Lawrence Berkeley National Laboratory is following California’s shelter-in-place order and has reduced onsite staffing levels.
Go to the Lab’s COVID-19 website for more information. Learn About COVID-19 Research at the Lab.
A Berkeley Lab-led research team’s surprising discovery could lead to new electronic materials that surpass the limitations imposed by Moore’s Law, which predicted in 1975 that the number of transistors packed into a silicon computer chip would double every two years.
Our biomanufacturing experts are helping accelerate the development of new COVID-19-fighting technologies. Learn how the scientists at the ABPDU are collaborating with biotech companies to scale up and optimize production of coronavirus-targeting antibodies and a highly accurate rapid testing system.
A team of scientists led by Berkeley Lab and UC Berkeley has demonstrated a powerful new technique that uses light to measure how electrons move and interact within 2D materials. Their finding could lead to new approaches for quantum devices.
Three scientists at Berkeley Lab have been selected by the U.S. Department of Energy’s Office of Science to receive significant funding for research through its Early Career Research Program. Also, three faculty scientists with joint appointments at UC Berkeley will receive ECRP funding through UC Berkeley.
A team of scientists working at Berkeley Lab’s 88-Inch Cyclotron has discovered a new form of the human-made element mendelevium. The newly created isotope, mendelevium-244, is the 17th and lightest form of the element, which was first discovered in 1955 by a Berkeley Lab team.
Sometimes, when something is broken, the first step to fixing it is to break it even more. This is the case for a human DNA repair protein that functions by marking and then further breaking damaged DNA. New findings provide insight into how DNA repair works in healthy cells and how mutations can translate into different diseases and cancer.
Humans have drawn technological inspiration from fish scales going back to ancient times, such as the scale armor Roman warriors, which provided both protection and mobility. Now Berkeley Lab scientists have characterized carp scales down to the nanoscale to understand how the material is resistant to penetration while retaining flexibility.
Marjorie Shapiro, an experimental particle physicist at Berkeley Lab, has been accustomed to working remotely and observing extreme social distancing from some colleagues for years, given that the scientific experiment she supports is 5,800 miles away. She is a participant in the ATLAS collaboration, a particle detector at CERN in Switzerland.
A new computational approach developed by scientists at Lawrence Berkeley National Laboratory offers a high-tech yet simple method for estimating groundwater: it pairs high-resolution images derived by satellite with advanced computer modeling to estimate aquifer volume change from observed ground deformation.
Using a unique combination of nanoscale imaging and chemical analysis, an international team of researchers has revealed a key step in the molecular mechanism behind the water splitting reaction of photosynthesis, a finding that could help inform the design of renewable energy technology. With an instrument that the team designed and fabricated, they analyzed photosynthetic proteins using both X-ray crystallography and X-ray emission spectroscopy.