Researchers at the Univ. of California, Los Angeles and the Univ. Pierre et Marie Curie in Paris have identified a method for manufacturing longer-lasting and stronger forms of glass. The research could lead to more durable display screens, fiber-optic cables, windows and other materials, including cement.
An international team of researchers has used infinitely short light pulses to observe ultrafast changes in the electron-level properties of superconductors, setting a new standard for temporal resolution in the field. The scientists liken the new technique to the development of high-speed film capture in the early days of photography.
One third of the world’s food-producing land has been lost in the past 40 years as a result of soil degradation, putting global food security at risk. Researchers have discovered how aluminum, a toxic result of soil acidification, acts to reduce plant growth.
With more than five times the thermal conductivity of copper, diamond is the ultimate heat spreader. But the slow rate of heat flow into diamond from other materials limits its use in practice. In particular, the physical process controlling heat flow between metals and diamond has remained a mystery to scientists for many years.
Imagine setting a frying pan on the stove and cranking up the heat, only to discover that in a few spots the butter isn't melting because part of the pan remains at room temperature. What seems like an impossible scenario in the kitchen is exactly what happens in the strange world of quantum physics, researchers at the Univ. of Arizona have discovered.
Researchers have used an advanced model to simulate in unprecedented detail the workings of "resistance-switching cells" that might replace conventional memory for electronics applications, with the potential to bring faster and higher capacity computer memory while consuming less energy. These electromechanical "metallization cells" rapidly switch from high resistance to low resistance.
An extraordinary self-regulating heating effect that can be achieved in a particular type of magnetic material may open the doors to a new strategy for hyperthermia cancer treatment. Temperatures that can be tolerated by healthy body cells have long been known to destroy cancerous cells. An approach that uses magnetic particles introduced into tissue and heated remotely has found some success in treating cancer.
Tiny, perfectly smooth carbon spheres added to motor oil have been shown to reduce friction and wear typically seen in engines by as much as 25%, suggesting a similar enhancement in fuel economy. The researchers also have shown how to potentially mass-produce the spheres, making them hundreds of times faster than previously possible using ultrasound to speed chemical reactions in manufacturing.
When scientists develop a full quantum computer, the world of computing will undergo a revolution of sophistication, speed and energy efficiency that will make even our beefiest conventional machines seem like Stone Age clunkers by comparison. But, before that happens, quantum physicists will have to create circuitry that takes advantage of the marvelous computing prowess promised by the quantum bit.
Engineers at The Univ. of Texas at Dallas have created semiconductor technology that could make night vision and thermal imaging affordable for everyday use. The engineers created an electronic device in affordable technology that detects electromagnetic waves to create images at nearly 10 THz, which is the highest frequency for electronic devices. The device could make night vision and heat-based imaging affordable.
Scientific debate has been hot lately about whether microbial nanowires, the specialized electrical pili of the mud-dwelling anaerobic bacterium Geobacter sulfurreducens, truly possess metallic-like conductivity as its discoverers claim. But now a Univ. of Massachusetts Amherst team says they settled the dispute between theoretical and experimental scientists by devising a combination of new experiments and better theoretical modeling.
From light-up shoes to smart watches, wearable electronics are gaining traction among consumers, but these gadgets’ versatility is still held back by the stiff, short-lived batteries that are required. These limitations, however, could soon be overcome.
A new provisionally patented technology from a New Mexico State Univ. researcher could revolutionize carbon dioxide capture and have a significant impact on reducing pollution worldwide. Through research on zeolitic imidazolate frameworks, or ZIFs, the researcher synthesized a new subclass of ZIF that incorporates a ring carbonyl group in its organic structure.
Researchers at the Univ. of Houston have created a new thermoelectric material, intended to generate electric power from waste heat with greater efficiency and higher output power than currently available materials. The material, germanium-doped magnesium stannide, has a peak power factor of 55, with a figure of merit of 1.4.
For almost a century, scientists have been puzzled by a process that is crucial to much of the life in Earth’s oceans: Why does calcium carbonate, the tough material of seashells and corals, sometimes take the form of calcite, and at other times form a chemically identical form of the mineral, called aragonite, that is more soluble—and therefore more vulnerable to ocean acidification?
Phosphorus, a highly reactive element commonly found in match heads, tracer bullets and fertilizers, can be turned into a stable crystalline form known as black phosphorus. In a new study, researchers from the Univ. of Minnesota used an ultra-thin black phosphorus film, only 20 layers of atoms, to demonstrate high-speed data communication on nanoscale optical circuits.
A new simple tool developed by nanoengineers at the Univ. of California, San Diego, is opening the door to an era when anyone will be able to build sensors, anywhere. The team developed high-tech bio-inks that react with several chemicals, including glucose. They filled off-the-shelf ballpoint pens with the inks and were able to draw sensors to measure glucose directly on the skin and sensors to measure pollution on leaves.
Lithium-sulfur batteries have been a hot topic in battery research because of their ability to produce up to 10 times more energy than conventional batteries, which means they hold great promise for applications in energy-demanding electric vehicles. However, there have been fundamental road blocks to commercializing these sulfur batteries.
Chemotherapy often shrinks tumors at first, but as cancer cells become resistant to drug treatment, tumors can grow back. A new nanodevice developed by Massachusetts Institute of Technology researchers can help overcome that by first blocking the gene that confers drug resistance, then launching a new chemotherapy attack against the disarmed tumors.
Dislocations in oxides such as cerium dioxide, a solid electrolyte for fuel cells, turn out to have a property that is the opposite of what researchers had expected, according to a new analysis. Researchers had thought that a certain kind of strain would speed the transport of oxygen ions through the material, potentially leading to the much faster diffusion that is necessary in high-performance solid-oxide fuel cells.
A research partnership is reporting advances on how to make solar cells stronger, lighter, more flexible and less expensive when compared with the current silicon or germanium technology on the market. The researchers discovered how a blend of conjugated polymers resulted in structural and electronic changes that increased efficiency three-fold, by incorporating graphene in the active layer of the carbon-based materials.
Regulating comfort in small commercial buildings could become more efficient and less expensive thanks to an innovative low-cost wireless sensor technology being developed by researchers at Oak Ridge National Laboratory. Buildings are responsible for about 40% of the energy consumed in the U.S. Studies indicate that advanced sensors and controls have the potential to reduce the energy consumption of buildings by 20 to 30%.
Graphene nanoribbons formed into a 3-D aerogel and enhanced with boron and nitrogen are excellent catalysts for fuel cells, even in comparison to platinum, according to Rice Univ. researchers. A team led by materials scientist Pulickel Ajayan and chemist James Tour made metal-free aerogels from graphene nanoribbons and various levels of boron and nitrogen to test their electrochemical properties.
On the search for high-performance materials for applications such as gas storage, thermal insulators or dynamic nanosystems it’s essential to understand the thermal behavior of matter down to the molecular level. Classical thermodynamics average over time and over a large number of molecules. Within a 3-D space single molecules can adopt an almost infinite number of states, making the assessment of individual species nearly impossible.
Lithium-ion batteries unleash electricity as electrochemical reactions spread through active materials. Manipulating this complex process and driving the reactions into the energy-rich heart of each part of these active materials is crucial to optimizing the power output and ultimate energy capacity of these batteries. Now, scientists have mapped these atomic-scale reaction pathways and linked them to the battery’s rate of discharge.