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"Researchers from the University of Houston have reported a new theory in physics called stress localization, which they used to tune and predict the properties of new materials," reports Phys.Org. "Based on those predictions, the researchers reported in Materials Horizons that they have created a durable silicone polymer coating capable of repelling ice from any surface." The new research has huge implications for aircraft, power transmission lines, and more. From the report: Hadi Ghasemi, Bill D. Cook Assistant Professor of mechanical engineering at UH and corresponding author for the work, said the findings suggest a way to take trial and error out of the search for new materials, in keeping with the movement of materials science toward a physics-driven approach. "You put in the properties you want, and the principle will tell you what material you need to synthesize," he said, noting that the concept can also be used to predict materials with superb antibacterial or other desirable properties.

The new material uses elastic energy localization where ice meets the material, triggering cracks at the interface that slough off the ice. Ghasemi said it requires minimal force to cause the cracks; the flow of air over the surface of an airplane acts as a trigger, for example. The material, which is applied as a spray, can be used on any surface, and Ghasemi said testing showed it is not only mechanically durable and unaffected by ultraviolet rays -- important for aircraft which face constant sun exposure -- but also does not change the aircraft's aerodynamic performance. Testing indicates it will last for more than 10 years, with no need to reapply, he said.

Zheng Chen, a 31-year-old nanoengineer at UC San Diego, says he has developed a way to recycle used cathodes from spent lithium-ion batteries and restore them to a like-new condition. The cathodes in some lithium-ion batteries are made of metal oxides that contain cobalt, a metal found in finite supplies and concentrated in one of the world's more precarious countries. Los Angeles Times reports how it works: The process takes degraded particles from the cathodes found in a used lithium-ion battery. The particles are then pressurized in a hot alkaline solution that contains lithium salt. Later, the particles go through a short heat-treating process called annealing, in which temperatures reach more than 1,400 degrees Fahrenheit. After cooling, Chen's team takes the regenerated particles and makes new cathodes. They then test the cathodes in batteries made in the lab. The new cathodes have been able to maintain the same charging time, storage capacity and battery lifetime as the originals did. Details of the recycling method were recently published in the research journal Green Chemistry, submitted by Chen and two colleagues.

An anonymous reader writes: The Guardian reports of a recent paper, published in the journal Energy and Environmental Science, that helps explain how wind and solar energy can power most of the United States: "The authors analyzed 36 years of hourly weather data (1980-2015) in the U.S. They calculated the available wind and solar power over this time period and also included the electrical demand in the U.S. and its variation throughout the year. With this information, the researchers considered two scenarios. In scenario 1, they imagined wind and solar installations that would be sufficient to supply 100% of the U.S. electrical needs. In the second scenario, the installations would be over-designed; capable of providing 150% of the total U.S. electrical need. But the authors recognize that just because a solar panel or a wind turbine can provide all our energy, it doesn't mean that will happen in reality. It goes back to the prior discussion that sometimes the wind just doesn't blow, and sometimes the sun isn't shining. With these two scenarios, the authors then considered different mixes of power, from all solar to all wind. They also included the effect of aggregation area, that is, what sized regions are used to generate power. Is your power coming from wind and solar in your neighborhood, your city, your state or your region?

The authors found that with 100% power capacity and no mechanism to store energy, a wind-heavy portfolio is best (about 75% wind, 25% solar) and using large aggregate regions is optimal. It is possible to supply about 75-80% of U.S. electrical needs. If the system were designed with excess capacity (the 150% case), the U.S. could meet about 90% of its needs with wind and solar power. The authors modified their study to allow up to 12 hours of US energy storage. They then found that the 100% capacity system fared even better (about 90% of the country's energy) and the optimal balance was now more solar (approximately 70% solar and 30% wind). For the over-capacity system, the authors found that virtually all the country's power needs could be met with wind, solar, and storage."

At the 254th National Meeting and Exposition of the American Chemical Society, researchers are presenting a low-cost, portable, paper-based sensor that can let you know when to toss food and cosmetics. The sensor can detect antioxidants in tea and wine, and be used to explore remote locations, such as the Amazon rainforest, in search of natural sources of antioxidants. "I've always been interested in developing technologies that are accessible to both industry and the general population," Silvana Andreescu, Ph.D., says. "My lab has built a versatile sensing platform that incorporates all the needed reagents for detection in a piece of paper. At the same time, it is adaptable to different targets, including food contaminants, antioxidants and free radicals that indicate spoilage." Phys.Org reports: What sets Andreescu's sensors apart from others, she says, are the nanostructures they use to catch and bind to compounds they're looking for. "Most people working on similar sensors use solutions that migrate on channels," Andreescu says. "We use stable, inorganic particles that are redox active. When they interact with the substances we want to detect, they change color, and the intensity of the change tells us how concentrated the analyte is." Additionally, because all of the reagents needed to operate the device are incorporated in the paper, users don't need to add anything other than the sample being tested. The American Chemical Society has published a video detailing the sensor. Their paper has been published in the journal Analyst.

Earlier this month, a research team led by John Goodenough announced that they had created a new fast charging solid-state battery that can operate in extreme temperatures and store five to ten times as much energy as current standard lithium-ion batteries. The announcement was big enough to have Google's Eric Schmidt tweeting about it. However, there are some skeptics, including other leading battery researchers. "For his invention to work as described, they say, it would probably have to abandon the laws of thermodynamics, which say perpetual motion is not possible," reports Quartz. "The law has been a fundamental of batteries for more than a century and a half." Quartz reports: Goodenough's long career has defined the modern battery industry. Researchers assume that his measurements are exact. But no one outside of Goodenough's own group appears to understand his new concept. The battery community is loath to openly challenge the paper, but some come close. "If anyone but Goodenough published this, I would be, well, it's hard to find a polite word," Daniel Steingart, a professor at Princeton, told Quartz. Goodenough did not respond to emails. But in a statement released by the University of Texas, where he holds an engineering chair, he said, "We believe our discovery solves many of the problems that are inherent in today's batteries. Cost, safety, energy density, rates of charge and discharge and cycle life are critical for battery-driven cars to be more widely adopted." In addition, Helena Braga, the paper's lead author, in an exchange of emails, insisted that the team's claims are valid. For almost four decades, Goodenough has dominated the world of advanced batteries. If anyone could finally make the breakthrough that allows for cheap, stored electricity in cars and on the grid, it would figure to be him. Goodenough invented the heart of the battery that is all but certainly powering the device on which you are reading this. It's the lithium-cobalt-oxide cathode, invented in 1980 and introduced for sale by Sony in 1991. Again and again, Goodenough's lab has emerged with dramatic discoveries confirming his genius. It's what is not stated in the paper that has some of the battery community stumped. How is Goodenough's new invention storing any energy at all? The known rules of physics state that, to derive energy, differing material must produce differing eletro-chemical reactions in the two opposing electrodes. That difference produces voltage, allowing energy to be stored. But Goodenough's battery has pure metallic lithium or sodium on both sides. Therefore, the voltage should be zero, with no energy produced, battery researchers told Quartz. Goodenough reports energy densities multiple times that of current lithium-ion batteries. Where does the energy come from, if not the electrode reactions? That goes unexplained in the paper.

Seth Darling and his colleagues at Argonne National Laboratory in Illinois have created a new material that can absorb up to 90 times its own weight in spilled oil and then be squeezed out like a sponge and reused. This is compared to most commercial products used for soaking up oil, called "sorbents," which act like a paper towel and are only good for a single use. Once the sorbents are used, they get incinerated along with the oil. New Scientist reports: The oil sponge consists of a simple foam made of polyurethane or polyimide plastics and coated with "oil-loving" silane molecules with a sweet spot for capturing oil. Too little chemical attraction would render the sponge useless as an absorber, whereas too much would mean the oil could not be released. In laboratory tests, the researchers found that when engineered with just the right amount of silane, their foam could repeatedly soak up and release oil with no significant changes in capacity. But to determine whether this material could help sort out a big spill in marine waters, they needed to perform a special large-scale test. To do this, the team made an array of square pads of the sponge material measuring around 6 square meters. "We made a lot of the foam, and then these pieces of foam were placed inside mesh bags -- basically laundry bags, with sewn channels to house the foam," Darling says. The researchers suspended their sponge-filled bags from a bridge over a large pool specially designed for practicing emergency responses to oil spills. They then dragged the sponges behind a pipe spewing crude oil to test the material's capability to remove oil from the water. They next sent the sponges through a wringer to remove the oil and then repeated the process, carrying out many tests over multiple days. This so-far unpublished test was conducted in early December at the National Oil Spill Response Research and Renewable Energy Test Facility in Leonardo, New Jersey. Here's a video showing the sponge in action.

A research team led by John Goodenough at the Cockrell School of Engineering (Yes, this is a legitimate story) has created a new fast charging solid-state battery. Decades ago, American physicist John Goodenough co-invented the lithium-ion battery, which is now omnipresent in today's technology. The team has published a research paper in the journal Energy and Environmental Science. Fossbytes reports: The design limitations of lithium batteries containing liquid electrolytes don't allow them to charge quickly. If done forcefully, it would lead to the formation of metal whiskers (dendrites). Eventually, a short circuit would happen, or the battery would explode. However, that's not the problem with the solid-state batteries. The researchers have used a solid glass electrolyte in place of the liquid one. The glass electrolyte allows the researchers to use the alkali metal anode (negative side) which increases the charge density of the battery and prevents the formation of dendrites. Also, the glass electrolyte enables a battery to operate in extreme temperatures of -20-degree celsius. You can read more via The University of Texas at Austin.

Mal-2 writes: An international group of scientists from Russia, France, and Germany have developed ion-exchange synthetic membranes based on amphiphilic compounds that are able to convert the energy of chemical reactions into electrical current. The new development described in the journal Physical Chemistry, Chemical Physics could potentially be used in fuel cells, and in separation and purification processes (abstract).

The molecules in question, with the working names A-Na and Azo-Na, are promising substances that are classified as benzenesulfonates. They are wedge-shaped and can independently assemble themselves into supramolecular structures — complex organized groups of multiple molecules. Depending on the conditions set by the scientists, the molecules form discs, which, in turn, form columns with ion channels inside.

Many people are convicted in American courts on the basis of drug lab analysis. Just how accurate or accountable are the people and labs? schwit1 writes with an excerpt that gives a good reminder of how people can land in jail based on fake data, with the example (an outlier, surely) of Annie Dookhan, a chemist who worked at a Massachusetts state lab drug. Dookhan was sentenced in 2013 to at least three years in prison, after pleading guilty in 2012 to having falsified thousands of drug tests. Among her extracurricular crime lab activities, Dookhan failed to properly test drug samples before declaring them positive, mixed up samples to create positive tests, forged signatures, and lied about her own credentials. Over her nine-year career, Dookhan tested about 60,000 samples involved in roughly 34,000 criminal cases. Three years later, the state of Massachusetts still can't figure out how to repair the damage she wrought almost single-handedly.

hypnosec writes: A novel technique of detecting cocaine abuse through a simple fingerprint has been developed by researchers from the UK and the Netherlands, paving the way for a secure, non-invasive drug detection method. The research, led by University of Surrey and published in the journal Analyst, demonstrates for the first time that cocaine can be detected by the excreted metabolites – benzoylecgonine and methylecgonine – resulting from abuse of the drug. These chemicals are found in fingerprint residue, which the researchers detect using analytical chemistry technique known as ambient mass spectrometry.

Taco Cowboy writes: Neonicotinoids are a class of neuro-active insecticides chemically similar to nicotine. Neonicotinoids kill insects by overwhelming and short-circuiting their central nervous systems (PDF). Shell and Bayer started the development of neonicotinoids back in the 1980s and 1990s. Since this new group of pesticides came to market, the bee population has been devastated in regions where they have been widely used. Studies from 2012 linked neonicotinoid use to crashing bee populations.

New studies, however, have discovered that bees prefer nectar laced with neonicotinoids over nectar free of any trace of neonicotinoids. According to researchers at Newcastle University, the bees may "get a buzz" from the nicotine-like chemicals in the same way smokers crave cigarettes.

HughPickens.com writes Much of what we buy never makes it out of the container and is instead thrown away — up to a quarter of skin lotion, 16 percent of laundry detergent and 15 percent of condiments like mustard and ketchup. Now Kenneth Chang reports at the NYT that scientists have just solved one of life's little problems — how to get that last little bit of ketchup (or glue) out of a bottle. Using a coating that makes the inside of the bottle permanently wet and slippery, glue quickly slides to the nozzle or back down to the bottom. The technology could have major environmental payoffs by reducing waste. Superhydrophobic surfaces work similar to air hockey tables. Tiny peaks and valleys on the surface create a thin layer of air between the liquid and the coating. The air decreases friction, so the liquid almost levitates above the surface, just like the hockey puck floats above the table. LiquiGlide's approach is similar, but it uses a liquid lubricant, not a gas. "What could be a solution that provides sort of universal slipperiness?" says Dr. Varanasi. "The idea we had was, Why not think about trapping a liquid in these features?" Dr. Varanasi and Mr. Smith worked out a theory to predict interactions among the surface, the lubricant and air. Essentially, the lubricant binds more strongly to the textured surface than to the liquid, and that allows the liquid to slide on a layer of lubricant instead of being pinned against the surface, and the textured surface keeps the lubricant from slipping out. "We're not defying physics, but effectively, we are," says Smith.

TechkNighT_1337 writes: Chinese scientists made calculations and predict that a new 2D allotrope of carbon based in a pentagonal form resembling a common pavement in the streets of Cairo can be synthesized. They call this new form penta-graphene. From the announcement in the Chemistry World, they say: "The team found that not only should a pentagon-containing version of graphene be fairly stable, it should also be stronger than conventional graphene and be able to withstand higher temperatures, up to 730C. It would also be a natural semiconductor, unlike conventional graphene, which is a highly efficient conductor and has to be chemically modified to turn it into a semiconductor."

The Royal Society of Chemistry reports that U.S. researchers Edwin Thomas and Jae-Hwang Lee have been testing the strength of graphene mesh in one role it's probably destined to appear in down the road: as ballistic shielding material. From the article: We cannot use conventional techniques such as a gun barrel or gunpowder [on this scale],’ explains Lee. ‘Instead we used a laser to accelerate a microscale silica bullet [at the multilayer graphene target].’ The bullet was propelled into stacked graphene sheets at supersonic speeds of up to 2000mph by the gases produced by laser pulses rapidly evaporating a gold film. The team calculated the energy difference of the bullet before and after to determine the energy absorbed. Neil Bourne, director of the National Centre for Matter under Extreme Conditions in the UK, who was not involved in the research, described the technique as ‘very exciting’. ‘They have taken a standard laboratory ballistics configuration and demonstrated its utility on microscopic scales,’ he says. Graphene was able to absorb up to 0.92MJ/kg of ballistic energy in the test, with cracks forming around the impact zone. By comparison, steel targets only absorbed up to 0.08MJ/kg at the same speed.

Zothecula writes: For all the attention graphene gets thanks to its impressive list of properties, how many of us have actually encountered it in anything other than its raw graphite form? Show of hands. No-one? That's because it is still difficult to mass-produce without introducing defects. Now a team at the Korea Institute of Science and Technology has developed a graphene substitute from plastic that offers the benefits of graphene for use in solar cells and semiconductor chips, but is easy to mass-produce (abstract).

aarondubrow writes: "Graphene, a one-atom-thick form of the carbon material graphite, is strong, light, nearly transparent and an excellent conductor of electricity and heat, but a number of practical challenges must be overcome before it can emerge as a replacement for silicon in electronics or energy devices. One particular challenge concerns the question of how graphene diffuses heat, in the form of phonons. Thermal conductivity is critical in electronics, especially as components shrink to the nanoscale. Using the Stampede supercomputer at the Texas Advanced Computing Center, Professor Li Shi simulated how phonons (heat-carrying vibrations in solids) scatter as a function of the thickness of the graphene layers. He also investigated how graphene interacts with substrate materials and how phonon scattering can be controlled. The results were published in the Proceedings of the National Academy of Sciences, Applied Physical Letters and Energy and Environmental Science."

dryriver sends this quote from Phys.org: "Harvesting waste heat from power stations and even vehicle exhaust pipes could soon provide a valuable supply of electricity. A small team of Monash University researchers ... has developed an ionic liquid-based thermocell (abstract). Thermocell technology is based on harnessing the thermal energy from the difference in temperature between two surfaces and converting that energy into electricity. The new thermocell could be used to generate electricity from low grade steam in coal fired power stations at temperatures around 130C. This would be implemented by having the steam pass over the outer surface of the hot electrode to keep it hot while the other electrode is air or water cooled."

New submitter countach44 writes "From an article in IEEE's Spectrum magazine: 'Upon closer consideration, moving from petroleum-fueled vehicles to electric cars begins to look more and more like shifting from one brand of cigarettes to another. We wouldn't expect doctors to endorse such a thing. Should environmentally minded people really revere electric cars?' The author discusses the controversy and social issues behind electric car research and demonstrates what many of us have been thinking: are electric cars really more environmentally friendly than those based on internal combustion engines?" Reader Jah-Wren Ryel takes issue with one of the sources, and offers a criticism from Fast Company.

cylonlover writes "Millions of years have evolution has resulted in plants being the most efficient harvesters of solar energy on the planet. Much research is underway into ways to artificially mimic photosynthesis in devices like artificial leaves, but researchers at the University of Georgia are working on a different approach that gives new meaning to the term 'power plant.' Their technology harvests energy generated through photosynthesis before the plants can make use of it (abstract), allowing the energy to instead be used to run low-powered electrical devices."

An anonymous reader writes "A team of MIT researchers has come up with a very different approach to solar collectors: building cubes and towers that extend solar cells upward in three-dimensional configurations. The results from the structures they've tested show power output ranging from double to more than 20 times that of fixed flat panels with the same base area (abstract, full pre-print). The biggest boosts in power were seen in the situations where improvements are most needed: in locations far from the equator, in winter months and on cloudier days."

An anonymous reader sends this excerpt from IEEE Spectrum's Nanoclast blog: "One of the fundamental problems with fuel cells has been the cost of producing hydrogen. While hydrogen is, of course, the most abundant element, it attaches itself to other elements like nitrogen or fluorine, and perhaps most ubiquitously to oxygen to create the water molecule. ... Now researchers at University of California, San Diego have developed a quite different approach to mimicking photosynthesis for splitting water molecules by using a 3D branched nanowire array that looks like a forest of trees. ... The nanowire forest [uses] the process of photoelectrochemical water-splitting to produce hydrogen gas. The method used by the researchers, which was published in the journal Nanoscale (abstract), found that the forest structure of the nanowires, which has a massive amount of surface area, not only captured more light than flat planar designs, but also produced more hydrogen gas."

Hugh Pickens writes "Dr. Jeffrey H. Toney writes that a team of biomedical engineers at the University of Pittsburgh led by Henry Zeringue have managed to grow an active brain in a dish, complete with memories by culturing brain cells capable of forming networks, complete with biological signals. To produce the models, the Pitt team stamped adhesive proteins onto silicon discs. Once the proteins were cultured and dried, cultured hippocampus cells from embryonic rats were fused to the proteins and then given time to grow and connect to form a natural network. The researchers disabled the cells' inhibitory response and excited the neurons with an electrical pulse which were then able to sustain the resulting burst of network activity for up to what in neuronal time is 12 long seconds compared to the natural duration of .25 seconds. The ability of the brain to hold information 'online' long after an initiating stimulus is a hallmark of brain areas such as the prefrontal cortex. The team will next work to understand the underlying factors that govern network communication and stimulation, such as the various electrical pathways between cells and the genetic makeup of individual cells. 'This is amazing,' writes Toney. 'I wonder what the "memory" could be — could be a good subject for a science fiction story.'"

Rhodin writes "Fullerenes, also known as buckminsterfullerenes or 'buckyballs,' were detected about 6,500 light years from Earth in the cosmic dust of Tc 1 (PDF; abstract), an object known as a planetary nebula. 'We found what are now the largest molecules known to exist in space,' said astronomer Jan Cami of the University of Western Ontario, Canada, and the SETI Institute in Mountain View, Calif. 'We are particularly excited because they have unique properties that make them important players for all sorts of physical and chemical processes going on in space.'" (More, below.) These results hark directly back to the experiments that originally identified Buckminsterfullerene, which mimicked the outer atmospheric chemistry of red giant carbon stars. Harry Kroto, who jointly won a Nobel Prize for this discovery in 1996, is excited by the findings' clarity. 'The spectrum is incredibly convincing,' the Florida State University academic said. 'I thought I would never be as convinced as I am. The fact that the four lines are there, and C70 is there, is just unbelievable. It's a spectacular paper.'"

ccktech writes "As reported by NPR and Chemistry world, the journal Science has a paper by David Ehre, Etay Lavert, Meir Lahav, and Igor Lubomirsky [note: abstract online; payment required to read the full paper] of Israel's Weizmann Institute, who have figured out a way to freeze pure water by warming it up. The trick is that pure water has different freezing points depending on the electrical charge of the surface it resides on. They found out that a negatively charged surface causes water to freeze at a lower temperature than a positively charged surface. By putting water on the pyroelectric material Lithium Tantalate, which has a negative charge when cooler but a positive change when warmer; water would remain a liquid down to -17 degrees C., and then freeze when the substrate and water were warmed up and the charge changed to positive, where water freezes at -7 degrees C."

AshokaTECH writes "A piece of plastic tubing is taped to an egg beater as replacement for expensive high tech equipment that is used to separate blood into different components that can be tested. From the article, 'The cheap, portable and readily-available egg beater can be used at the point of care, meaning that health workers can diagnose illness in remote areas. The technique also uses smaller volumes of blood than regular centrifuges.'"

iandoh passes along the news that researchers at Stanford University have completed the first quantitative, scientific comparison of alternative energy solutions by assessing not only their potential for delivering energy for electricity and vehicles, but also their impacts on global warming, human health, energy security, water supply, space requirements, wildlife, water pollution, reliability, and sustainability. Based on their model, they found that the best sources of alternative energy are wind, concentrated solar, and geothermal energy. The worst are nuclear, clean coal, and ethanol-based fuels. In other words, "the options that are getting the most attention are between 25 to 1,000 times more polluting than the best available options."

cheesethegreat writes "The Royal Society of Chemistry has sharply criticized the 'catastrophically' falling standards for UK school exams in the sciences. The RSC had 1,300 highly achieving students take an exam made up of questions taken from the last 50 years. The students averaged an appalling 15% on 'hard' numerical questions set in the 1960s, but managing much higher marks on the more recent 'soft' non-numerical questions. This latest report has garnered mainstream media attention. The RSC has also created a petition on the UK Prime Minister's official website, calling for urgent intervention to halt the slide, which has garnered over 3,000 signatures. The issue of declining exam standards has been an ongoing concern in the UK, with allegations that exam results have been manipulated by the government to increase pass rates and meet its own targets."

Roland Piquepaille writes "Japanese researchers have found a way to build long threads of DNA using miniaturized hooks and bobbins. In fact, they've demonstrated how to manipulate delicate DNA chains without breaking them. They've designed these laser-directed microdevices to pick up and manipulate individual molecules of DNA. The scientists have used optical tweezers to catch and move these microdevices, which could be used in the future to detect genetic disorders such as Down syndrome." Here's a link to the journal article.

Roland Piquepaille writes "Japanese researchers have found a way to build long threads of DNA using miniaturized hooks and bobbins. In fact, they've demonstrated how to manipulate delicate DNA chains without breaking them. They've designed these laser-directed microdevices to pick up and manipulate individual molecules of DNA. The scientists have used optical tweezers to catch and move these microdevices, which could be used in the future to detect genetic disorders such as Down syndrome." Here's a link to the journal article.

esocid writes "US scientists have designed a new spray-on explosive detector sensitive enough to detect just a billionth of a gram of (nitrogen-containing) explosive. After treatment, the explosive glows blue under UV light, making the detector perfect for use in the field. The silafluorene-fluorene copolymer can detect explosives at much lower levels than existing systems because it detects particles instead of explosive vapors, and is able to show the difference between nitrate esters (trinitroglycerin) and nitroaromatic explosives (TNT). The team is currently working on a similar system to detect peroxide-based explosives and say they hope to be able to investigate perchlorates and organic nitrates, too."

An anonymous reader writes "Physicists at the Bhavnagar University in Gujarat, India have trapped light in a nano-soup concoction. The chance discovery could pave the way for lab-on-a-chip devices for processing optical information. As of now there is no theoretical explanation for why the fluid has the effects it does on laser light."

SoyChemist writes "When she started her job as a new professor at UC Merced, Michelle Khine was stuck without a clean room or semiconductor fabrication equipment, so she went MacGyver and started making Lab-on-a-Chip devices in her kitchen with Shrinky Dinks, a laser printer, and a toaster oven. She would print a negative image of the channels onto the polystyrene sheets and then shrink them with heat. The miniaturized pattern served as a perfect mold for forming rounded, narrow channels in PDMS — a clear, synthetic rubber."

Invisible Pink Unicorn writes "Researchers at New Jersey Institute of Technology have developed an inexpensive solar cell that can be painted or printed on flexible plastic sheets. According to the lead researcher, "Someday homeowners will even be able to print sheets of these solar cells with inexpensive home-based inkjet printers. Consumers can then slap the finished product on a wall, roof or billboard to create their own power stations." The team combined carbon nanotubes with tiny carbon buckyballs (fullerenes) to form snake-like structures. Add sunlight to excite the polymers, and the buckyballs will grab the electrons. The article abstract is available through the Journal of Materials Chemistry, with an illustration of the technology."

An anonymous reader writes "Scientists have developed a form of plastic skin that can heal itself when damaged. The material relies on an underlying network of vessels — similar to blood capillaries — that carry a healing agent to areas on the material's surface that sustain damage. Unlike previous self-healing systems that relied on capsules of agent buried in the polymer and which became depleted after one use, the new system can respond to damage at the same point many times over."

An anonymous reader writes "UK researchers are announcing the first ever workable transistor made of graphene — that's one layer of carbon atoms. It's thinner and smaller than a silicon transistor can ever be, and it works at room temperature. When silicon electronics are dead, this is what many speculate is going to take over. There's slight controversy as they decided to announce their results via a review article, rather than wait for their (submitted) peer review paper to come out."