New technology under development at the Univ. of California, Berkeley could soon give bomb-sniffing dogs some serious competition. A team of researchers has found a way to dramatically increase the sensitivity of a light-based plasmon sensor to detect incredibly minute concentrations of explosives.
One of the major road blocks to the design and development of new, more efficient solar cells...
The doubling of transistors on a microprocessor...
Researchers at Lawrence Berkeley National Lab and the Univ. of Hawaii have uncovered the first step in the process that transforms gas-phase molecules into solid particles like soot and other carbon-based compounds. The finding could help combustion chemists make more-efficient, less-polluting fuels and help materials scientists fine-tune their carbon nanotubes and graphene sheets for faster, smaller electronics.
What is believed to be the smallest force ever measured has been detected by researchers with the Lawrence Berkeley National Laboratory and the Univ. of California, Berkeley. Using a combination of lasers and a unique optical trapping system that provides a cloud of ultracold atoms, the researchers measured a force of approximately 42 yoctonewtons.
Skyrmions have been observed for the first time using x-rays. An international collaboration of researchers working at the Advanced Light Source observed skyrmions in copper selenite an insulator with multiferroic properties. The results not only hold promise for ultra-compact data storage and processing, but may also open up entire new areas of study in quantum topology.
Researchers at the Joint BioEnergy Institute (JBEI) have unveiled the first glycosyltransferase clone collection specifically targeted for the study of the biosynthesis of plant cell walls. The idea behind “the JBEI GT Collection” is to provide a functional genomic resource for researchers seeking to extract the sugars in plant biomass and synthesize them into clean, green and renewable transportation fuels.
From allowing our eyes to see, to enabling green plants to harvest energy from the sun, photochemical reactions are ubiquitous and critical to nature. Photochemical reactions also play essential roles in high technology. Using photochemical reactions to our best advantage requires a deep understanding of the interplay between the electrons and atomic nuclei within a molecular system after that system has been excited by light.
Hydrogen is a neutral atom. Its single electron orbits a single proton, and the net effect is no electrical charge. But what about hydrogen’s antimatter counterpart, antihydrogen? Made of a positron that orbits an antiproton, the antihydrogen atom should be neutral too. Various results have indicated as much, but because the charge of antiatoms is difficult to measure, it has remained an open question.
An advance has been achieved towards next-generation ultrasonic imaging with potentially 1,000 times higher resolution than today’s medical ultrasounds. Researchers with Lawrence Berkeley National Laboratory have demonstrated a technique for producing, detecting and controlling ultra-high-frequency sound waves at the nanometer scale.
While big machines were once the stuff that scientific dreams are made of, analytical spectroscopy instrumentation has trended to smaller products that are portable, affordable and fit into locations far removed from a standard laboratory, such as the back of an ambulance or inside a chemical reactor.
The days of self-assembling nanoparticles taking hours to form a film over a microscopic-sized wafer are over. Researchers with Lawrence Berkeley National Laboratory have devised a technique whereby self-assembling nanoparticle arrays can form a highly ordered thin film over macroscopic distances in one minute.
Atomic-scale snapshots of a bimetallic nanoparticle catalyst in action have provided insights that could help improve the industrial process by which fuels and chemicals are synthesized from natural gas, coal or plant biomass. A multinational laboratory collaboration has taken the most detailed look ever at the evolution of platinum/cobalt bimetallic nanoparticles during reactions in oxygen and hydrogen gases.
Scientists from Lawrence Berkeley National Laboratory have gained more insights into why older women are more susceptible to breast cancer. They found that as women age, the cells responsible for maintaining healthy breast tissue stop responding to their immediate surroundings, including mechanical cues that should prompt them to suppress nearby tumors.
A new study of supermassive black holes at the centers of galaxies has found magnetic fields play an impressive role in the systems’ dynamics. In fact, in dozens of black holes surveyed, the magnetic field strength matched the force produced by the black holes’ powerful gravitational pull, says a team of scientists.
Faster electronic device architectures are in the offing with the unveiling of the world’s first fully 2-D field-effect transistor (FET) by researchers at Lawrence Berkeley National Laboratory. Unlike conventional FETs made from silicon, these 2-D FETs suffer no performance drop-off under high voltages and provide high electron mobility, even when scaled to a monolayer in thickness.
Scientists have discovered a material that has the same extraordinary electronic properties as 2-D graphene, but in a sturdy 3-D form that should be much easier to shape into electronic devices such as very fast transistors, sensors and transparent electrodes. The material, cadmium arsenide, is being explored independently by three groups.
A team at Lawrence Berkeley National Laboratory found unexpected traces of water in semiconducting nanocrystals. The water as a source of small ions for the surface of colloidal lead sulfide nanoparticles allowed the team to explain just how the surface of these important particles are passivated, meaning how they achieve an overall balance of positive and negative ions.
Making a tabletop particle accelerator just got easier. A new study shows that certain requirements for the lasers used in an emerging type of small-area particle accelerator can be significantly relaxed. Researchers hope the finding could bring about a new era of accelerators that would need just a few meters to bring particles to great speeds, rather than the many kilometers required of traditional accelerators.
It took every inch of the Large Hadron Collider's 17-mile length to accelerate particles to energies high enough to discover the Higgs boson. New laser-plasma accelerators, which use lasers instead of high-power radio-frequency waves to energize electrons in very short distances, could do the same thing in a football field length or less. A new theoretical study predicts that this approach may be easier than previously thought.
A pathway to the design of even more effective versions of the powerful anticancer drug Taxol has been opened with the most detailed look ever at the assembly and disassembly of microtubules, tiny fibers of tubulin protein that form the cytoskeletons of living cells and play a crucial role in mitosis.
In June, 2010, two months after the Deepwater Horizon oil spill, Regina Lamendella collected samples along a hard-hit beach near Grand Isle, Louisiana. She was part of a team of Lawrence Berkeley National Laboratory researchers that wanted to know how the microbes along the shoreline were responding to the spill.
Graphene continues to reign as the next potential superstar material for the electronics industry, a slimmer, stronger and much faster electron conductor than silicon. With no natural energy bandgap, however, graphene’s superfast conductance can’t be switched off, a serious drawback for transistors and other electronic devices.
New analysis of ancient Jian wares reveals the distinctive pottery contains an unexpected and highly unusual form of iron oxide. This rare compound, called epsilon-phase iron oxide, was only recently discovered and characterized by scientists and so far has been extremely difficult to create with modern techniques.
In new work, a research team has shed light on a type of molecular motor used to package the DNA of a number of viruses, including such human pathogens as herpes and the adenoviruses. The scientists found that this viral packaging motor exerts torque to rotate DNA and adapts to changing conditions in order to coordinate its mechano-chemical activity.
For years, scientists have had an itch they couldn’t scratch. Even with the best microscopes and spectrometers, it’s been difficult to study molecules at the mesoscale, a region of matter that ranges from 10 to 1,000 nm. Now, with the help of broadband infrared light from the Advanced Light Source synchrotron, researchers have developed a broadband imaging technique that looks inside this realm with unprecedented sensitivity and range.
The icing on the cake for semiconductor nanocrystals that provide a non-damped optoelectronic effect may exist as a layer of tin that segregates near the surface. One method of altering the electrical properties of a semiconductor is by introducing impurities called dopants. A team of researchers has demonstrated that equally important as the amount of dopant is how the dopant is distributed on the surface and throughout the material.
The drive to develop ultra-small and ultra-fast electronic devices using a single atomic layer of semiconductors, such as transition metal dichalcogenides, has received a significant boost. Researchers with Lawrence Berkeley National Laboratory have recorded the first observations of a strong nonlinear optical resonance along the edges of a single layer of molybdenum disulfide.
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