Slashdot Mirror

Zothecula writes "Researchers at Northwestern University, Illinois, have broken a world record in the creation of two synthetic materials, named NU-109 and NU-110, which have the greatest amount of surface areas of any material to date (abstract). To put this into perspective: if one were able to take a crystal of NU-110 the size of a grain of salt, and somehow unfold it, the surface area would cover a desktop. Additionally, the internal surface area of just one gram of the new material would cover one-and-a-half football fields."

carmendrahl writes "Despite a 2009 report from the National Academy of Sciences that found the science in crime labs wanting, very little reform of forensic science has taken place. At a session about the Innocence Project, a group that exonerates prisoners with DNA evidence, speakers called on chemists to join the fight for reform. But forensic chemists don't all agree on what needs reforming."

New submitter GregLaden writes "The object known as the Galileo Thermometer is a vertical glass tube filled with a liquid in which are suspended a number of weighted glass balls. As the temperature of the liquid changes, so does the density. Since each glass ball is set to float at equilibrium in a sightly different density of the liquid, as the temperature increases, each glass ball sinks to the bottom. It turns out that this thermometer was actually invented by a team of instrument inventors that formed a scientific society who had the impressive motto 'Probando e Reprobando,' which in English means 'testing and retesting.' The Accademia del Cimento operated under the leadership of the Grand Duke Ferdinand II from 1657-1667 in Florence, Italy. According to Peter Loyson, who has written a corrective article for the Journal of Chemical Education, Galileo did invent a temperature measuring device called a thermoscope."

MTorrice writes "Scientists have developed a way to convert lipids from sewage sludge into biodiesel. The low cost and high yield of the sludge process may make it economically feasible as a source of biofuel, the researchers say. Today, biofuel producers use lipids in vegetable oils to derive biodiesel, a mixture of fatty-acid-like molecules. Biodiesel is compatible with existing diesel engines, burns with less pollution than petroleum-derived diesel does, and comes from renewable resources. But current biodiesel feedstocks are expensive, limiting the fuel's widespread use. The researchers from South Korea found that sewage sludge, the semisolid material left over from wastewater treatment, can yield 2,200 times more lipids than soybeans and costs 96% less to process. To turn the sludge lipids into biodiesel, the researchers heated them with methanol."

MTorrice writes "Scientists have developed a way to convert lipids from sewage sludge into biodiesel. The low cost and high yield of the sludge process may make it economically feasible as a source of biofuel, the researchers say. Today, biofuel producers use lipids in vegetable oils to derive biodiesel, a mixture of fatty-acid-like molecules. Biodiesel is compatible with existing diesel engines, burns with less pollution than petroleum-derived diesel does, and comes from renewable resources. But current biodiesel feedstocks are expensive, limiting the fuel's widespread use. The researchers from South Korea found that sewage sludge, the semisolid material left over from wastewater treatment, can yield 2,200 times more lipids than soybeans and costs 96% less to process. To turn the sludge lipids into biodiesel, the researchers heated them with methanol."

MTorrice writes "Scientists have developed a way to convert lipids from sewage sludge into biodiesel. The low cost and high yield of the sludge process may make it economically feasible as a source of biofuel, the researchers say. Today, biofuel producers use lipids in vegetable oils to derive biodiesel, a mixture of fatty-acid-like molecules. Biodiesel is compatible with existing diesel engines, burns with less pollution than petroleum-derived diesel does, and comes from renewable resources. But current biodiesel feedstocks are expensive, limiting the fuel's widespread use. The researchers from South Korea found that sewage sludge, the semisolid material left over from wastewater treatment, can yield 2,200 times more lipids than soybeans and costs 96% less to process. To turn the sludge lipids into biodiesel, the researchers heated them with methanol."

MTorrice writes "Microscopic particles of aluminum and gallium rocket around using water as their fuel. The particles, which are 20 micrometers in diameter, are asymmetric: A chemical reaction on the back side of the particle forms hydrogen gas bubbles that propel the motor forward. Over the past several years, bioengineers have built micro- and nanosized rockets that zip through liquids, fueled by chemical reactions between the materials that make up the rockets and their environments. The engineers hope someday these tiny motors could help deliver cargo, such as drugs, in people. Unfortunately, many of these motors require toxic hydrogen peroxide as fuel source, limiting their use in the body. To overcome that constraint, the new micromotors harness a well-known reaction between aluminum and water to produce hydrogen gas."

MTorrice writes "Microscopic particles of aluminum and gallium rocket around using water as their fuel. The particles, which are 20 micrometers in diameter, are asymmetric: A chemical reaction on the back side of the particle forms hydrogen gas bubbles that propel the motor forward. Over the past several years, bioengineers have built micro- and nanosized rockets that zip through liquids, fueled by chemical reactions between the materials that make up the rockets and their environments. The engineers hope someday these tiny motors could help deliver cargo, such as drugs, in people. Unfortunately, many of these motors require toxic hydrogen peroxide as fuel source, limiting their use in the body. To overcome that constraint, the new micromotors harness a well-known reaction between aluminum and water to produce hydrogen gas."

MTorrice writes "Microscopic particles of aluminum and gallium rocket around using water as their fuel. The particles, which are 20 micrometers in diameter, are asymmetric: A chemical reaction on the back side of the particle forms hydrogen gas bubbles that propel the motor forward. Over the past several years, bioengineers have built micro- and nanosized rockets that zip through liquids, fueled by chemical reactions between the materials that make up the rockets and their environments. The engineers hope someday these tiny motors could help deliver cargo, such as drugs, in people. Unfortunately, many of these motors require toxic hydrogen peroxide as fuel source, limiting their use in the body. To overcome that constraint, the new micromotors harness a well-known reaction between aluminum and water to produce hydrogen gas."

New submitter Celarent Darii writes "Prospects for harvesting Uranium from seawater turned interesting by using shrimp shells as a sort of catalyst." Researchers at ORNL presented their findings from a test of a chitin net for harvesting Uranium at the ACS fall meeting. From the ORNL press release: "In a direct comparison to the current state-of-the-art adsorbent, HiCap provides significantly higher uranium adsorption capacity, faster uptake and higher selectivity, according to test results. Specifically, HiCap's adsorption capacity is seven times higher (146 vs. 22 grams of uranium per kilogram of adsorbent) in spiked solutions containing 6 parts per million of uranium at 20 degrees Celsius. In seawater, HiCap's adsorption capacity of 3.94 grams of uranium per kilogram of adsorbent was more than five times higher than the world's best at 0.74 grams of uranium per kilogram of adsorbent. The numbers for selectivity showed HiCap to be seven times higher."

ananyo writes "Chemists have turned red blood cells into long lived sensors that could be put back into circulation to monitor the make up of patients' blood in real time. Many patients require monitoring of their blood, such as diabetics. But extracting blood is both invasive and provides only a one-off measurement. At the American Chemical Society meeting in Philadelphia, Xiaole Shao explained how her team has built sensors that may one day allow both non-invasive and long-term monitoring of crucial aspects of blood chemistry. Shao, a chemist at the University of Missouri-Columbia, and her colleagues exploited the fact that near-infrared light will penetrate skin. This means it can trigger florescent molecules that are circulating in the blood, and this florescence can be picked up by an external monitoring device. If the molecule's florescence changes in response to chemical conditions, these changes can also be detected, and you have a sensor. But florescent dyes can be toxic, and they don't last long in the body, as they are quickly filtered out. To avoid the problem, the researchers encapsulated the sensors in red blood cells. The team next plans to inject the sensors into rats."

Diggester writes "A group of scientists from MIT and the University of British Columbia have created 'mini-factories' that can be programmed to produce different types of proteins, and when implanted into living cells, it should distribute those proteins throughout the body. The scientists have initially triggered these 'factories' into action through the use of a laser light to relay the message of which proteins to produce."

carmendrahl writes "Why do foods taste good together? Scientists aren't anywhere near figuring it out, but that hasn't stopped one popular idea from spawning a company dedicated to discovering avant-garde new pairings. The idea, called flavor-pairing theory, says that if foods share a key odor molecule, they'll pair well. But some scientists say the idea can't explain all cuisines, and another contends his work with tomato flavor (abstract) shows that flavor pairing is 'a gimmick by a chef who is practicing biology without a license.'"

LilaG writes "Drug tests spot banned substances based on their chemical structures, but a new breed of narcotics is designed to evade such tests. These synthetic marijuana drugs, found in 'herbal incense,' are mere chemical tweaks of each other, allowing them to escape detection each time researchers develop a new test for one of the compounds. Now chemists have developed a method that can screen for multiple designer drugs at once, without knowing their structures. The test may help law enforcement crack down on the substances. The researchers used a technique called 'mass defect filtering,' which can detect related compounds all at once. That's because related compounds have almost equal numbers to the right of the decimal point in their molecular masses. The researchers tested their technique on 32 herbal products ... They found that every product contained one or more synthetic cannabinoid; all told, they identified nine different compounds in them — two illegal ones and seven that are not regulated. The original paper appears (behind a paywall) in Analytical Chemistry." From the article: "The research is timely, too. 'Many drugs of abuse in the Olympics are designer drugs,' he [Gary Siuzdak] says, in the steroid family. Grabenauer plans to extend her method to other designer drug families."

LilaG writes "Drug tests spot banned substances based on their chemical structures, but a new breed of narcotics is designed to evade such tests. These synthetic marijuana drugs, found in 'herbal incense,' are mere chemical tweaks of each other, allowing them to escape detection each time researchers develop a new test for one of the compounds. Now chemists have developed a method that can screen for multiple designer drugs at once, without knowing their structures. The test may help law enforcement crack down on the substances. The researchers used a technique called 'mass defect filtering,' which can detect related compounds all at once. That's because related compounds have almost equal numbers to the right of the decimal point in their molecular masses. The researchers tested their technique on 32 herbal products ... They found that every product contained one or more synthetic cannabinoid; all told, they identified nine different compounds in them — two illegal ones and seven that are not regulated. The original paper appears (behind a paywall) in Analytical Chemistry." From the article: "The research is timely, too. 'Many drugs of abuse in the Olympics are designer drugs,' he [Gary Siuzdak] says, in the steroid family. Grabenauer plans to extend her method to other designer drug families."

LilaG writes "Who hasn't marveled at the ability of water bugs to skate along the surface of lakes and ponds? Now materials scientists in China have taken a cue from water striders and created a device that can coast along the surface between oil and water. The tricky part was figuring out how to make an oil-repelling surface that worked underwater. It came down to coating copper wires with copper oxide microstructures that look like flowers made up of nanopetals. Scientists think such coatings could enable robots that clean up oil spills, bug-proof car windshields, and ship hulls that don't build up barnacles."

LilaG writes "To develop new materials for robotics, scientists have developed graphene-based actuators that convert electricity into motion. In robots, actuators act like muscles, driving the movement of mechanical arms and fins. Most actuator materials, such as ceramics and conductive polymers, respond slowly, require a lot of power, or provide very little force. To make speedy, strong actuators, Chinese researchers coated graphene paper with the polymer polydiacetylene. Graphene provides a highly conductive, flexible backing for the fragile polymer crystals, which deform in response to electrical current. The actuators can bend 200 times per second and generate more force than most current materials. Using a sheet of the material, the scientists built a simple inchworm robot that arches and relaxes to crawl forward."

LilaG writes "To develop new materials for robotics, scientists have developed graphene-based actuators that convert electricity into motion. In robots, actuators act like muscles, driving the movement of mechanical arms and fins. Most actuator materials, such as ceramics and conductive polymers, respond slowly, require a lot of power, or provide very little force. To make speedy, strong actuators, Chinese researchers coated graphene paper with the polymer polydiacetylene. Graphene provides a highly conductive, flexible backing for the fragile polymer crystals, which deform in response to electrical current. The actuators can bend 200 times per second and generate more force than most current materials. Using a sheet of the material, the scientists built a simple inchworm robot that arches and relaxes to crawl forward."

New submitter MTorrice writes "Scientists decorated red blood cells with gold nanoparticles so they could trigger the cells to dump their contents with a zap from a laser. The laser pulses heated the particles to produce nanopores in the cells' membranes. The cells contained two fluorescent dyes and both flooded through the pores and out of the cells after the laser pulses. Although the researchers studied the release of dyes, their end goal is to use red blood cells as a vehicle for drug delivery, because the cells are naturally compatible with the immune system and circulate for days in the body. Until now, researchers have found easy ways to load the cells with drugs, but the challenge has been to control the molecules' release."

New submitter MTorrice writes "Scientists decorated red blood cells with gold nanoparticles so they could trigger the cells to dump their contents with a zap from a laser. The laser pulses heated the particles to produce nanopores in the cells' membranes. The cells contained two fluorescent dyes and both flooded through the pores and out of the cells after the laser pulses. Although the researchers studied the release of dyes, their end goal is to use red blood cells as a vehicle for drug delivery, because the cells are naturally compatible with the immune system and circulate for days in the body. Until now, researchers have found easy ways to load the cells with drugs, but the challenge has been to control the molecules' release."

New submitter MTorrice writes "Scientists decorated red blood cells with gold nanoparticles so they could trigger the cells to dump their contents with a zap from a laser. The laser pulses heated the particles to produce nanopores in the cells' membranes. The cells contained two fluorescent dyes and both flooded through the pores and out of the cells after the laser pulses. Although the researchers studied the release of dyes, their end goal is to use red blood cells as a vehicle for drug delivery, because the cells are naturally compatible with the immune system and circulate for days in the body. Until now, researchers have found easy ways to load the cells with drugs, but the challenge has been to control the molecules' release."

LilaG writes with a paragraph from Chemical & Engineering news: "Chemists in China have precisely grown arrays of ultrathin flakes of bismuth selenide and bismuth telluride on a surface. The bismuth compounds belong to a recently discovered – and weird — class of materials called topological insulators, which conduct electrons only along their surfaces, not through their insides. Researchers think topological insulators promise a new realm of fast, energy-efficient electronic and spintronic devices. Making well-defined nanoparticle arrays such as the new study's flakes is a key step towards such devices."

LilaG writes "Not just a way to transport trains at high speed, magnetic levitation could find use in diagnosing disease. Researchers at Harvard have shown that they can detect proteins in blood using MagLev. The researchers, led by George Whitesides, use levitation to detect a change in the density of porous gel beads that occurs when a protein binds to ligands inside the beads. The lower the bead levitates, the more protein it holds. The method (abstract of paywalled article) could work for detecting disease proteins in people's blood samples in the developing world: The magnets cost only about $5 each, and the device requires no electricity or batteries. Because the beads are visible to the naked eye, researchers can make measurements with a simple ruler with a millimeter scale."

First time accepted submitter LilaG writes "Gasoline-burning engines put out twice as much black carbon as was previously measured, according to new field methods tested in Toronto. The tiny particles known as black carbon pack a heavy punch when it comes to climate change, by trapping heat in the atmosphere and by alighting atop, and melting, Arctic ice. With an eye toward controlling these emissions, researchers have tracked black carbon production from fossil fuel combustion in gasoline-burning cars and diesel-burning trucks. Until this study was published [abstract of paywalled article], gas-burning vehicles had been thought to be relatively minor players."

First time accepted submitter LilaG writes "Gasoline-burning engines put out twice as much black carbon as was previously measured, according to new field methods tested in Toronto. The tiny particles known as black carbon pack a heavy punch when it comes to climate change, by trapping heat in the atmosphere and by alighting atop, and melting, Arctic ice. With an eye toward controlling these emissions, researchers have tracked black carbon production from fossil fuel combustion in gasoline-burning cars and diesel-burning trucks. Until this study was published [abstract of paywalled article], gas-burning vehicles had been thought to be relatively minor players."

An anonymous reader writes "German researchers have developed a battery that can remove sodium and chloride ions from seawater. In theory, their invention could be far more energy efficient than thermal desalination or reverse osmosis. This would cut the cost of using salt water for drinking or irrigation. It could also be used to make compact desalination systems for boats and life rafts, or crops. Each battery is made with manganese oxide nanorod electrodes, which absorb sodium when an electrical current passes through them. When the current is reversed, they dump the sodium ions out into waste water."

sciencehabit writes "Researchers have created the world's thinnest pane of glass. The glass, made of silicon and oxygen, formed accidentally when the scientists were making graphene, an atom-thick sheet of carbon, on copper-covered quartz. They believe an air leak caused the copper to react with the quartz, which is also made of silicon and oxygen, producing a glass layer with the graphene. The glass is a mere three atoms thick — the minimum thickness of silica glass—which makes it two-dimensional. The team notes that the structure 'strikingly resembles' a diagram drawn by a glass theorist attempting to unravel its structure back in 1932. Such ultra-thin glass could be used in semiconductor or graphene transistors." See Nano Letters for an abstract (and another picture) to the paywalled article.

cylonlover writes with an excerpt from a Gizmag article: "The cell membrane is one of the most important components of a cell because it separates the interior from the environment and controls the movement of substances in and out of the cell. In a move that brings mankind another step closer to being able to create artificial life forms from scratch, chemists from the University of California, San Diego (UCSD), and Harvard University have created artificial self-assembling cell membranes using a novel chemical reaction. The chemists hope their creation will help shed light on the origins of life." The full paper is available in the Journal of the American Chemical Society (behind a paywall).

An anonymous reader writes "A team of researchers reports they can't reproduce the most important claim from 2010's controversial 'arsenic bacteria' paper — they find no arsenic in the bug's DNA. Meanwhile, other scientists are looking at different aspects of the bug and at arsenic in biology in general."

cylonlover writes with this excerpt from an article at Gizmag: "Research into developing insect cyborgs for use as first responders or super stealthy spies has been going on for a while now. Most research has focused on using batteries, tiny solar cells, or piezoelectric generators to harvest kinetic energy from the movement of an insect's wings to power the electronics attached to the insects. Now a group of researchers at Case Western Reserve University have created a biofuel cell power supply that relies just on the insect's normal feeding [registration required to download full paper]."

An anonymous reader writes "Grad students at UC Irvine have built a spatial frequency domain imaging system using parts from a cheap LCD projector and a digital camera. The system can be used to check the level of bruising or oxygenation in layers of tissue that aren't visible to the naked eye, according to an article in Chemical and Engineering News. An accompanying video shows the series of patterned pulses that the improvised imaging system makes in order to read hemoglobin and fat levels below the surface of the skin. A more sophisticated version of the imaging system is being commercialized by a startup within UC Irvine, called Modulated Imaging. The article and video also describe infrared brain scanners that can non-invasively check for brain bleeds, and multiphoton microscopes that produce stunning images of live skin cells."

An anonymous reader writes "Researchers at Notre Dame have created a nanoparticle paste, which acts as the main ingredient in solar cells that are very easy to construct. In a short video clip, they can be seen assembling a functional solar cell with little more than a heat gun, tape, and some binder clips. The paste is made from a mix of t-butanol, water, and a mix of cadmium selenide with cadmium sulfide nanoparticles. So far, the experimental devices are not nearly as efficient as standard solar cells, but they were just developed. If the materials were slightly less toxic, it might even be a project that kids could do at home."

eldavojohn writes "Researchers at Purdue University's Birck Nanotechnology Center have released news of a proof of concept new ferroelectric transistor random access memory or 'FeTRAM.' This new technology is nonvolatile and the researchers claim it could use up to 99% less energy than current flash memory. Unlike most FeRAM technology that uses a capacitor, FeTRAM provides nondestructive readout by storing information using a ferroelectric transistor instead. From the article: 'The new technology also is compatible with industry manufacturing processes for complementary metal oxide semiconductors, or CMOS, used to produce computer chips. It has the potential to replace conventional memory systems.' So if they get this into production, you might not have to worry about your laptop cooking your genitals. They've been published in ACS (paywalled) and the professor leading the research has many patents filed relating to transistor nanotechnology."

First time accepted submitter Babu V Bassa writes "Concerned about adding too much carbon dioxide to the atmosphere? Consider a roof top coating on your car with this new material. A multinational team of researchers have developed a renewable sponge like material to capture and store gaseous carbon dioxide. The organic material is made up of gamma-cyclodextrin. Conventional metal-organic frameworks, which also are effective at adsorbing carbon dioxide, are usually prepared from materials derived from crude oil and often incorporate toxic heavy metals and are also non-renewable. The research paper published in the Journal of the American Chemical Society claims that its synthesis is essentially carbon-neutral and have the demonstrated ability to absorb carbon dioxide from the atmosphere makes them promising materials for carbon fixation."

An anonymous reader writes "A new study unveiled at the American Chemical Society points to panda poop as a source of remarkably efficient enzyme-producing bacteria that are able to break down plant materials for cheaper and more efficient biofuel production. Inspired by the giant panda's voracious appetite for bamboo, scientists began to study the fecal matter of giant pandas at the Memphis Zoo. A year of samples indicated that the pandas have a unique ability to convert lignocellulose from plant matter into energy. In fact, gut bacteria of a giant panda can convert 95 percent of the plant's biomass into simple sugars."

With his first accepted Slashdot submission, Zandamesh sends this excerpt from ZDNet: "On earth, nuclear reactors are under attack because of concerns over damage caused by natural disasters. In space, however, nuclear technology may get a new lease on life. Plans for the first nuclear power plant for the production of electricity to be used by manned or unmanned bases on the Moon, Mars and other planets have been unveiled at the 242nd National Meeting & Exposition of the American Chemical Society. 'The reactor itself may be about 1 ½ feet wide by 2 ½ feet high, about the size of a carry-on suitcase. There are no cooling towers. ... The team is scheduled to build a technology demonstration unit in 2012."

athe!st writes "A new anti-microbial treatment that can make clothing — including smelly socks — permanently germ-free has been developed by US scientists. In a paper published in the American Chemical Society journal Applied Materials and Interfaces, Dr Jason Locklin and his colleagues state that the treatment kills a wide range of dangerous pathogens, including staph, strep, E. coli, pseudomonas and acinetobacter."

athe!st writes "A new anti-microbial treatment that can make clothing — including smelly socks — permanently germ-free has been developed by US scientists. In a paper published in the American Chemical Society journal Applied Materials and Interfaces, Dr Jason Locklin and his colleagues state that the treatment kills a wide range of dangerous pathogens, including staph, strep, E. coli, pseudomonas and acinetobacter."

RogerRoast writes "Vanderbilt University scientists report that they have developed a simple technique for stamping patterns invisible to the human eye onto a special class of nanomaterials. According to the article, the method works with materials that are riddled with tiny voids that give them unique optical, electrical, chemical and mechanical properties. 'It's amazing how easy it is. We made our first imprint using a regular tabletop vise,' Sharon M. Weiss the lead author said. The article was published in the latest issue of the journal Nano Letters."

erfnet writes "The Technical University of Munich, along with a German beer-maker, have kindly published a 'Comprehensive Sensomics Analysis of Hop-Derived Bitter Compounds During Storage of Beer' They determined 56 hop-derived sensometabolites which contribute to bitter taste during storage, increasing with time and temperature. If we had only had this information during our College days, we could have been even geekier! 'Duuuuude, it's not skunked, it's suffering from proton-catalyzed cyclization of trans-iso-a-acids.'"

cylonlover writes "It's certainly an established fact that electricity can cause fires, but a group of Harvard scientists have presented their research on the use of electricity for fighting fires. In a presentation at the 241st National Meeting & Exposition of the American Chemical Society, Dr. Ludovico Cademartiri told of how they used a unique device to shoot beams of electricity at an open flame over one foot tall. Almost immediately, he said, the flame was extinguished. 'Such a device could be used, for instance, to make a path for firefighters to enter a fire or create an escape path for people to exit, he said. The system shows particular promise for fighting fires in enclosed quarters, such as armored trucks, planes, and submarines.'"

michaelmalak writes "Scientists at the US Department of Energy's Brookhaven National Laboratory and Los Alamos National Laboratory have fabricated transparent, thin films capable of absorbing light and generating electric charge over a relatively large area. The material, described in the journal Chemistry of Materials (subscription required), could be used to develop transparent solar panels or even windows that absorb solar energy to generate electricity. The material consists of a semiconducting polymer doped with carbon-rich fullerenes."

SkinnyGuy writes "New carbon nanotube-based technology could literally allow companies to paint layers of electricity-holding lithium-ion on standard pieces of paper. The possibilities are endless." You can also read the actual paper.

SkinnyGuy writes "New carbon nanotube-based technology could literally allow companies to paint layers of electricity-holding lithium-ion on standard pieces of paper. The possibilities are endless." You can also read the actual paper.

Garrett Fox writes "University of Cincinnati researchers describe a method of getting photosynthesis from a high-surface-area foam containing enzymes that produce sugar using light and CO2 (abstract). Oddly, the foam itself is derived from a species of frog. More interesting is that the technique doesn't use whole cells or apparently even chloroplasts. The researchers claim 'chemical conversion efficiencies approaching 96%,' as well as tolerance for deliberately high-CO2 environments."

cyberfringe writes "Professor of Materials Science Dawn Bonnell and colleagues at the University of Pennsylvania have discovered a way to turn optical radiation into electrical current that could lead to self-powering molecular circuits and efficient data storage. They create surface plasmons that ride the surface of gold nanoparticles on a glass substrate. Surface plasmons were found to increase the efficiency of current production by a factor of four to 20, and with many independent parameters to optimize, enhancement factors could reach into the thousands. 'If the efficiency of the system could be scaled up without any additional, unforeseen limitations, we could conceivably manufacture a 1A, 1V sample the diameter of a human hair and an inch long,' Prof. Bonnell explained. The academic paper was published in the current issue of ACS Nano. (Abstract available for free.) The significance? This may allow the creation of nano-sized circuits that can power themselves through sunlight (or another directed light source). Delivery of power to nanodevices is one of the big challenges in the field."

retroworks writes "Greenercomputing.com staff covered a study which sheds more light on the controversial practice of exporting used computer equipment overseas. University of Arizona professors Ramzy Kahhat and Eric Williams newly published research, Product or Waste? Importation and End-of-Life Processing of Computers in Peru apparently confirms what WR3A.org says in the Video 'Fair Trade Recycling'. Namely, that most of the exports of used computers imported by buyers overseas (88%) are really for reuse and repair. Otherwise, people would not pay to import them. This bolsters pro-export arguments made in a scholarly article by Charles Schmidt of NIH in 2006. Perhaps what is needed to stem e-waste pollution is not a ban on exports, but for more people to export, so that buyers have more choice of (ethical) suppliers. Put another way: If used computer exports are outlawed, only outlaws will export used computers."

suraj.sun writes "Researchers at the Massachusetts Institute of Technology have developed a fabric made of a mesh of light-sensitive fibers that collectively act like a rudimentary camera. The fibers, which each can detect two frequencies of light, produced signals that when amplified and processed by a computer reproduced an image of a smiley face near the mesh. 'This is the first time that anybody has demonstrated that a single plane of fibers, or "fabric," can collect images just like a camera but without a lens,' said Yoel Fink, an associate professor of materials science, who along with colleagues described the approach in a the journal Nano Letters. MIT suggested that the technology, if developed further, could give a soldier a uniform that would help him see threats in all directions. Optical fiber webs, by distributing the chore across a large area, would be less susceptible to damage in one area."

Hugh Pickens writes "Digital storage devices have become ubiquitous in our lives but the move to digital storage has raised concerns about the lifetime of the storage media. Now Alex Zettl and his group at the University of California, Berkeley report that they have developed an experimental memory device consisting of a crystalline iron nanoparticle enclosed in a multiwalled carbon nanotube that could have a storage capacity as high as 1 terabyte per square inch and temperature-stability in excess of one billion years. The nanoparticle can be moved through the nanotube by applying a low voltage, writing the device to a binary state represented by the position of the nanoparticle. The state of the device can then be subsequently read by a simple resistance measurement while reversing the nanoparticle's motion allows a memory 'bit' to be rewritten. This creates a programmable memory system that, like a silicon chip, can record digital information and play it back using conventional computer hardware storing data at a high density with a very long lifetime. Details of the process are available at the American Chemical Society for $30."

Hugh Pickens writes "New Scientist reports that two decades after the world's largest nuclear disaster, life around Chernobyl continues to adapt, with Chernobyl soya containing significantly different amounts of several dozen proteins, including one protein involved in defending cells from heavy metal and radiation damage. 'One protein is known to actually protect human blood from radiation,' says Martin Hajduch of the Slovak Academy of Sciences. In a study to determine how plants might have adapted to the meltdown, Hajduch's team compared soya grown in radioactive plots near Chernobyl with plants grown about 100 km away in uncontaminated soil. Results from the study suggest that adaptation toward heavy metal stress, protection against radiation damage, and mobilization of seed storage proteins are involved in the plant adaptation mechanism to radioactivity in the Chernobyl region (abstract). Determining how plants coped with life after Chernobyl could help scientists engineer radiation-resistant plants. While few farmers are eager to cultivate radioactive plots on Earth, future interplanetary travelers may one day need to grow crops to withstand space radiation."