A team of scientists led by Berkeley Lab has developed a library of artificial proteins or “peptoids” that effectively “chelate” or bind to lanthanides and actinides, heavy metals that make up the so-called f-block elements at the bottom of the periodic table. The new library offers researchers an automated, high-throughput method for precisely designing new
Scientists at Berkeley Lab are the first to use cryogenic electron microscopy (cryo-EM) to image atomic changes in artificial proteins known as “peptoids.” Their findings have implications for the synthesis of soft, 2D materials for a wide variety of applications.
To better understand how a liquid interacts with the surface of a solid, Berkeley Lab researchers developed a platform to explore these interactions under real conditions at the nanoscale using a technique that combines infrared light with an atomic-scale probe.
Scientists at Berkeley Lab have revealed how atomic defects emerge in TMDs (transition metal dichalcogenides), and how those defects shape the 2D material’s electronic properties. Their findings could provide a versatile yet targeted platform for designing 2D materials for quantum information science.
Scientists at Berkeley Lab have designed an affordable ‘flow battery’ membrane that could accelerate renewable energy for the electrical grid.
A new test agent can easily and efficiently detect the misfolded protein aggregates that cause devastating neurological diseases in blood samples. The technology could lead to early diagnosis of prion, Alzheimer’s, and Parkinson’s diseases for the first time.
Scientists at Berkeley Lab have demonstrated how a powerful electron microscopy technique can provide direct insight into the performance of any material – from strong metallic glass to flexible semiconducting films – by pinpointing specific atomic “neighborhoods.”
Berkeley Lab researchers are pushing the boundaries of electron microscopy by exploring the exciting new frontier of cold microscopes.
Scientists at Berkeley Lab have gained valuable insight into why 3D transition-metal-oxide nanoparticles can easily grow into 2D nanosheets. Their findings could revolutionize the design of materials with surface-enhanced properties for energy storage and catalysis applications.
A Q&A with scientist Jeff Urban, who explains forward osmosis and how Berkeley Lab is pushing the frontiers of this emerging technology.