Visiting scientists gave input during a workshop last week on the range of new X-ray science made possible by a planned upgrade of the Advanced Light Source.
Defects and jagged surfaces at the edges of nanosized platinum and gold particles are key hot spots for chemical reactivity, researchers confirmed using a unique infrared probe.
Scientists have enlisted the exotic properties of graphene to function like the film of an incredibly sensitive camera system in visually mapping tiny electric fields. They hope to enlist the new method to image electrical signaling networks in our hearts and brains.
Researchers at the Joint BioEnergy Institute and the Great Lakes Bioenergy Research Center used crystallography and biophysical methods to better understand how the NOV1 enzyme breaks down a a stilbene substrate into two smaller compounds. Understanding this unusual chemical reaction brings insight on how to generate desirable biofuels and bioproducts from biomass deconstruction.
Berkeley Lab scientists are developing new ways to see the unseen. Here are seven imaging advances (recently reported in our News Center) that are helping to push science forward, from developing better batteries to peering inside cells to exploring the nature of the universe. 1. Seeing DNA nanostructures in 3-D DNA segments can serve as a
Motivated by public hazards associated with contaminated sources of drinking water, a team of scientists has successfully developed and tested tiny, glowing crystals that can detect and trap heavy-metal toxins like mercury and lead.
An international team of scientists is providing new insight into the process by which plants use light to split water and create oxygen. In experiments led by Berkeley Lab scientists, ultrafast X-ray lasers were able to capture atomic-scale images of a protein complex found in plants, algae, and cyanobacteria at room temperature.
Scientists have produced detailed 3-D visualizations that show an unexpected connectivity in the genetic material at the center of cells, providing a new understanding of a cell’s evolving architecture.
Berkeley Lab scientists have found a way to engineer the atomic-scale chemical properties of a water-splitting catalyst for integration with a solar cell, and the result is a big boost to the stability and efficiency of artificial photosynthesis. The research comes out of the Joint Center for Artificial Photosynthesis (JCAP), established to develop a cost-effective method of turning sunlight, water, and carbon dioxide into fuel.
Berkeley Lab-developed tech enabling energy-saving roofs, long-lived batteries, better data from X-ray experiments, safer drinking water, and reduced carbon dioxide in the atmosphere have received 2016 R&D 100 awards.