Lawrence Berkeley National Laboratory’s Tissue-Specific Cell-Wall Engineering is a powerful new method for rapidly transforming crops into biological factories. The technology, a suite of high-precision genetic tools and procedures, makes it possible to change plant traits in a highly selective, tissue-specific fashion.
It’s well known that compared with 2-D cell culture models, 3-D cell culture models have...
The first direct observations of how facets form and develop on platinum nanocubes point the way...
Scientists have, for the first time, characterized so-called quantum vortices that swirl...
Whether the application is biofuels, microbial ecological investigation or medical research, Lawrence Berkeley National Laboratory’s Berkeley Lab Multiplex Chemotyping Microarray (MCM) has proven to be the most powerful and precise system for investigations of biomass at the molecular level. MCM performs rapid chemical analyses of prospective biofuel crops and microbial communities by combining high-throughput micro-contact printing technology with high-fidelity vibrational spectroscopy and mass spectrometry.
Earth’s magnetic field, a familiar directional indicator over long distances, is routinely probed in applications ranging from geology to archaeology. Now it has provided the basis for a technique which might, one day, be used to characterize the chemical composition of fluid mixtures in their native environments.
Wind energy pricing is at an all-time low, according to a new report released by the U.S. Dept. of Energy and prepared by Lawrence Berkeley National Laboratory. The prices offered by wind projects to utility purchasers averaged just $25/MWh for projects negotiating contracts in 2013, spurring demand for wind energy.
While the powerful solvents known as ionic liquids show great promise for liberating fermentable sugars from lignocellulose and improving the economics of advanced biofuels, an even more promising candidate is on the horizon—bionic liquids. Researchers at the Joint BioEnergy Institute have developed “bionic liquids” from lignin and hemicellulose, two by-products of biofuel production from biorefineries.
The human brain harbors far more copper, iron and zinc than anywhere else in the body. Abnormally high levels of these metals can lead to disorders such as Alzheimer’s and Parkinson’s diseases. Chris Chang, a faculty chemist with Berkeley Lab’s Chemical Sciences Div., has spent the past several years developing new probes and techniques for imaging the molecular activity of these metals in the brain.
The first analysis of space dust collected by a special collector onboard NASA’s Stardust mission and sent back to Earth for study in 2006 suggests the tiny specks, which likely originated from beyond our solar system, are more complex in composition and structure than previously imagined. The analysis opens a door to studying the origins of the solar system and possibly the origin of life itself.
There’s a new wave of sound on the horizon carrying with it a broad scope of tantalizing potential applications, including advanced ultrasonic imaging and therapy, and acoustic cloaking, levitation and particle manipulation. Researchers with Lawrence Berkeley National Laboratory have developed a technique for generating acoustic bottles in open air that can bend the paths of sound waves along prescribed convex trajectories.
A powerful new tool that can help advance the genetic engineering of “fuel” crops for clean, green and renewable bioenergy, has been developed by researchers at the Joint BioEnergy Institute, a multi-institutional partnership led by Lawrence Berkeley National Laboratory. The researchers have developed an assay that enables scientists to identify and characterize the function of nucleotide sugar transporters.
A powerful new tool that could help advance the genetic engineering of “fuel” crops bioenergy, has been developed by researchers with the Joint BioEnergy Institute. Their new, unique assay enabled them to analyze nucleotide sugar transporter activities in Arabidopsis, a promising source of plant biomass, and characterize a family of six nucleotide sugar transporters that has never before been described.
Some chemical conversions are harder than others. Refining natural gas into an easy-to-transport, easy-to-store liquid alcohol has so far been a logistic and economic challenge. But now, a new material, designed and patented by researchers at Lawrence Berkeley National Laboratory, is making this process a little easier.
It’s an all-too familiar scenario for many people. You sprain your ankle or twist your knee. If you’re an adult, the initial pain is followed by a long road of recovery, with no promise that the torn ligament or tendon will ever regain its full strength. That’s because tendon and ligament cells in adults produce little collagen, the fibrous protein that is used to build new tendon and ligament tissue.
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 may have been cleared. Researchers with the Lawrence Berkeley National Laboratory have developed the first ab initio method for characterizing the properties of “hot carriers” in semiconductors. Hot carriers are electrical charge carriers with significantly higher energy than charge carriers at thermal equilibrium.
The doubling of transistors on a microprocessor occurs roughly every two years, and is the outcome of what is called Moore’s Law. In a bid to continue this trend of decreasing transistor size and increasing computation and energy efficiency, chip-maker Intel has partnered with Lawrence Berkeley National Laboratory to design an entirely new kind of photoresist, one that combines the best features of two existing types of resist.
A crucial piece of the puzzle behind nature’s ability to split the water molecule during photosynthesis that could help advance the development of artificial photosynthesis for clean, green and renewable energy has been provided by an international collaboration of scientists led by researchers with the Lawrence Berkeley National Laboratory and the SLAC National Accelerator Laboratory.
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.
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