-By Emily Scott Ten years ago, Lawrence Berkeley National Laboratory announced the opening of a brand new, 15,000-square-foot facility full of stainless steel state-of-the-art bioprocessing equipment – what we now know as the Advanced Biofuels and Bioproducts Process Development Unit, or ABPDU, was officially open for business. Funded by the U.S. Department of Energy’s Bioenergy
With a simple stretch, a thin semiconductor material can achieve near 100% light-emission efficiency at all brightness levels. The discovery, reported by scientists at Berkeley Lab and UC Berkeley in the journal Science, has implications for energy-efficient mobile devices and lighting applications.
Scientists at Berkeley Lab and UC Berkeley have taken the clearest picture yet of electronic particles that make up a mysterious magnetic state called quantum spin liquid. The achievement could facilitate the development of superfast quantum computers and energy-efficient superconductors.
Scientists at Berkeley Lab and UC Berkeley have created a one-atom thin magnet that operates at room temperature. The ultrathin magnet could lead to new applications in computing and electronics, and new tools for the study of quantum physics.
X-ray beams at the Advanced Light Source allowed researchers to “see” oxygen gas molecules adhere to a specially prepared electrode surface, an important step in the electrochemical reaction taking place in fuel cells.
Researchers at Stanford and Berkeley Lab’s Molecular Foundry have developed virus-killing molecules called peptoids. The technology could make possible an emerging category of antiviral drugs that could treat everything from herpes and COVID-19 to the common cold.
Scientists at Berkeley Lab and UC Berkeley have developed a nanoparticle composite that grows into 3D crystals. The new 3D-grown material could speed up production and eliminate errors in the mass manufacturing of nanoscale photonics for smart buildings or actuators for robotics.
In our future electrified world, the demand for battery storage is projected to be enormous, reaching to upwards of 2 to 10 terawatt-hours (TWh) of annual battery production by 2030, from less than 0.5 TWh today. However, concerns are growing as to whether key raw materials will be adequate to meet this future demand.
A multidisciplinary team has been working for several years to develop a game-changing plastic that, unlike traditional plastics, can be recycled indefinitely and is not made from petroleum. In this Q&A, we asked two project leaders about the inspiration for the unique plastic, shortfalls in our current recycling systems, and how this ambitious project is enabled by a diverse combination of scientific expertise.
A UC Berkeley-led research team in collaboration with Berkeley Lab has discovered a way to simplify the removal of toxic metals, like mercury and boron, during desalination to produce clean water, while at the same time potentially capturing valuable metals, such as gold.