The materials science and engineering researcher and an interdisciplinary team formed at the Research Corporation for Science Advancement's Scialog have received funding to investigate water-free mining of valuable metals like iron and lithium.
In collaboration with materials company Homerun Resources, Inc., UC Davis engineering researchers have developed a one-step laser technique that purifies raw silica sand to over 99.99% silica. This is the first step in a multiphase project to create a clean-energy pathway to producing silicon.
Researchers from UC Davis and Lawrence Livermore National Laboratory have developed deep-learning model ensembles to investigate the magnetic properties of perovskite oxide multilayers and gain key insights into how they might be used in next-generation electronic devices.
With a Seed Grant for International Activities from UC Davis Global Affairs, Professor of Materials Science and Engineering Yayoi Takamura is collaborating with researchers from Chile to use plasma-enhanced pulsed laser deposition to synthesize and characterize thin films for sustainable energy technologies.
Two Ph.D. candidates in materials science and engineering at UC Davis will reside at Lawrence Berkeley National Laboratory to conduct research as part of the U.S. Department of Energy Office of Science Graduate Student Research Program.
Assistant Professor of Materials Science and Engineering Scott McCormack is part of a multi-university team awarded $7.5 million over five years from the Department of Defense Multidisciplinary University Research Initiative, or MURI, program.
New research published in Physical Review Letters shows how an experiment with lasers and magnets resulted in the domain walls within ferromagnetic layers moving at previously unheard-of speeds, paving the way for more sustainable and energy-efficient data storage.
Materials science and engineering professor Marina Leite has received $1 million to make switchable photonic devices more efficient with hybrid perovskites, a class of materials with physical properties that can be controlled through light alone.
Marina Leite is on her fourth cell phone. A professor in the Department of Materials Science and Engineering at the University of California, Davis, and a Chancellor’s Fellow, Leite is holding out on upgrading her phone because tossing her old one would produce excess waste.
The inside of a living cell is crowded with large, complex molecules. New research on how these molecules could spontaneously organize themselves could further our understanding of how cells manage their essential biochemistry in the crowded space.