaea all inhabit a close phylogenetic association.

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6140281/

 

____________________________________



New Uses of Haloarchaeal Species in Bioremediation Processes

13 October 2014

https://www.intechopen.com/chapters/48401


____________________________________


Haloarchaea: worth exploring for their biotechnological potential

12 September 2017

Abstract

Halophilic archaea are unique microorganisms adapted to survive under high salt conditions and biomolecules produced by them may possess unusual properties. Haloarchaeal metabolites are stable at high salt and temperature conditions that are useful for industrial applications. Proteins and enzymes of this group of archaea are functional under salt concentrations at which bacterial counterparts fail to be active. Such properties makes haloarchaeal enzymes suitable for salt-based applications and their use under dehydrating conditions. For example, bacteriorhodopsin or the purple membrane protein present in halophilic archaea has the most recognizable applications in photoelectric devices, artificial retinas, holograms etc. Haloarchaea are also useful for bioremediation of polluted hypersaline areas. Polyhydroxyalkanoates and exopolysccharides produced by these microorganisms are biodegradable and have the potential to replace commercial non-degradable plastics and polymers. Moreover, halophilic archaea have excellent potential to be used as drug delivery systems and for nanobiotechnology by virtue of their gas vesicles and S-layer glycoproteins. Despite of possible applications of halophilic archaea, laboratory-to-industrial transition of these potential candidates is yet to be established.

https://link.springer.com/article/10.1007/s10529-017-2434-y

____________________________________


Archaea: An Agro-Ecological Perspective

2021 May 21


Abstract

Microorganisms inhabiting bulk soil and rhizosphere play an important role in soil biogeochemical cycles leading to enhanced plant growth and productivity. In this context, the role of bacteria is well established, however, not much reports are available about the role archaea plays in this regard. Literature suggests that archaea also play a greater role in nutrient cycling of carbon, nitrogen, sulfur, and other minerals, possess various plant growth promoting attributes, and can impart tolerance to various abiotic stresses (especially osmotic and oxidative) in areas of high salinity, low and high temperatures and hydrogen ion concentrations. Thermoacidophilic archaea have been found to potentially involve in bioleaching of mineral ores and bioremediation of chemical pollutants and aromatic compounds. Looking at immense potential of archaea in promoting plant growth, alleviating abiotic stresses, and remediating contaminated sites, detailed studies are required to establish their role in different ecological processes, and their interactions in rhizosphere with plant and other microflora (bacteria and fungi) in different ecosystems. In this review, a brief discussion on archaea from the agro-ecological point of view is presented.

https://pubmed.ncbi.nlm.nih.gov/34019119/

____________________________________


Role of archaea in aquaculture: prospects and challenges

29 October 2023

https://link.springer.com/article/10.1007/s10499-023-01317-y

____________________________________


Diversity, metabolism and cultivation of archaea in mangrove ecosystems

02 December 2020

Abstract

Mangroves comprise a globally significant intertidal ecosystem that contains a high diversity of microorganisms, including fungi, bacteria and archaea. Archaea is a major domain of life that plays important roles in biogeochemical cycles in these ecosystems. In this review, the potential roles of archaea in mangroves are briefly highlighted. Then, the diversity and metabolism of archaeal community of mangrove ecosystems across the world are summarized and Bathyarchaeota, Euryarchaeota, Thaumarchaeota, Woesearchaeota, and Lokiarchaeota are confirmed as the most abundant and ubiquitous archaeal groups. The metabolic potential of these archaeal groups indicates their important ecological function in carbon, nitrogen and sulfur cycling. Finally, some cultivation strategies that could be applied to uncultivated archaeal lineages from mangrove wetlands are suggested, including refinements to traditional cultivation methods based on genomic and transcriptomic information, and numerous innovative cultivation techniques such as single-cell isolation and high-throughput culturing (HTC). These cultivation strategies provide more opportunities to obtain previously uncultured archaea.

https://link.springer.com/article/10.1007/s42995-020-00081-9

 
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Distribution and genomic variation of ammonia-oxidizing archaea in abyssal and hadal surface sediments

22 December 2023

Abstract

Ammonia-oxidizing archaea of the phylum Thaumarchaeota play a central role in the biogeochemical cycling of nitrogen in benthic sediments, at the interface between pelagic and subsurface ecosystems. However, our understanding of their niche separation and of the processes controlling their population structure in hadal and abyssal surface sediments is still limited. Here, we reconstructed 47 AOA metagenome-assembled genomes (MAGs) from surface sediments of the Atacama and Kermadec trench systems. They formed deep-sea-specific groups within the family Nitrosopumilaceae and were assigned to six amoA gene-based clades. MAGs from different clades had distinct distribution patterns along oxygen-ammonium counter gradients in surface sediments. At the species level, MAGs thus seemed to form different ecotypes and follow deterministic niche-based distributions. In contrast, intraspecific population structure, defined by patterns of Single Nucleotide Variants (SNV), seemed to reflect more complex contributions of both deterministic and stochastic processes. Firstly, the bathymetric range had a strong effect on population structure, with distinct populations in abyssal plains and hadal trenches. Then, hadal populations were clearly separated by trench system, suggesting a strong isolation-by-topography effect, whereas abyssal populations were rather controlled by sediment depth or geographic distances, depending on the clade considered. Interestingly, genetic variability between samples was lowest in sediment layers where the mean MAG coverage was highest, highlighting the importance of selective pressure linked with each AOA clade’s ecological niche. Overall, our results show that deep-sea AOA genome distributions seem to follow both deterministic and stochastic processes, depending on the genomic variability scale considered.

https://www.nature.com/articles/s43705-023-00341-6

 

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Biotechnological potentials of halophilic microorganisms and their impact on mankind

2022 May 31

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9152817/

 
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Genes identified that allow bacteria to thrive despite toxic heavy metal in soil

March 2024

https://phys.org/news/2024-03-genes-bacteria-toxic-heavy-metal.html 

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Genetically engineered microorganisms for environmental remediation

2022

https://www.sciencedirect.com/science/article/pii/S0045653522032441

 

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Perspectives on biotechnological applications of archaea

2002 May 31

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC2685559/

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Biotechnological applications of archaeal enzymes from extreme environments

2018

https://pubmed.ncbi.nlm.nih.gov/30290805/

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Extremozymes: A Potential Source for Industrial Applications

2017

 Abstract

Extremophilic microorganisms have established a diversity of molecular strategies in order to survive in extreme conditions. Biocatalysts isolated by these organisms are termed extremozymes, and possess extraordinary properties of salt allowance, thermostability, and cold adaptivity. Extremozymes are very resistant to extreme conditions owing to their great solidity, and they pose new opportunities for biocatalysis and biotransformations, as well as for the development of the economy and new line of research, through their application. Thermophilic proteins, piezophilic proteins, acidophilic proteins, and halophilic proteins have been studied during the last few years. Amylases, proteases, lipases, pullulanases, cellulases, chitinases, xylanases, pectinases, isomerases, esterases, and dehydrogenases have great potential application for biotechnology, such as in agricultural, chemical, biomedical, and biotechnological processes. The study of extremozymes and their main applications have emerged during recent years.

https://www.jmb.or.kr/journal/view.html?doi=10.4014/jmb.1611.11006

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Radiation-resistant extremophiles and their potential in biotechnology and therapeutics


Abstract

Extremophiles are organisms able to thrive in extreme environmental conditions. Microorganisms with the ability to survive high doses of radiation are known as radioresistant or radiation-resistant extremophiles. Excessive or intense exposure to radiation (i.e., gamma rays, X-rays, and particularly UV radiation) can induce a variety of mutagenic and cytotoxic DNA lesions, which can lead to different forms of cancer. However, some populations of microorganisms thrive under different types of radiation due to defensive mechanisms provided by primary and secondary metabolic products, i.e., extremolytes and extremozymes. Extremolytes (including scytonemin, mycosporine-like amino acids, shinorine, porphyra-334, palythine, biopterin, and phlorotannin, among others) are able to absorb a wide spectrum of radiation while protecting the organism's DNA from being damaged. The possible commercial applications of extremolytes include anticancer drugs, antioxidants, cell-cycle-blocking agents, and sunscreens, among others. This article aims to review the strategies by which microorganisms thrive in extreme radiation environments and discuss their potential uses in biotechnology and the therapeutic industry. The major challenges that lie ahead are also discussed.

https://pubmed.ncbi.nlm.nih.gov/23271672/


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Archaea: Microbial Candidates in Next-generation Probiotics Development

2018


Abstract

Pharmabiotics and probiotics in current use or under development belong to 2 of 3 domains of life, Eukarya (eg, yeasts) and Bacteria (eg, lactobacilli). Archaea constitute a third domain of life, and are currently not used as probiotics, despite several interesting features. This includes the absence of known pathogens in humans, animals, or plants and the existence of some archaea closely associated to humans in various microbiomes. We promote the concept that some specific archaea that naturally thrive in the human gut are potential next-generation probiotics that can be rationally selected on the basis of their metabolic phenotype not being encountered in other human gut microbes, neither Bacteria nor Eukarya. The example of the possible bioremediation of the proatherogenic compound trimethylamine into methane by archaeal microbes is described.

https://pubmed.ncbi.nlm.nih.gov/29668558/

 
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Major Groups of Microorganisms Employed in Bioremediation

11 December 2022

https://link.springer.com/chapter/10.1007/978-3-031-18017-0_8

 
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We must have regulations put in place, this is in order so that companies do not release unregulated genetically modified plants into the wilderness. This has already happened with unregulated genetically modified wheat that was released in Oregon. Many question how we can stop the damage that has been done. We must stop bad genetic experiments that harm the environment and planet.

 
What if it were possible to genetically modify a plantmthat could balance out the air in the atmosphere. Many also question that if we try to tamper with natural disasters, such as how a volcano could change the chemical composition of our atmosphere. That this could interfere with the natural balance of this planet, and that it could have consequences later on. With new types of technology, it could be possible to save our civilization, including a lot of the wildlife, such as trees, plants and animals from natural disasters and extinction. 

 

 
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Pollution-Busting Plants

 

Transgenic trees and plants may break down the pollutants left behind at sites ranging from former factories to firing ranges

 

http://www.scientificamerican.com/article/genetically-modified-plants-suck-up-pollution/


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Uptake of BTEX Compounds by Hybrid Poplar Trees in Hazardous Waste Remediation

http://cfpub.epa.gov/ncer_abstracts/index.cfm/fuseaction/display.abstractDetail/abstract/5312

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Enzymatic micromotor-driven CO2 sequestration in water

September 17, 2015

Rapid decontamination of an aqueous solution by a freely moving microscrubber: this scenario has been realized by American scientists for the sequestration of CO2 from water. In the journal Angewandte Chemie, they introduce their concept of enzymatic conversion of CO2 into solid calcium carbonate, which is greatly facilitated by the use of self-propelled micromotors that act as a movable enzyme support.

The on-site mineralization of the gaseous CO2 into solid and durable carbonate salts is one of the options that scientists consider feasible for tackling the issue of the ongoing and massive man-made release of carbon dioxide by the combustion of fossil fuels. Calcium carbonate is one of the preferred storage forms for CO2, and marine organisms have piled up layers of calcium carbonate as thick as mountains by bioconversion of carbon dioxide over millions of years, However, the uncatalyzed formation of carbonates from carbon dioxide in aqueous environments is too slow to be practically applicable for large-scale CO2 sequestration by man. Joseph Wang and his group at the University of California, San Diego, have now greatly speeded up this conversion by a cunning chemical-nanoengineering approach. "Our approach combines the biocatalytic activity of carbonic anhydrase [a zinc metalloenzyme that catalyzes the hydration of CO2 to form bicarbonate] with the self-propulsion of chemically powered micromotors through CO2-saturated samples to act as highly efficient mobile biocatalytic microscrubbers," they write. The main advantage of this method is the automatic self-mixing and scrubbing of the reaction solution just by adding environmentally friendly hydrogen peroxide, the "fuel" of the micromotors.

http://phys.org/news/2015-09-enzymatic-micromotor-driven-co2-sequestration.html

 

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Engineered surface holds promise for tech to convert CO₂ into liquid fuel

March 24, 2025 

Researchers have developed a novel combination of materials that have organic and inorganic properties, with the goal of using them in technologies that convert carbon dioxide from the atmosphere into a liquid fuel. The paper, "Mild-Annealed Molecular Layer Deposition (MLD) Tincone Thin Film as Photoelectrochemically Stable and Efficient Electron Transport Layer for Si Photocathodes," is published in ACS Applied Energy Materials.

https://techxplore.com/news/2025-03-surface-tech-liquid-fuel.html

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Biodiesel wastewater treatment: Capturing carbon and valuable chemicals

March 21, 2025

While biodiesel provides a cleaner-burning alternative to petroleum diesel, it produces ​​CO2 and hazardous wastewater during manufacturing, requiring extra steps to achieve sustainability. A diagnostic study led by University of Michigan researchers works to improve a process that captures CO2 while treating biodiesel wastewater and produces valuable co-products like fuels and green chemicals.

During biodiesel production, fats—like vegetable oils, animal fats or recycled restaurant grease—are transformed into fuel through a process called transesterification. With the help of a catalyst, an alcohol (typically methanol) breaks the bonds in the fat molecules to create glycerol and long, chain-like molecules called fatty acid esters. 

The fatty acid esters, which resemble petroleum diesel’s molecular structure, become biodiesel while the glycerol goes into the wastewater as a byproduct. If left untreated, glycerol can pollute natural water resources by depleting oxygen levels, suffocating fish and other organisms.

https://cee.engin.umich.edu/2025/03/21/biodiesel-wastewater-treatment-capturing-carbon-and-valuable-chemicals/

 

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Scientists Develop Breakthrough Catalyst for Clean Propane Conversion 

 

August 04, 2025

 

Propane dehydrogenation (PDH) is a chemical process that requires a large input of heat, typically needing temperatures above 600°C when carried out using traditional thermo-catalytic methods, the journal Nature Chemistry reported.

 

These high temperatures pose several issues, including high energy usage, degradation of the catalyst through sintering, and the buildup of carbon deposits known as coke. Scientists have long sought ways to overcome these limitations and carry out PDH at or near room temperature, which remains a key challenge in the field of catalysis.

 

A new study published in Nature Chemistry offers a promising solution. Led by Prof. Tao Zhang and Prof. Aiqin Wang from the Dalian Institute of Chemical Physics at the Chinese Academy of Sciences (CAS), in collaboration with Prof. Yi Gao’s team at the Shanghai Advanced Research Institute of CAS, the researchers introduced a novel approach.

 

They developed a water-assisted PDH process that uses a copper single-atom catalyst (SAC) and is driven by a combination of light and heat, known as photo-thermo catalysis. This method enables efficient conversion of propane into propylene at much lower temperatures than previously possible.

 

By using a Cu1/TiO2 SAC, researchers achieved PDH under near-ambient conditions in a water vapor atmosphere. In a continuous-flow fixed-bed reactor, the reaction temperature was reduced to just 50–80 °C, achieving a maximum reaction rate of 1201 μmol gcat-1 h-1.

 

Researchers revealed that Cu single atoms, water vapor, and light illumination all played essential roles in the propane-to-propylene conversion.

 

Through photocatalytic water splitting on the Cu1/TiO2 SAC, hydrogen and hydroxyl species were generated. Hydroxyl radicals subsequently adsorbed on the catalyst surface, abstracting hydrogen atoms from propane to form propylene and water. Water acted catalytically without being consumed. This mechanism fundamentally differs from traditional PDH and oxidative dehydrogenation of propane.

 

https://ana.ir/en/news/9574/scientists-develop-breakthrough-catalyst-for-clean-propane-conversion 

 

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New method uses microalgae to create eco-friendly carbon fibers for manufacturing

July 30, 2025

Carbon fibers play a crucial role in aviation, wind energy, and lightweight construction. However, their conventional production relies on petroleum-derived materials, resulting in significant environmental impact. A research consortium led by the Technical University of Munich (TUM) has developed a new production method that utilizes renewable raw materials to manufacture carbon fibers.

Novel Production Process for Carbon Fibers

Carbon fibers are known for their lightweight, high strength, and durability. They are widely used in carbon fiber-reinforced plastics for aircraft, vehicles, wind turbines, and sports equipment such as bicycles, tennis rackets, and skis. These materials are typically produced using acrylonitrile, which is primarily derived from petroleum-based propylene.

Researchers at the Werner Siemens Chair of Synthetic Biotechnology at the TUM School of Natural Sciences explored the use of photosynthetically active microalgae to extract oils. According to Prof. Thomas Brück, these microalgae absorb carbon dioxide during photosynthesis and store it in the form of algae oils. Chemical processes were then used to extract glycerine from these oils.

The Fraunhofer Institute for Interfacial Engineering and Biotechnology (IGB) developed a catalytic process to convert biogenic glycerol into acrylonitrile, the essential raw material for carbon fiber production. This process has reached a level of maturity at the Straubing branch of Fraunhofer IGB and is now ready for scaling toward industrial implementation.

"We have thus created the conditions for the production of sustainable carbon fibers that have the same high-performance properties as conventionally manufactured carbon fibers," said Dr. Arne Roth, department head at Fraunhofer IGB.

https://advancedcarbonscouncil.org/blogpost/2151389/512769/New-method-uses-microalgae-to-create-eco-friendly-carbon-fibers-for-manufacturing

 

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Mechanochemical approach enables low-temperature CO₂ capture and conversion

June 13, 2025

https://advancedcarbonscouncil.org/blogpost/2151389/511626/Mechanochemical-approach-enables-low-temperature-CO-capture-and-conversion

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Electrocatalytic sterilization: Nanowires produce localized highly alkaline microenvironments to kill bacteria

March 13, 2025

Harmful microorganisms such as bacteria represent one of the largest threats to human health. Efficient sterilization methods are thus a necessity.

In the journal Angewandte Chemie, a research team has now introduced a novel, sustainable, electrocatalytic sterilization method based on electrodes covered with copper oxide nanowires. These generate very strong local electric fields, thereby producing highly alkaline microenvironments that efficiently kill bacteria.

Conventional disinfection methods, such as chlorination, treatment with ozone, hydrogen peroxide oxidation, and irradiation with ultraviolet light have disadvantages, including harmful by-products and high energy consumption.

Electrochemical disinfection methods, which rely primarily on a pulsed high-voltage electric field and the electrocatalytic generation of highly oxidative radicals, are more efficient and sustainable. However, they require either high voltage or a significant gas supply, which limits their application in practice.

A team led by Tong Sun and Yuanhong Xu at Qingdao University (China) have now proposed a novel, in situ, electrocatalytic sterilization method that induces localized highly alkaline microenvironments in neutral electrolytes under a constant current at relatively low voltage. Most bacteria cannot survive in such extremely alkaline environments.

https://phys.org/news/2025-03-electrocatalytic-sterilization-nanowires-localized-highly.html

 

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New coating uses graphene oxide to deliver silver ions for long-lasting antimicrobial action

July 30, 2025

https://advancedcarbonscouncil.org/blogpost/2151389/512772/New-coating-uses-graphene-oxide-to-deliver-silver-ions-for-long-lasting-antimicrobial-action

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Graphene oxide patchwork membranes

 

12 March 2021

https://www.nature.com/articles/s41565-021-00876-6

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PGClear Uses a Palladium-Gold Catalyst to Break Down Hazardous Compounds

April 16, 2013

 

Using a palladium-gold catalyst to break down hazardous compounds, the PGClear project is set to help clean the environment and treat contaminated groundwater.

 

https://scitechdaily.com/pgclear-uses-a-palladium-gold-catalyst-to-break-down-hazardous-compounds/

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99.7% in Only One Hour – New Nanocoating Kills More Bacteria Faster

 

September 23, 2022

 

A New Copper Coating Could Be the Next Superbug Fighter

A new copper covering that kills bacteria faster and in greater amounts than existing formulations might be available for hospitals and other high-traffic locations in the near future.

 

Although current formulations comprised of pure copper are antibacterial and self-sanitizing, they kill certain forms of bacteria with a thicker cell wall (Gram-positive bacteria), more slowly than bacteria with a thinner cell wall (Gram-negative).

 

Nano-Copper Coating with Zinc for Enhanced Effectiveness

 

Using zinc and bacteria-killing nanoscale features, a team of the University of British Columbia researchers under the direction of Dr. Amanda Clifford, an assistant professor in the department of materials engineering, has created a nano-copper coating. Small bumps known as nanoscale features have the power to kill bacteria by rupturing their cell walls. In contrast to pure copper alone, zinc, which is similarly antibacterial, selectively oxidizes in the presence of copper and aids in the faster killing of bacteria.

 

“Use of our coating could significantly reduce the incidence of contracting bacterial infections from high-touch surfaces in healthcare facilities, such as doorknobs and elevator buttons since it kills bacteria using multiple approaches,” says Dr. Clifford. “As it contains less copper than other existing coatings or whole copper parts, it would also be cheaper to make.”

 
https://scitechdaily.com/99-7-in-only-one-hour-new-nanocoating-kills-more-bacteria-faster/

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By ‘Editing’ Plant Genes, Companies Avoid Regulation

 JAN. 1, 2015

Its first attempt to develop genetically engineered grass ended disastrously for the Scotts Miracle-Gro Company. The grass escaped into the wild from test plots in Oregon in 2003, dooming the chances that the government would approve the product for commercial use.

Yet Scotts is once again developing genetically modified grass that would need less mowing, be a deeper green and be resistant to damage from the popular weedkiller Roundup. But this time the grass will not need federal approval before it can be field-tested and marketed.

Scotts and several other companies are developing genetically modified crops using techniques that either are outside the jurisdiction of the Agriculture Department or use new methods — like “genome editing” — that were not envisioned when the regulations were created.

The department has said, for example, that it has no authority over a new herbicide-resistant canola, a corn that would create less pollution from livestock waste, switch grass tailored for biofuel production, and even an ornamental plant that glows in the dark.

The trend alarms critics of biotech crops, who say genetic modification can have unintended effects, regardless of the process.

“They are using a technical loophole so that what are clearly genetically engineered crops and organisms are escaping regulation,” said Michael Hansen, a senior scientist at Consumers Union. He said the grass “can have all sorts of ecological impact and no one is required to look at it.”

Even some people who say the crops are safe and the regulations overly burdensome have expressed concern that because some crops can be left unregulated, the whole oversight process is confusing and illogical, in some cases doing more harm than good.

In November’s Nature Biotechnology, plant researchers at the University of California, Davis, wrote that the regulatory framework had become “obsolete and an obstacle to the development of new agricultural products.”

But companies using the new techniques say that if the methods were not labeled genetic engineering, novel crops could be marketed or grown in Europe and other countries that do not readily accept genetically modified crops.

Freedom from oversight could also open opportunities for smaller companies and university breeders and for the modification of less common crops. Until now, in part because of the costs associated with regulation, crop biotechnology has been dominated by Monsanto and a handful of other big companies working mainly on widely grown crops like corn and soybeans.

“It enables small companies to develop products, and even university start-ups,” said Luc Mathis, chief executive of Cellectis Plant Sciences, which recently received a regulatory exemption for a potato it says will make French fries less unhealthy.

An industry-sponsored study said that the large companies spend an average of $136 million on the development of a genetically engineered crop, including $35 million in regulatory costs. The Agriculture Department once took two to five years to review applications, though it is trying to reduce that to 13 to 16 months.

Continue reading the main story

Genetically engineered crops, popularly called genetically modified organisms or G.M.O.s, typically have genes from other organisms inserted into their DNA. The most popular ones, like Roundup-resistant soybeans and insect-resistant corn, use genes from bacteria...

 

http://www.nytimes.com/2015/01/02/business/energy-environment/a-gray-area-in-regulation-of-genetically-modified-crops.html?_r=0

 
 
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Mealworms need more than plastic to be a nutritious food source

 

June 17, 2025

 

Mealworms need a minimum level of protein to grow and become a sustainable food source, according to a new study that challenges the myth that insects have superpowers of taking plastic waste and converting it to a nutritionally valuable product.

https://phys.org/news/2025-06-mealworms-plastic-nutritious-food-source.html

 

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Q&A: Geoengineering Is ‘A Bad Idea Whose Time Has Come

03.23.10

 http://www.wired.com/2010/03/hacktheplanet-qa/

 

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We can see many of the bad problems with geoengineering in food. We have seen many of the good prospects, from geoengineering in certain medical fields. Advancements in recent biotechnology have made many people wonder if geoengineering is a good or bad idea. 

 

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Chapter 34: Toxic clean-up technology



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People have been making plastics out of oil for many years. Oil can even make natural sheets and rocks similar to plastic in the wild.

Using a little oil is not that big of a problem. However, the way that we consume, burn and drill for oil these days is questionably causing problems to living beings and the environment.

Many people see the amount of fossil fuel being drilled for many plastics and synthetic fibers.  Too much oil can cause problems to wildlife when plastic and products made from fossil fuel enter the environment. This is why people say that plant based plastic could be better for the environment.

There are many synthetic chemicals used in scientific experiments. There are constantly new inventions with synthetic chemicals and fibers. We still do not know the long-term effects of many experiments with harmful chemicals. This includes genetically modified chemicals as well. Many question if we can design a way, in order to remove a lot of the toxic waste in landfills.  It is debated, when we try to destroy materials and matter, the exact amount of materials that stay intact and exist on a microscopic level.   

 

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High-Powered Plasma Turns Garbage Into Gas

 

• 01.20.12

 

http://www.wired.com/2012/01/ff_trashblaster/

 

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Plasma arc recycling

 

Last updated: November 24, 2014.

 http://www.explainthatstuff.com/plasma-arc-recycling.html

 

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Plasma Gasification: Revolutionizing Waste Management

August 12, 2024

Plasma (“the fourth state of matter”) is an extremely high-temperature, highly ionized gas that is able to carry an electric current. Natural plasma includes lightning and gas at the surface of the sun, while man-made plasma is formed using a plasma torch to pass an electric current through a gas like oxygen. The reaction dissociates the gas into electrons and ions and increases its temperature to nearly as hot as the sun’s surface. This plasma can then be used for plasma gasification, a process that breaks waste down into basic chemicals. 

Plasma gasification can turn “any kind of trash” into chemical products and clean fuels. Industry leader InEnTec was founded in 1995 to focus on governments and companies with large amounts of toxic waste. Their patented Plasma Enhanced Melter (PEM) system is deployed in 13 facilities worldwide. “Back in the early ’90s, global warming was more of an academic pursuit,” InEnTech co-founder, president, and CEO Jeffrey E. Surma told MIT News in 2021. With climate change a leading global challenge, his co-founder, Daniel R. Cohn, believes it is time for InEnTech to expand its impact. 

“About 130 million tons of waste per year go into landfills in the U.S., and that produces at least 130 million tons of CO2-equivalent emissions,” Cohn argues. Most of these emissions are methane, a greenhouse gas that is 28 times more potent than carbon dioxide (CO2) and a global concern. The Global Methane Initiative (GMI) is an international public-private partnership focused on advancing methane mitigation in oil and gas, biogas, and coal mines. By utilizing plasma gasification and reducing or even eliminating landfills and other waste, the GMI could make significant advancements.

https://www.aii.org/plasma-gasification-revolutionizing-waste-management/ 

 

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Some people think that a more environmentally friendly way of cremation would be with solar fire. This could be better than cutting down trees to burn or coals for fire.


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Melting steel with solar power

 

https://www.youtube.com/watch?v=8tt7RG3UR4c


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Giant Magnifier Reaches 5,000 Degrees Using Only Sunlight

 

2010

 

It was created to research our most powerful weapons, but it's also used to try to protect Earth from cataclysmic destruction. 

 

 http://discovermagazine.com/2010/sep/solar-concentrator-reaches-5000-degrees

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The following article explains the environmental impact and chemicals given off by cremations. This includes cremation by fire, or using liquid nitrogen to freeze and shatter the cremains.

 

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METALS IN MEDICINE AND THE ENVIRONMENT

Cremation Waste and Toxins

http://faculty.virginia.edu/metals/cases/huffman1.html

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Our biggest concern is trying to get rid of highly toxic waste, such as uranium and other harmful chemicals. With new technology, we are able to make clean energy from uranium .

 

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Improving the selective extraction of spent uranium in nuclear waste clean-up

June 16, 2015

Driven by the need to find ways of separating, recycling and reducing nuclear waste, chemists at The University of Nottingham are developing our understanding of how uranium interacts with elements from around the periodic table to potentially help improve the selective extraction of spent uranium in nuclear waste clean-up.

 http://phys.org/news/2015-06-spent-uranium-nuclear-clean-up.html#jCp

 

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Recycling nuclear waste via advanced reactor design

 

May 28th, 2015


 An advanced nuclear reactor under development by Hitachi could help solve the nuclear waste problem, and University of Michigan researchers were involved in verifying its safe performance through computer simulations.


The U-M team worked with colleagues at the Massachusetts Institute of Technology and the University of California, Berkeley. After more safety analysis, Hitachi plans to move forward with a prototype of the "resource-renewable boiling water reactor" in the next few years.

One of the major technological hurdles for nuclear energy is developing systems to dispose of the waste produced by typical reactors. It must be sealed away for hundreds of millennia while the radioactivity naturally decreases.

Hitachi's new design would burn off the longest-lived radioactive materials, called transuranics, shortening that isolation period to a few centuries. This would recycle the nuclear waste to produce yet more energy and reduce the amount that must be stowed away.

http://phys.org/news/2015-05-recycling-nuclear-advanced-reactor.html

 


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Destroying nuclear waste to create clean energy? It can be done

Nov 16, 2018

If not for long-term radioactive waste, then nuclear power would be the ultimate “green” energy. The alternative to uranium is thorium, a radioactive ore whose natural decay is responsible for half of our geothermal energy, which we think of as “green energy.” More than 20 years of research at the European Centre for Nuclear Research (CERN), the birthplace of the internet and where Higgs boson was discovered, demonstrate that thorium could become a radically disruptive source of clean energy providing bountiful electricity any place and at any time.

Coal and gas remain by far the largest sources of electricity worldwide, threatening our climate equilibrium. Non-fossil alternatives, such as solar power, use up a forbidding amount of land, even in sunny California, plus the decommissioning will pose a serious recycling challenge within 20 years. Solar is best used on an individual household basis, rather than centralized plants. Wind requires an even larger surface area than solar.

As Michael Shellenberger, a Time magazine “Hero of the Environment”, recently wrote: “Had California and Germany invested $680 billion into nuclear power plants instead of renewables like solar and wind farms, the two would already be generating 100% or more of their electricity from clean energy sources.” Correct, but the disturbing issue of long-term nuclear waste produced by conventional, uranium based, nuclear plants still remains.

In the early 1990s, Carlo Rubbia, Nobel prize winner in physics (1984) and then CERN’s director general, launched a small experiment applying cutting-edge accelerator technologies toward energy production. The First Energy Amplifier Test (FEAT), funded by the European Commission, successfully demonstrated the principles of a clean and inherently safe process of energy production, based on widely available thorium. Since then, numerous experiments have demonstrated the feasibility of a large scale-up for industrial use. They also demonstrated that existing long-term (240,000 years or more) nuclear waste can be “burned up” in the thorium reactor to become a much more manageable short-term (less than 500 years) nuclear waste.

An Accelerator-Driven System (ADS), as the process is called, comprises an assembly of key technologies developed at CERN: an accelerated proton beam focuses on a metal target, usually lead, in a process called spallation. This spawns neutrons that in turn convert thorium into fissile uranium233, producing heat by way of nuclear fission. The heavy uranium233 nuclei divides into smaller nucleus such as zirconium (think Shopping Channel jewellery) or xenon (used in camera flash bulbs), with only minimal radioactive waste produced. 

The advantages of an ADS over other energy production process are many:

Clean: No emissions are produced (CO2, nitrogen or sulphur oxides particles, among others), unlike with fossil fuel. Heat is generated from the transmutation of thorium into the highly radioactive uranium233 and its subsequent fission into smaller particles.

Feasible: ADS technology development has been proven to be a bounded problem with a realistic development timeline. In comparison, fusion is an unbounded problem that does not have a constrained development timeline.

Transmutation of nuclear waste: the ADS process has been proven to transmute long-term nuclear waste, harmful for 240,000 years or more, into short-term radioactivity waste of less than 500 years toxicity. The technology would solve the intractable problem of very long-term radioactive waste storage.

No military usage: The International Atomic Energy Agency has repeatedly stated that the technology is “intrinsically proliferation resistant.”

Large thorium reserves: enough for 20 centuries at 2018 level of global electricity consumption. Thorium is well distributed around the globe, with no nation having a monopoly.

High energy density: 1 tonne of thorium would provide the energy equivalent of 3 million tonnes of coal, or 200 tonnes of natural uranium enriched for use in a nuclear reactor.

Inherent safety: the process operates at atmospheric pressure therefore the plant can’t explode (unlike Chernobyl). The reaction is also stops immediately when the proton beam is interrupted, providing inherent safety.

Smart grid friendly: Immediate ON/OFF capability would make ADS power plants ideal for base load energy production for smart grids.

Small footprint: A 500MW ADS plant would only be as large as a mediumsize factory, compared to 26 km2 (10 mi2) for the 550MW Topaz solar farm in the sunny California desert. In the wintery north-west, an equivalent solar farm would be almost three times larger, approximately 62 km2. Wind turbines require even more space.

Proximity: inherent safety and small size make ADS ideally suited for any use, industrial or urban, and able to be located in remote regions, including high latitudes with little sunshine.

Decarbonized hydrogen production: reactors could be set close to abundant freshwater at high latitudes for clean hydrogen production, allowing the conversion of electrons into a green gas used for transport, heating and industrial processes. 

DS technology advances the double promise of boundless clean electricity, together with the destruction of highly toxic long-term nuclear waste. Its inherent safety will allow power plants to be located anywhere, even close to urban areas, and in any climate. ADS offers the possibility to provide sustainable energy on demand and with easy integration into smart grids. Combined with the production of green hydrogen, it could decarbonize our entire energy needs, from transport to industrial.

The development of this promising technology offers hope for a paradigm shift in clean energy production, achievable in years instead of decades, helping the fight against global warming.

https://www.weforum.org/stories/2018/11/destroying-nuclear-waste-to-create-clean-energy-it-can-be-done/

 

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Radioactive nuclear waste is a global threat. These scientists may have a new solution

Aug 8, 2018

The US and Russia have approximately 7000 warheads each, enough to destroy humanity many times over. The US has enough highly radioactive plutonium, left over from the Cold War and generated by its nuclear power plants, to produce 10,000 more warheads. What are we to do with this unnecessary, deadly remnant of our belligerence?

There are “two kinds of problems, the urgent and the important", as President Dwight Eisenhower said in his 1954 speech at Northwestern University.

"The urgent are not important, and the important are never urgent." Plutonium waste is not on the urgent pile of world leaders’ agendas. But it’s top of the important pile for humanity. We are already failing our future generations.

In February 2014, an explosion shook the main plutonium storage facility near Carlsbad, New Mexico, resulting in extensive damage. Its cause was an innocent typo and poor oversight, according to Patrick Malone of the journal New Mexican. Absorbent clay is used to neutralize potential acidic chemical reactions from diverse neutralizing compounds in the waste drums. Probably to cut costs, relying on cat litter as a source of clay was recommended.

But a slight typo in an update memo changed the specifications from "kitty litter/zeolite clay" to simply "kitty litter (clay)", as the official report noted. The result was the use of a highly reactive organic wheat-based cat litter (sWheat Scoop brand), instead of an inorganic clay-based litter, to stabilize the drum mixture. This led to a slow but relentless chemical reaction inside the drum, causing it to overheat and finally explode. The cost of repair and delays was estimated at $1.4 billion.

In May 2017, a storage tunnel collapsed at the Hanford nuclear waste storage facility in Washington state. Maintenance was at fault, not only of the infrastructure but of the waste drums themselves. Leakages of highly radioactive waste have happened before in that facility, according to The Atlantic. On the Department of Energy’s website, it announces the removal of “radioactive sludge stored near the Columbia River”, where “near” means “about 400 yards” (360 metres) from the river. There are 53 million gallons of such radioactive sludge stored at Hanford, with no clear measure of the current level of leakage so close to a precious water resource. 

Such contamination has already taken place, for example in Coldwater Creek, north of Saint Louis, Missouri. A report published in June 2018 by the US Department of Health and Human Services concluded: "children and adults who regularly played in or around Coldwater Creek or lived in its floodplain for many years in the past (1960s to 1990s) may have been exposed to radiological contaminants. ATSDR estimated that this exposure could increase the risk of developing bone or lung cancer, leukemia, or (to a lesser extent) skin or breast cancer." Coldwater Creek does not have near the level of radiation of Chernobyl or Fukushima, but its contamination was more insidious because there was no warning to residents, who unknowingly played around radioactive shores.

Nuclear waste is a global problem. France, one of the countries most reliant on nuclear power, still has no long-term storage plan in place. In the meantime, it generates 2kg of radioactive waste per person annually, a small but not insignificant part of which will remain dangerous for at least 200,000 years. The oldest known illustrative cave paintings are only 40,000 years old. The first writing system appeared 10,000 years ago. It’s impossible, if not recklessly hubristic, to make any plan on a timescale of 100,000 years.

What are we to make of similar radioactive waste storage predicaments in Russia, Japan, China, Ukraine, or any of the more than 30 nations relying on nuclear power? Such waste must be secured for a minimum of 300 years, some of it for hundreds of thousand of years. But after only a few decades, our institutions are already showing signs of fatigue.

Vitrification, a method of encasing waste in glass to make it leakproof, is the consensus proposal to remedy leakage issues. But such an irreversible process will forever limit access to the waste, thereby nullifying any future remediation solution. Intense radioactivity will still be toxic through the glass. Vitrification is a solution steeped in our limited scientific knowledge that will burden humanity with man-made radioactivity longer than any of our institutions, or even forms of government, can reasonably be expected to last.

Giving us hope, a team of current and former CERN scientists in Geneva, among them Nobel Prize winner Carlo Rubbia, suggest a different approach. They simulated and partially tested a system to transform highly radioactive waste lasting hundreds of thousands of years into mildly radioactive waste with less than 300 years of toxicity, a more manageable time frame. Relying on a proton beam, which is common technology at CERN, and a little-used natural element called thorium, which is almost as common as lead, they propose to neutralize the world’s highly radioactive waste in as little as a few decades.

They call their detailed design the "Accelerator Driven System" (ADS), and they have partnerships in place to prove its efficacy. The estimated budget to take it from computer modelling to actual demonstration within five years is $70 million. But while the Bechtel corporation is starting construction on a $17 billion vitrification plant, the CERN team of eminent scientists have yet to receive any significant funding. A corollary of the radioactive waste neutralization reaction could be CO2-free electrical energy, if coupled with a heat exchanger. Sometimes, as Steve Jobs marvelled, the right technology is generous and feels magical.

Wouldn’t it be fair to our great-great-great-grandchildren to try a new approach to radioactive waste management? We have already failed our oceans from a lack of political will to face plastic pollution. Let’s not risk allowing our entire planet to face a similar fate from radioactive waste. 

https://www.weforum.org/stories/2018/08/radioactive-nuclear-waste-global-threat-cern-scientists-new-solution/

 

 
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Uranium in drinking water: Health risks and detection methods

 

Uranium in drinking water is a serious concern for many communities. This naturally occurring element can seep into groundwater from rocks and soil.

It poses health risks when consumed over time.

https://watersciencehub.com/uranium-in-drinking-water/ 

 

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A non-polluting method for rapidly purifying uranium-containing wastewater and efficiently recovering uranium through electrochemical mineralization and oxidative roasting

2021

Highlights 

 

• •
  A novel method was devised to treat radioactive wastewater and recover uranium.
• •
  The method rapidly extracts uranium via microcurrent mineralization.
• •
  Extracted uranium is separated from magnetite through crystal structure conversion.
• •
  Iron and uranium are further separated and recovered.
• •
  This will help in water purification, green synthesis, and resource regeneration.

 

Abstract

 

Iron-based materials have been widely used for treating uranium-containing wastewater. However, the iron-uranium solids originating by treating radioactive water through pollutant transfer methods has become a new uncontrolled source of persistent radioactive pollution. The safe disposal of such hazardous waste is not yet well-resolved. The electrochemical mineralization method was developed to rapidly purify uranium-containing wastewater through lattice doping in magnetite and recover uranium without generating any pollutants. An unexpected isolation of U₃O₈ from uranium-doped magnetite was discovered through in-situ XRD with a temperature variation from 300 °C to 700 °C. Through HRTEM and DFT calculation, it was confirmed that the destruction of the inverse spinel crystal structure during the gradual transformation of magnetite into γ-Fe₂O₃ and α-Fe₂O₃ promoted the migration, aggregation, and isolation of uranium atoms. Uniquely generated U₃O₈ and Fe₂O₃ were easily separated and over 80% uranium and 99.5% iron could be recovered. These results demonstrate a new strategy for uranium utilization and the environmentally friendly treatment of uranium-containing wastewater.

 

Introduction

 

Uranium-containing wastewater (UCW) is a typical radioactive waste generated by the nuclear industry. Uranium (U(VI)) has an extremely long half-life and better migratory characteristics than ordinary heavy metals; hence, it has more subterranean and persistent contamination characteristics. Presently, selective adsorption (Saleh et al., 2017, Liu et al., 2021, Tuzen et al., 2020) or reductive precipitation (Tsarev et al., 2016, Shao et al., 2016, Wang et al., 2016, Singh et al., 2017) are the dominant techniques for treating UCW. Nevertheless, obsolete radioactive materials form through adsorption, while secondary pollutants form through reoxidation of uranium oxides under reductive precipitation in the form of more mobile U(VI) due to environmental changes; hence, a safe method needs to be urgently developed to address these challenges while treating UCW (He et al., 2017, Jiang et al., 2018). Numerous attempts have been made to incorporate uranium into the crystal lattice of artificial minerals through mineralization and for safely releasing uranium into nature (Budnyak et al., 2016, Kong et al., 2016, van Veelen et al., 2016, Lu et al., 2018), considering the environmental stability of the consequent crystal structure. Uranium has been successfully incorporated into the mineral crystal lattice of zircons, iron oxides, silicates, and phosphates among others using methods such as high-temperature roasting, hydrothermal co-precipitation, and biotransformation (Marshall et al., 2014, Massey et al., 2014, McMaster et al., 2014, Newsome et al., 2015, Duan et al., 2019). Remarkably, the maximum amount of uranium incorporated has reached 0.3% of the total mass of a crystal lattice, exceeding the mean for commercial uranium minerals on a global scale to date. In fact, such uranium mineral compounds act as a potential uranium resource.

Removing uranium from wastewater and recycling it as a resource are regarded as the most effective methods for addressing persistent radioactive contamination of the environment caused by uranium. However, previously reported methods of mineralization were usually suffered from conditions of high-temperature and pressure, and additives or considerably long-term crystallization for achieving mineralization of uranium (Marshall et al., 2018). In addition, uranium-doped minerals formed under extreme conditions could stably exist in various natural environments because of their highly ordered crystal structure (Komlos et al., 2008, Ilton et al., 2012, Chen et al., 2021); only if the structure of the mineralized matrix is thoroughly destroyed could the uranium be re-released. Contamination-free secondary separation between impure ions originating in the destroyed mineralized matrix and uranium in leachate is considered a new challenge, even if the mineralized matrix is destroyed through special techniques such as hydrometallurgical leaching (Li et al., 2017, Chen et al., 2018, McBriarty et al., 2018).

Recovering uranium from wastewater without producing any new pollutants requires addressing three issues: (1) finding an environment friendly intermediate carrier for rapid synthesis of a large batch and selectively incorporating uranium; (2) the intermediate carrier could help isolate uranium; however, its structure should be steady and independent; (3) this intermediate carrier must be capable for reuse in the absence of new contaminants generated. Iron from a wide range of sources is non-toxic, low-cost, and multivalent; hence, it is considered an appropriate intermediate carrier for incorporating uranium. It has been reported that highly selective lattice incorporated uranium could be obtained using ferrihydrite (Massey et al., 2014), hematite (Kerisit et al., 2011), goethite (Kerisit et al., 2016, Sadergaski and Hixon, 2018), or magnetite (Pidchenko et al., 2017, Roberts et al., 2017, Pan et al., 2020), as U(VI) and Fe(II) both have similar atomic radii. Uranium is generally incorporated in an unoccupied octahedral site in the form of the hexavalent species U(VI), making it easier to form an interstitial solid solution. Magnetite is considered the best intermediate carrier for uranium because of the following features: it can be magnetically separated; its two valence states can undergo easy structural transformation; and it can be reused as a raw material for iron. However, the formation conditions for magnetite, considering a high-temperature reaction at 80 °C and a crystallization time of 24 h (Chen et al., 2013, Yang et al., 2013, Aali et al., 2018, Dodi et al., 2018), does not satisfy the engineering requirements for treating UCW in large quantities. Moreover, understanding how to isolate uranium from unoccupied octahedral sites in magnetite, and separate iron and uranium at high yields without destroying the original crystal structure are key toward the practical application in using magnetite for uranium incorporation.

Currently, electrochemical treatment is a notable clean technology, versatile and environmentally compatible for the removal of uranium from wastewater (Brown et al., 2017). There are two main ideas for electrochemical treatment of UCW: (1) using special electrodes to deposit uranium on the electrode. T. Liu (Liu et al., 2019) investigated the removal and recovery uranium using direct electrochemical reduction method. U(VI) were reduced to U(IV)O₂ on the surface of Ti electrode and over 98.0% of the accumulated U(IV)O₂ could be recovered. Yuan et al. (2015a) have successfully reduced the uranium on magnetite by electrochemical method, and U(VI) were reduced to U(V) on the surface of magnetite electrode. However, it is easy to be further oxidized and re-enter the natural environment due to the instability of U(IV) or U(V) in the environment. (2) making uranium enter the mineral crystal lattice in the form of doping using electrochemical methods. For example, B. Lu have successfully achieved purification of UCW through immobilization of uranium into magnetite (Fe₃O₄) with electrochemical methods (Lu et al., 2018). Unfortunately, the separation of iron and uranium from uranium-doped magnetite has not been resolved. Here, we designed a simple electrochemical mineralization system, with metallic iron as an anode and graphite as a cathode, by inducing microcurrents to rapidly obtain short-range ordered nano-magnetite crystals that synchronously incorporate uranium at an ambient temperature and pressure. This short-range ordered nano-magnetite can be transformed into α-Fe₂O₃ with changing its inverse spinel structure in an aerobic environment >700 °C, which can help synchronously isolate U₃O₈. U₃O₈ rapidly dissolves in dilute sulfuric acid, while α-Fe₂O₃ is insoluble, thereby helping separate U and Fe. For iron smelting, α-Fe₂O₃ is regarded as raw material for reconversion into metallic iron. Therefore, no new radioactive solid materials are produced during the process.

Iron-based materials are widely used for treating UCW. However, persistent radioactive pollution is caused by iron-uranium pollutants formed while treating UCW; moreover, iron-uranium resources are unrecoverable. This study developed a non-polluting electrochemical mineralization method followed by roasting for treating UCW. This study primarily aimed to understand: (1) the relationship between the variations in the electrochemical parameters and the uranium removal efficiency from wastewater; (2) the mechanism for converting uranium-doped magnetite into α-Fe₂O_3; and (3) the isolation of U₃O₈.

 

https://www.sciencedirect.com/science/article/abs/pii/S0304389421008499

 

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TiO₂ Nanoparticles Simultaneously Remove Arsenic and Uranium from Groundwater

March 26, 2025

 

A research team led by Prof. Luan Fubo from the Research Center for Eco-Environmental Sciences of the Chinese Academy of Sciences, has uncovered a novel mechanism involving a ternary surface complex on titanium dioxide (TiO₂) that improves the simultaneous removal of arsenic (As) and uranium (U) from contaminated groundwater. This study was published in Proceedings of the National Academy of Sciences (PNAS).  

Groundwater contamination by arsenic and uranium is a severe environmental and public health concern, linked to cancer, kidney damage, and other chronic diseases. Conventional remediation methods typically target either arsenic or uranium, often proving ineffective when both contaminants coexist due to competitive adsorption effects.  

In this study, the researchers demonstrated that TiO₂ nanoparticles can simultaneously and efficiently adsorb both As(V) and U(VI). Notably, uranium enhanced arsenic adsorption, increasing removal efficiency by up to 3.4 times compared to arsenic-only systems.  

 

Using in situ ATR-FTIR spectroscopy and density functional theory (DFT) calculations, the researchers identified the formation of a ternary surface complex, [Ti–U(VI)–As(V)], as the critical mechanism. In this process, arsenate ions displace carbonate ligands in uranyl-carbonate complexes adsorbed on TiO₂, forming a stable ternary structure that facilitates co-removal of both pollutants.  

The adsorption process proved effective under typical groundwater conditions, achieving >99% removal efficiency for both contaminants. Post-treatment residual concentrations fell below the safety limits of the World Health Organization for drinking water.  

An advantage of this method is the regenerability and reusability of the TiO₂ adsorbent. The captured arsenic and uranium can be recovered using a mild sodium hydroxide solution, allowing the material to be reused multiple times without significant loss of performance.  

This study provides a cost-effective, scalable, and eco-friendly approach to remediating dual-contaminated groundwater, offering the potential for improving global drinking water safety.

 
https://www.technologynetworks.com/applied-sciences/news/tio2-nanoparticles-simultaneously-remove-arsenic-and-uranium-from-groundwater-397700 

 

 

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Enhanced uranium extraction from seawater using bifunctional-modified molecular sieves with high selectivity and adsorption capacity

 

2025

 

Highlights

 

• •
  For the first time, the bifunctional modification of SBA-15 was achieved using aldoxime and amino/carboxyl/phosphate groups.
• •
  Under optimal conditions, the adsorption capacity for uranium of aldoxime and amino biofunctional SBA-15(SBA-15-SAO-N) reached a maximum of 701.85 mg·g^-1.
• •
  SBA-15-SAO-N exhibited excellent adsorption selectivity (U/V=30) in uranium-vanadium mixed solution; The actual uranium adsorption capacity in seawater is 135.26 ug·g^-1.
• •
  The synergistic action of multiple groups enhances the adsorption capacity and selectivity of uranium.

 

Abstract

 

The extraction of uranium from seawater is not only crucial from a strategic standpoint but also poses significant technical challenges. In this work, a series of novel bifunctionalized mesoporous silicas were prepared through a straightforward method, utilizing the structural characteristics of SBA-15 and synergistic effect of functional groups. The impact of pH value, initial uranium concentration, temperature, and duration on uranium adsorption was investigated through a series of batch experiments. The bifunctional modified SBA-15 demonstrated rapid uranium adsorption, which was a spontaneous endothermic reaction and conformed to the pseudo-second-order model. Thereinto, SBA-15 modified with aldoxime and amino group (SBA-15-SAO-N) exhibited the best uranium adsorption performance, with a maximum adsorption capacity of 701.85 mg·g⁻¹ at 298 K and pH 6, an increase of 146 % compared to SBA-15-SAO. SBA-15-SAO-N exhibits excellent U/V selectivity (selectivity coefficient of 30) in the coexistence of U and V solutions, and it still maintains high adsorption capacity after five adsorption-desorption cycles. In actual seawater conditions, the adsorption capacity of SBA-15-SAO-N was 135.26 μg·g⁻¹. By combining DFT calculations and characterization, the coordination model and interaction energy between functional groups and uranyl were elucidated, revealing that introducing bifunctional groups can enhance the binding strength of adsorbents to uranium and form more stable complexes, thereby improving adsorption capacity and selectivity. These results indicate that bifunctional modified mesoporous silica offers a promising strategy for recovering uranium resources from seawater.

https://www.sciencedirect.com/science/article/abs/pii/S0011916424011792 

 

 

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Uranium removal from environmental water and nuclear waste: Nanomaterial solutions and their environmental sustainability

2025

Highlights

    
    Nanomaterial-based extraction methods show promise for removing uranium from a variety of aqueous streams.
    
    Nanomaterials have high adsorption capacity, dense active sites, excellent selectivity, and are easy to reuse.
    
    Carbonaceous, magnetic, functionalized, silicon-based, metallic oxide, and biological nanomaterials are discussed.
    
    The stability (chemical, thermal, and mechanical) and toxicity of nanomaterials are important concerns.
    
    The sustainability and transformation of nanomaterials in aquatic and terrestrial environments are analysed in depth.

Abstract

The separation and extraction of uranium from mining waste water, contaminated surface water and groundwater, and even from seawater hold significant importance in various applications. Nanomaterial-based extraction methods have been quickly developing and offer a promising means of removing and recovering uranium from a variety of aqueous streams. Nanomaterials possess distinct advantages such as high adsorption capacity, dense active sites, ease of reuse, and excellent selectivity. In this comprehensive review, we conduct an in-depth examination of a wide range of nanomaterials, including carbonaceous, magnetic, functionalized, silicon-based, and metallic oxide/hydroxide nanomaterials, each exhibiting diverse morphologies. Additionally, we offer detailed discussions on mixed oxides and bio-nanocomposites. Carbonaceous nanomaterials demonstrate superior chemical stability in strongly acidic nuclear wastewaters than common inorganic sorbents like hydroxyapatite and hydrous oxides. Furthermore, they are more resilient to radiation and thermal conditions than organic exchange resins. Extraction using recyclable functionalized magnetic nanomaterials offers high selectivity and reduces the complexity of the required equipment. We delve into the challenges and opportunities associated with employing nanomaterials for uranium separation, discussing them in detail. The control of their structures and the stability (chemical, thermal, and mechanical) and toxicity of nanomaterials are important concerns. Finally, we perform an in-depth analysis of the environmental sustainability of nanomaterials. These materials can enter aquatic and terrestrial environments through direct industrial discharges, wastewater effluents, surface runoff, and indirectly via land-applied products like sludges or biosolids. Once in the environment, nanomaterials undergo transformations influenced by their properties and the surrounding medium, involving processes like aggregation, dissolution, and redox reactions.

1. Introduction

Finding sustainable energy supplies poses a significant challenge for human development. Nuclear energy, as a clean and scalable source, offers a solution to the global energy problem. The urgency of addressing global warming has prompted certain countries to develop their nuclear industries, thus highlighting the potential for nuclear energy to revolutionize the global energy structure.
Scientists and Scholars on Nuclear for Climate Change, in their Open Letter to Heads of Governments of G-20 countries [13], emphasize the pressing need for rapid nuclear infrastructure development in the next 20–30 years to meet the demands of our “burning” planet. Presently, there are over 430 nuclear reactors worldwide, generating 400 GWe (Gigawatt Electrical), which accounts for 11 % of global electricity output. By 2040, it is projected that nuclear capacity will reach 516 GWe. For instance, China has set ambitious plans to construct 80 nuclear reactors by 2030 and a total of 230 reactors by 2050.

Uranium plays a crucial role in nuclear energy. Fig. 1 illustrates the fluctuation of uranium prices from 1968 to 2020. In 2007, due to increasing demand, particularly from emerging economies like India and China, uranium reached its highest recorded spot price of $140 per pound. However, the global economic crisis in 2008 resulted in a significant drop in uranium prices to below $50 per pound. In early 2011, as the world economy recovered from the financial crisis, uranium prices experienced a notable increase, reaching $75 per pound. However, following the Fukushima Daiichi incident in the same year, the shutdown of all 54 Japanese nuclear power plants caused a global collapse in uranium prices. This led to a 13 % reduction in global uranium demand. Moreover, the sale of uranium from offline Japanese nuclear power plants' inventory had a substantial impact on the uranium market, causing prices to plummet from $75 to $21 per pound. The COVID-19 pandemic in 2020 further disrupted the uranium supply from mining companies, resulting in a price surge to $34 per pound, marking the highest price in the past four years.

The International Atomic Energy Agency (IAEA) categorizes uranium resources as conventional and unconventional. Conventional resources refer to those from which uranium is extracted as the primary product, co-product, or significant by-product. Within this category, there are two main types: Reasonably Assured Resources (RAR) and Inferred Resources (IR), which can be recovered at a cost of less than $260 per kilogram of uranium (kgU). Unconventional uranium resources encompass those from which uranium is recoverable as a minor by-product. The primary unconventional source of uranium resources is phosphate rock, while other sources such as black shale, non-ferrous ore, carbonate, lignite, and seawater are less significant.

The Republic of Kazakhstan is the world's leading producer of uranium. In 2015 Kazakhstan produced 23,800 tons of uranium (tU), accounting for 39 % of global uranium production. This surpassed the combined production of the second and third largest uranium producers, Canada and Australia. It is projected that the global annual uranium requirement will increase from 67,000 to 105,000 tU by 2035. Fig. 2 provides a visual representation of global uranium production and reactor requirements from 1946 to 2015.

https://www.sciencedirect.com/science/article/pii/S1385894725011039

 

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How We Make Uranium Mining Safer and More Eco-Friendly

August 27, 2024

https://williamsheriff.com/make-uranium-mining-safer-and-more-eco-friendly/  

 

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Using Graphene Foam To Filter Uranium and Other Heavy Metals From Drinking Water

August 9, 2021

 

Some kinds of water pollution, such as algal blooms and plastics that foul rivers, lakes, and marine environments, lie in plain sight. But other contaminants are not so readily apparent, which makes their impact potentially more dangerous. Among these invisible substances is uranium. Leaching into water resources from mining operations, nuclear waste sites, or from natural subterranean deposits, the element can now be found flowing out of taps worldwide.

 

In the United States alone, “many areas are affected by uranium contamination, including the High Plains and Central Valley aquifers, which supply drinking water to 6 million people,” says Ahmed Sami Helal, a postdoc in the Department of Nuclear Science and Engineering. This contamination poses a near and present danger. “Even small concentrations are bad for human health,” says Ju Li, the Battelle Energy Alliance Professor of Nuclear Science and Engineering and professor of materials science and engineering.

 

Now, a team led by Li has devised a highly efficient method for removing uranium from drinking water. Applying an electric charge to graphene oxide foam, the researchers can capture uranium in solution, which precipitates out as a condensed solid crystal. The foam may be reused up to seven times without losing its electrochemical properties. “Within hours, our process can purify a large quantity of drinking water below the EPA limit for uranium,” says Li.

 

A paper describing this work was published in last week’s Advanced Materials. The two first co-authors are Helal and Chao Wang, a postdoc at MIT during the study, who is now with the School of Materials Science and Engineering at Tongji University, Shanghai. Researchers from Argonne National Laboratory, Taiwan’s National Chiao Tung University, and the University of Tokyo also participated in the research. The Defense Threat Reduction Agency (U.S. Department of Defense) funded later stages of this work.

 

Targeting the Contaminant

 

The project, launched three years ago, began as an effort to find better approaches to environmental cleanup of heavy metals from mining sites. To date, remediation methods for such metals as chromium, cadmium, arsenic, lead, mercury, radium, and uranium have proven limited and expensive. “These techniques are highly sensitive to organics in water, and are poor at separating out the heavy metal contaminants,” explains Helal. “So they involve long operation times, high capital costs, and at the end of extraction, generate more toxic sludge.”

 

To the team, uranium seemed a particularly attractive target. Field testing from the U.S. Geological Service and the Environmental Protection Agency (EPA) has revealed unhealthy levels of uranium moving into reservoirs and aquifers from natural rock sources in the northeastern United States, from ponds and pits storing old nuclear weapons and fuel in places like Hanford, Washington, and from mining activities located in many western states. This kind of contamination is prevalent in many other nations as well. An alarming number of these sites show uranium concentrations close to or above the EPA’s recommended ceiling of 30 parts per billion (ppb) — a level linked to kidney damage, cancer risk, and neurobehavioral changes in humans.

 

The critical challenge lay in finding a practical remediation process exclusively sensitive to uranium, capable of extracting it from solution without producing toxic residues. And while earlier research showed that electrically charged carbon fiber could filter uranium from water, the results were partial and imprecise.

 

Wang managed to crack these problems — based on her investigation of the behavior of graphene foam used for lithium-sulfur batteries. “The physical performance of this foam was unique because of its ability to attract certain chemical species to its surface,” she says. “I thought the ligands in graphene foam would work well with uranium.”

 

Simple, Efficient, and Clean

 

The team set to work transforming graphene foam into the equivalent of a uranium magnet. They learned that by sending an electric charge through the foam, splitting water and releasing hydrogen, they could increase the local pH and induce a chemical change that pulled uranium ions out of solution. The researchers found that the uranium would graft itself onto the foam’s surface, where it formed a never-before-seen crystalline uranium hydroxide. On reversal of the electric charge, the mineral, which resembles fish scales, slipped easily off the foam.

 

It took hundreds of tries to get the chemical composition and electrolysis just right. “We kept changing the functional chemical groups to get them to work correctly,” says Helal. “And the foam was initially quite fragile, tending to break into pieces, so we needed to make it stronger and more durable,” says Wang.

 

This uranium filtration process is simple, efficient, and clean, according to Li: “Each time it’s used, our foam can capture four times its own weight of uranium, and we can achieve an extraction capacity of 4,000 mg per gram, which is a major improvement over other methods,” he says. “We’ve also made a major breakthrough in reusability, because the foam can go through seven cycles without losing its extraction efficiency.” The graphene foam functions as well in seawater, where it reduces uranium concentrations from 3 parts per million to 19.9 ppb, showing that other ions in the brine do not interfere with filtration.

 

The team believes its low-cost, effective device could become a new kind of home water filter, fitting on faucets like those of commercial brands. “Some of these filters already have activated carbon, so maybe we could modify these, add low-voltage electricity to filter uranium,” says Li.

 

“The uranium extraction this device achieves is very impressive when compared to existing methods,” says Ho Jin Ryu, associate professor of nuclear and quantum engineering at the Korea Advanced Institute of Science and Technology. Ryu, who was not involved in the research, believes that the demonstration of graphene foam reusability is a “significant advance,” and that “the technology of local pH control to enhance uranium deposition will be impactful because the scientific principle can be applied more generally to heavy metal extraction from polluted water.”

 

The researchers have already begun investigating broader applications of their method. “There is a science to this, so we can modify our filters to be selective for other heavy metals such as lead, mercury, and cadmium,” says Li. He notes that radium is another significant danger for locales in the United States and elsewhere that lack resources for reliable drinking water infrastructure.

 

“In the future, instead of a passive water filter, we could be using a smart filter powered by clean electricity that turns on electrolytic action, which could extract multiple toxic metals, tell you when to regenerate the filter, and give you quality assurance about the water you’re drinking.”

 
https://scitechdaily.com/using-graphene-foam-to-filter-uranium-and-other-heavy-metals-from-drinking-water/ 

 

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Encouraging minerals to capture troubling radionuclides

 

 May 08, 2015 

 

 http://phys.org/news/2015-05-minerals-capture-radionuclides.html?utm_source=menu&utm_medium=link&utm_campaign=item-menu

 

 

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Graphene, the finest filter

 

January 5, 2016

 http://phys.org/news/2016-01-graphene-finest-filter.html#nRlv

 Graphene can simplify production of heavy water and help clean nuclear waste by filtering different isotopes of hydrogen, University of Manchester research indicates.

Writing in Science, a team led by Sir Andre Geim demonstrated that using membranes made from graphene can act as a sieve, separating protons – nuclei of hydrogen – from heavier nuclei of hydrogen isotope deuterium.

The process could mean producing heavy water for nuclear power plants could be ten times less energy intensive, simpler and cheaper using graphene.

One of the hydrogen isotopes, deuterium, is widely used in analytical and chemical tracing technologies and, also, as heavy water required in thousands of tons for operation of nuclear power stations.

The heaviest isotope, tritium, is radioactive and needs to be safely removed as a byproduct of electricity generation at nuclear fission plants. Future nuclear technology is based on fusion of the two heavy isotopes.

The current separation technologies for production of heavy water are extremely energy intensive, and have presented a major scientific and industrial problem. Now graphene promises do so efficiently.

Researchers tested whether deuterons – nuclei of deuterium – can pass through graphene and its sister material boron nitride. They fully expected deuterons to easily pass through, as existing theory did not predict any difference in permeation for both isotopes.


The researchers were surprised to find that deuterons were not only effectively sieved out by their one atom thick membranes, but were sieved with a high separation efficiency.

The discovery makes monolayers of graphene and boron nitride attractive as separation membranes to enrich mixtures of deuterium and tritium.

Furthermore, the researchers showed that the separation is fully scalable. Using chemical-vapor-deposited (CVD) graphene, they built centimetre-sized devices to effectively pump out hydrogen from a mixture of deuterium and hydrogen.

Dr Marcelo Lozada-Hidalgo, University of Manchester postdoctoral researcher and first author of the paper, said: "This is really the first membrane shown to distinguish between subatomic particles, all at room temperature.

"Now that we showed that it is a fully scalable technology, we hope it will quickly find its way to real applications."

Professor Irina Grigorieva, who co-authored the research, said: "We were stunned to see that a membrane can be used to separate subatomic particles.

"It is a really simple set up. We hope to see applications of these filters not only in analytical and chemical tracing technologies but also in helping to clean nuclear waste from radioactive tritium."

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White Graphene: The One-Atom Wonder Driving Greener Energy and Faster Tech

 

13 January 2025

Researchers at the University of Surrey have made a breakthrough in understanding how Hexagonal Boron Nitride (hBN), a 2D material, grows and forms nanostructures on metal substrates. This discovery could lead to more efficient electronics, cleaner energy solutions, and environmentally friendly chemical manufacturing.

 

Known as “white graphene,” hBN is an ultra-thin material only one atom thick. It is highly durable, capable of withstanding extreme temperatures, resisting chemical damage, and blocking electrical currents. These properties make hBN an essential material in advanced electronics, where it protects sensitive microchips and supports the development of faster, more efficient transistors.

 

The researchers have also demonstrated the creation of nanoporous hBN, a novel form of the material with tiny, structured voids. This unique structure enables selective absorption and advanced catalysis, significantly enhancing its potential for environmental applications. These include detecting and filtering pollutants, improving hydrogen storage, and serving as electrochemical catalysts for fuel cells in advanced energy systems.

 

https://www.stardrive.org/index.php/sd-science-news/70827-white-graphene-the-one-atom-wonder-driving-greener-energy-and-faster-tech

 

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Halophilic archaea as tools for bioremediation technologies

29 June 2024

Microorganisms for bioremediation

Haloarchaea as promising tools for bioremediation

https://link.springer.com/article/10.1007/s00253-024-13241-z


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Arsenic removal approaches: A focus on chitosan biosorption to conserve the water sources

 

2021

 

https://www.sciencedirect.com/science/article/abs/pii/S0141813021022029 

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Microrobots clean up radioactive waste (w/video)

  

Oct 30, 2019

(Nanowerk News) According to some experts, nuclear power holds great promise for meeting the world’s growing energy demands without generating greenhouse gases. But scientists need to find a way to remove radioactive isotopes, both from wastewater generated by nuclear power plants and from the environment in case of a spill.

Now, researchers reporting in ACS Nano ("Radioactive Uranium Preconcentration via Self-Propelled Autonomous Microrobots Based on Metal-Organic Frameworks") have developed tiny, self-propelled robots that remove radioactive uranium from simulated wastewater.

The accidental release of radioactive waste, such as what occurred in the Chernobyl and Fukushima nuclear plant disasters, poses large threats to the environment, humans and wildlife. Scientists have developed materials to capture, separate, remove and recover radioactive uranium from water, but the materials have limitations.

One of the most promising recent approaches is the use of metal-organic frameworks (MOFs) –– compounds that can trap specific substances, including radioactive uranium, within their porous structures.

Martin Pumera and colleagues wanted to add a micromotor to a rod-shaped MOF called ZIF-8 to see if it could quickly clean up radioactive waste.

To make their self-propelled microrobots, the researchers designed ZIF-8 rods with diameters about 1/15 that of a human hair. The researchers added iron atoms and iron oxide nanoparticles to stabilize the structures and make them magnetic, respectively.

Catalytic platinum nanoparticles placed at one end of each rod converted hydrogen peroxide “fuel” in the water into oxygen bubbles, which propelled the microrobots at a speed of about 60 times their own length per second. In simulated radioactive wastewater, the microrobots removed 96% of the uranium in an hour. The team collected the uranium-loaded rods with a magnet and stripped off the uranium, allowing the tiny robots to be recycled.

The self-propelled microrobots could someday help in the management and remediation of radioactive waste, the researchers say.

https://scitechdaily.com/swarms-of-microrobots-quickly-clean-up-radioactive-waste-video/


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Many have even mentioned about using genetically modified archaea (bacteria), that could eat and digest uranium, including other toxic waste. The bacteria could turn the toxic waste into a different chemical structure, this structure may not be as toxic, or could biodegrade properly. Some question if this type of bacteria could pose a threat to the environment.


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For uranium cleanup ... bacteria?

May 19, 2006

http://news.stanford.edu/news/2006/may24/criddle-052406.html

Bacteria are back

 
Bioremediation was used in the 1980s to clean up toxic organics, mainly spills of fuels and solvents. Bacteria basically ate the fuels—chomping down long-chain hydrocarbons—or they "breathed" the solvents and created nontoxic forms.
"Microorganisms also 'breathe' metals like uranium, converting it into a form that is immobile because it does not appreciably dissolve in water," said Nyman, a doctoral student whose laboratory studies helped to guide operations in the field. After microbes convert the uranium, it's "just sitting there, like a rock," Criddle said. "In future studies, we hope to see how stable we can make that 'rock.' Ideally, it will remain in that form for thousands of years."

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Scientists develop material to remove radioactive contaminants from drinking water

 

April 13, 2011 

 

A combination of forest byproducts and crustacean shells may be the key to removing radioactive materials from drinking water, researchers from North Carolina State University have found.
"As we're currently seeing in Japan, one of the major health risks posed by nuclear accidents is radioactive iodide that dissolves into drinking water. Because it is chemically identical to non-radioactive iodide, the human body cannot distinguish it – which is what allows it to accumulate in the thyroid and eventually lead to cancer," says Dr. Joel Pawlak, associate professor of forest biomaterials. "The material that we've developed binds iodide in water and traps it, which can then be properly disposed of without risk to humans or the environment."

http://phys.org/news/2011-04-scientists-material-radioactive-contaminants.html#nRlv

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Technique could set new course for extracting uranium from seawater

 

December 17, 2015

 

 An ultra-high-resolution technique used for the first time to study polymer fibers that trap uranium in seawater may cause researchers to rethink the best methods to harvest this potential fuel for nuclear reactors.

 http://phys.org/news/2015-12-technique-uranium-seawater.html

 

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TiO2 Nanoparticles Simultaneously Remove Arsenic and Uranium from Groundwater

 

March 26, 2025

 

Titanium dioxide (TiO₂) may offer a scalable, cost-effective and eco-friendly solution for water remediation.

 

https://www.technologynetworks.com/applied-sciences/news/tio2-nanoparticles-simultaneously-remove-arsenic-and-uranium-from-groundwater-397700

 

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Enhanced uranium extraction from seawater using bifunctional-modified molecular sieves with high selectivity and adsorption capacity

2025

https://www.sciencedirect.com/science/article/abs/pii/S0011916424011792

 

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Using Graphene Foam To Filter Uranium and Other Heavy Metals From Drinking Water

 

August 9, 2021

 

MIT-led research team fashions graphene foam into device that can extract uranium and other heavy metals from tap water.

https://scitechdaily.com/using-graphene-foam-to-filter-uranium-and-other-heavy-metals-from-drinking-water/

 

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Some people think that this technology could be useful to cleanup excess uranium from water and ocean water. 

We even have the medical technology in order to treat radiation sickness. This technology could also become beneficial for cancer patients.

 
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FDA ticks off first drug to treat radiation sickness after nuclear disasters

May 25, 2015

http://www.gizmag.com/fda-drug-radiation-nuclear/37671/




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Metal foams could provide lightweight radiation shielding

 

• July 22, 2015

 Radiation generally comes under the heading of "things you want to stay away from," so it's no surprise that radiation shielding is a high priority in many industries. However, current shielding is bulky and heavy, so a North Carolina State University team is developing a new lightweight shielding based on foam metals that can block X-rays, gamma rays, and neutron radiation, as well as withstanding high-energy impact collisions.

http://www.gizmag.com/metal-foam-lightweight-radiation-shielding/38515/?li_source=LI&li_medium=default-widget

 
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New Material Selenomelanin Offers Extreme Radiation Shielding

Aug 17, 2020

https://www.youtube.com/watch?v=I50EEKzrOd4

 

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Researchers awarded patent for tokamak device, would turn nuclear waste into fuel

September 13, 2012

 University of Texas at Austin physicists have been awarded a U.S. patent for an invention that could someday be used to turn nuclear waste into fuel, thus removing the most dangerous forms of waste from the fuel cycle.

The researchers—Mike Kotschenreuther, Prashant Valanju and Swadesh Mahajan of the College of Natural Sciences—have patented the concept for a novel fusion-fission hybrid nuclear reactor that would use nuclear fusion and fission together to incinerate nuclear waste. Fusion produces energy by fusing atomic nuclei, and fission produces energy by splitting atomic nuclei.

The process of burning the waste would also produce energy. The researchers' goal is to eliminate 99 percent of the most toxic transuranic waste from nuclear fission reactors.

"The potential for this kind of technology is enormous," said Mahajan, professor of physics. "Now that we have the patent, we hope this will open up opportunities to engage with the research and development community to further this potentially world-changing technology."

The researchers' patent covers a tokamak device, which uses magnetic fields to produce fusion reactions. The patented tokamak is surrounded by an area that would house a nuclear waste fuel source and waste by-products of the nuclear fuel cycle. The device is driven by a transformational technology called the Super X Divertor.

The Super X Divertor is a crucial technology that has the capacity to safely divert the enormous amounts of heat out of the reactor core to keep the reactor producing energy.

Toxic nuclear waste is stored at sites around the U.S., and the need to store nuclear waste is widely considered to be a major disadvantage associated with nuclear energy.

The physicists' invention could someday drastically decrease the need for any additional or expanded geological repositories, making nuclear power cleaner and more viable.

The patented hybrid reactor is currently in a conceptual phase.

The Super X Divertor, however, is being installed as the centerpiece of a $40 million upgrade of the MAST tokamak in the United Kingdom. This installation is a critical step forward in testing the Super X Divertor experimentally. It is not covered by the U.S. patent but is the technology invented by the University of Texas at Austin physicists.

 http://phys.org/news/2012-09-awarded-patent-tokamak-device-nuclear.html#nRlv




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Nuclear ‘Power Balls’ May Make Meltdowns a Thing of the Past


06.30.2020

Triso particles are an alien-looking fuel with built-in safety features that will power a new generation of high-temperature reactors.

https://www.wired.com/story/nuclear-power-balls-triso-fuel/?utm_source=pocket-newtab


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The new, safer nuclear reactors that might help stop climate change

Feb 27. 2019

From sodium-cooled fission to advanced fusion, a fresh generation of projects hopes to rekindle trust in nuclear energy.

https://www.technologyreview.com/s/612940/the-new-safer-nuclear-reactors-that-might-help-stop-climate-change/


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Have Physicists Found the Key to Safer Nuclear Power?

Aug 2017

Unlike the uranium commonly used to power nuclear reactors, thorium salts are protected against meltdowns and can’t be weaponized.

https://www.nbcnews.com/mach/science/have-physicists-found-key-safer-nuclear-power-ncna796616

 

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Chemical looping turns environmental waste into fuel

January 29, 2025

 

 
Turning environmental waste into useful chemical resources could solve many of the inevitable challenges of our growing amounts of discarded plastics, paper and food waste, according to new research.

In a significant breakthrough, researchers from The Ohio State University have developed a technology to transform materials like plastics and agricultural waste into syngas, a substance most often used to create chemicals and fuels like formaldehyde and methanol.

https://techxplore.com/news/2025-01-chemical-looping-environmental-fuel.html

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Water filter with nanoscale channels selectively removes stubborn 'forever chemicals'

April 8, 2025

https://phys.org/news/2025-04-filter-nanoscale-channels-stubborn-chemicals.html

 

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We have the technology to use good biopolymers and bioplastics.
We have the technology to make organic computing crystals for computers.
We can make non-toxic fibers, alloys, paints, dyes and lubricants.
We can make and grow our food to be non-toxic, and sustainable as well.
We could make all parts of a vehicle sustainable, this includes the energy used in a vehicle.  


Some people question many of the practices used in current mining techniques for mining metals, minerals and alloys. This is why some people think that plant based materials, or different materials such as silicone, could be more environmentally friendly for fibers. We need to properly recycle and reuse the metals, minerals and alloys that have already been mined and produced on the planet. However, there will always be a need for new scientific experiments with rare metals and minerals. 

 
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Chapter 35: Adhesives

 

 

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Latest adhesive and sealant news

 

https://www.specialchem.com/adhesives/all-news

 

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Scientists stick materials together without using glue — just electricity

 

March 14, 2024

 

 Researchers at the University of Maryland have devised a novel method of binding materials together without the need for traditional adhesives. Rather than glue, this technique harnesses the power of electricity. By applying a small voltage, the researchers showed it’s possible to securely join hard and soft objects together. This non-stick method has the added advantage of being completely reversible. By reversing the direction of the electron flow, the two objects are easily and immediately separated. 

 

It's an electric twist to material bonding. Plus, it's completely reversible at the push of a button. 

 

https://www.zmescience.com/science/news-science/material-bonding-electricity/ 

 

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Electroadhesion: The Magic of Making Materials Stick Without Glue

 

July 21, 2024

  

A novel electroadhesion process allows for the easy and reversible attachment of hydrogels to metals using electricity, effective on a variety of materials from food to metals.

 

How would you stick a slice of banana to a sheet of copper? Until a few months ago, you couldn’t. But a new discovery called “hard-soft electroadhesion” enables chemists to stick almost any hydrogel to almost any metal, using nothing but an electric current. And you can unstick the materials simply by reversing the current.

 

Recently reported in ACS Central Science, this astonishingly general phenomenon works with a wide variety of gels (including fruits, vegetables, meat, and fish) and conductors (including metals and graphite). Join our host George as he attempts to replicate electroadhesion in his basement and tries to discover what — if anything — this remarkable phenomenon shares with super glue.

 
https://scitechdaily.com/electroadhesion-the-magic-of-making-materials-stick-without-glue-video/

 

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Researchers Realize Rapid Synthesis of Gold Microsphere Array for Advanced Packaging

Nov 12, 2024

 

As electronic devices get smaller, it's becoming harder to achieve high-quality connections that are both reliable and safe from short circuits. Researchers developed the array-ACF (anisotropic conductive adhesives film) using metal-coated polymer microsphere arrays to make these connections years ago, but the bond between the metal and polymer could crack under pressure, affecting its performance.

 

Now, a collaborated team led by researchers from Hefei Institutes of Physical Science of the Chinese Academy of Sciences, enables efficient construction of gold microsphere array-based anisotropic conductive adhesives film (ACF) for advanced packaging. 

 

The research findings were published in Nature Communications.

 

In their study, the researchers developed a new approach to fabricate pure gold microsphere arrays within one minute through a positioned self-assembly and laser-irradiated ripening strategy. This technique relies on a rapid layer-by-layer laser-induced melting and fusion process, effectively avoiding the anisotropic growth principle.

 

The fundamental advantage of this strategy lies on the formed size of gold microsphere determined by the initial templating microholes and precisely positioned within them. This not only facilitates precise control but also ensures compatibility with lithography techniques in the industry.

 

The technique is also flexible and can be used to create different kinds of microspheres, including alloy microspheres made from gold and other metals. When these microspheres are treated with laser, they fuse together smoothly, creating stable and durable materials.

 

Compared to commercial gold-plated microspheres, the pure gold microspheres are much more flexible and resistant to electrical problems under pressure. These gold microsphere arrays could help improve the bonding of micro-displays, like those used in μLED chips, which are key to creating high-resolution displays.

 

https://english.cas.cn/newsroom/research_news/phys/202411/t20241113_694177.shtml

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Inspired by Fly Feet: New Adhesive Structure Capable of Repeated Attachment and Detachment

 

August 30, 2020

 

 

Electron micrograph of the fly foot. The adhesive spatula-shaped setae (light-blue structures) allow the fly to attach itself to objects.

 

Recycle-compatible, environmentally friendly technology inspired by footpad formation mechanism during fly’s pupal metamorphosis.

 

NIMS, HUE, and HUSM have succeeded in developing a method of easily and cheaply producing an adhesive structure capable of repeated attachment and detachment. The design of this structure was inspired by the adhesive spatula-shaped hairs (setae) found on the footpads of flies, while the method of producing it was hinted at by seta formation in fly pupae. These environmentally sound technologies could potentially contribute to a more sustainable society.

 

Many types of manufactured products are reinforced with strong adhesives. However, the use of these adhesives hampers recycling processes (i.e., sorting and decomposition), countering efforts to promote a circular economy. For this reason, adhesive technologies capable of repeated attachment and detachment have been designed and developed. The biomimetic approach to the development of high-performance adhesive technologies seeks to imitate elaborate adhesive structures found in living organisms. However, this approach is frequently costly as it requires the use of MEMS (microelectromechanical systems) to create complex structures.

 
https://scitechdaily.com/inspired-by-fly-feet-new-adhesive-structure-capable-of-repeated-attachment-and-detachment/

 

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Spider Silk-Inspired Bio-Based Adhesive: Robust Adhesion Strength, Exceptional Flame Retardancy, and Full Recyclability

 

April 27, 2025 

 

https://pubs.acs.org/doi/10.1021/acsmaterialslett.5c00388 

 

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Weird Spider Hair Discovery May Inspire Powerful – Yet Reversible – Adhesives

 

June 18, 2021

 

Engineers Impressed by the Functional Great Diversity of Hairs on Spider Legs

 

Just how do spiders walk straight up — and even upside-down across — so many different types of surfaces? Answering this question could open up new opportunities for creating powerful, yet reversible, bioinspired adhesives. Scientists have been working to better understand spider feet for the past several decades. Now, a new study in Frontiers in Mechanical Engineering is the first to show that the characteristics of the hair-like structures that form the adhesive feet of one species — the wandering spider Cupiennius salei — are more variable than previously thought.

 

Different Types of Hair Work Together

 

Unexpectedly, each hair showed unique adhesive properties. When the team looked at the hairs under a powerful microscope, they also found that each one showed clearly different — and previously unrecognized — structural arrangements. The team believes that this variety may be key to how spiders can climb so many surface types.

 

This current work studied only a small number of the thousands of hairs on each foot, and it’s beyond the scope of existing resources to consider studying them all. But the team expects that not all of the hairs are unique, and that it might be possible to find clusters or repeating patterns instead.

 

Bioinspired Applications Possible

 

“Although it is still very difficult to fabricate nanostructures like those of the spider — and especially to achieve the stability and reliability of the natural materials — our findings can further optimize existing models for reversible and residue-free artificial adhesives,” says Schaber. “The principle of different shapes and alignments of adhesive contacts as found in the spider attachment system can improve the attachment ability of bioinspired materials to a broad range of substrates with different properties.”

https://scitechdaily.com/weird-spider-hair-discovery-may-inspire-powerful-yet-reversible-adhesives/

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Gecko-Inspired Controllable Adhesive: Structure, Fabrication, and Application

1 March 2024

https://www.mdpi.com/2313-7673/9/3/149

 

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Researchers explore biomimetic approach for making adhesives tougher

03/04/2020

A team from Purdue University takes inspiration from sea creatures to produce stronger adhesives with weaker bonds.

https://www.compositesworld.com/news/researchers-explore-biomimetic-approach-for-making-adhesives-tougher

 

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Henkel, Synthomer partner to cut carbon emissions in adhesives

05/02/2025

Integration of Synthomer Clima resins into Henkel Technomelt hot-melt adhesive portfolio targets significant Scope 3 GHG emissions reductions for electronics, automotive, comsumer and composites customers.

https://www.compositesworld.com/news/henkel-synthomer-partner-to-cut-carbon-emissions-in-adhesives

 

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Joint venture strengthens Bostik instant engineering adhesives business

01/22/2021

Investment in Crackless Monomer Co. accelerates development and production of specialty cyanoacrylate monomers on an industrial scale.

https://www.compositesworld.com/news/joint-venture-strengthens-bostik-instant-engineering-adhesives-business-

 
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BioBond launches two plant-based HMAs for packaging applications

 

 Aug 4, 2025

 

https://www.specialchem.com/adhesives/news/biobond-launches-two-plant-based-hmas-for-packaging-applications 

 

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Henkel advances sustainable packaging with resource-efficient solutions

 Aug 4, 2025

 

https://www.specialchem.com/adhesives/news/henkel-advances-sustainable-packaging-with-resource-efficient-solutions 

 

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Fedrigoni introduces solvent-based acrylic adhesives for pharma labeling

 

Aug 5, 2025

 

https://www.specialchem.com/adhesives/news/fedrigoni-introduces-solvent-based-acrylic-adhesives-for-pharma-labeling  

 

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Evonik shifts epoxy curing agent plants to 100% green electricity

 

 Aug 1, 2025

 

https://www.specialchem.com/adhesives/news/evonik-shifts-epoxy-curing-agent-plants-to-100-green-electricity 

 

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Making Natural Glue From Pine Resin

 

Jun 18, 2024

 

https://trailtrektribe.com/making-natural-glue-from-pine-resin/ 

 

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Some have even mentioned the use of genetically modified plants, bacteria and hydrogen that could act as solar energy harvesters. We have seen many unsafe experiments with genetically modified organisms. This includes the use of genetically modified organisms which can survive in outer space.

To continue this discussion, view our book titled " 'Energy Science 101.  - ( Pollution Science 101 )."  -  http://EnergyScience101.blogspot.com   ." We have taken some information from our energy science book and added the information to our Pollution Science 101 - Solutions book.

Here is a preview of the following subjects and chapters of the new book " 'Energy Science 101.  - ( Pollution Science 101 )."  -  http://EnergyScience101.blogspot.com   ."


Chapter 1: Tesla
Chapter 2: CERN
Chapter 3: Antimatter
Chapter 4: Plasma energy 
Chapter 5: Fusion
Chapter 6: Dark Energy   
Chapter 7: Batteries & energy storage
Chapter 8: Magnetic energy
Chapter 9: Piezoelectric & mechanical energy
Chapter 10: Lazers


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