To see, in microscopic detail, what makes the diabolical ironclad beetle so uniquely sturdy, researchers used an X-ray imaging technique at Berkeley Lab’s Advanced Light Source synchrotron, and other techniques, to explore a protective covering known as the “elytra,” its abdomen, and other parts.
The discovery of a primitive form of a photosynthetic enzyme will help scientists understand how carbon-fixing organisms oxygenated the atmosphere and how modern plants evolved
A team of scientists led by Berkeley Lab has gained important new insight into electrons’ role in the harvesting of light in artificial photosynthesis systems. The scientists say that their findings can help researchers develop more efficient material combinations for the design of high-performance solar fuels devices.
View Berkeley Lab from the sky in this aerial video, which features drone footage taken earlier this year by Thor Swift, lead photographer in Berkeley Lab’s Creative Services office of the Information Technology Division. The video was produced by Marilyn Sargent, a multimedia producer in the Strategic Communications department.
Scientists at Berkeley Lab have demonstrated a new technique that could improve the performance of atomically thin semiconductors for next-generation electronics such as optoelectronics, thermoelectrics, and sensors.
Scientists at Berkeley Lab and the Joint Center for Artificial Photosynthesis (JCAP) have gained important new insight into how the performance of a promising semiconducting thin film can be optimized at the nanoscale for renewable energy technologies such as solar fuels.
X-ray experiments at Berkeley Lab played a key role in resolving the origin of rare, odd meteorites that have puzzled scientists since their discovery a half-century ago. Known as type IIE iron meteorites, they appear to have originated from a parent body that had a composition featuring both fully melted and unmelted parts – other meteorite types display only one composition.
Researchers at Berkeley Lab, in collaboration with Carnegie Mellon University, have developed a new battery material that could enable long-range electric vehicles that can drive for hundreds of miles on a single charge, and eVTOL (electric vertical takeoff and landing) aircraft.
A research team co-led by Berkeley Lab and UC Berkeley grew onto silicon an ultrathin material that demonstrates ferroelectricity. The discovery could lead to ultrathin materials that control the smallest electronic devices.
Humans have drawn technological inspiration from fish scales going back to ancient times: Romans, Egyptians, and other civilizations would dress their warriors in scale armor, providing both protection and mobility. Now, using advanced X-ray imaging techniques, Berkeley Lab scientists have characterized carp scales down to the nanoscale, enabling them to understand how the material is resistant to penetration while retaining flexibility.