SLAC National Accelerator Laboratory
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Philip Schuster
Professor of Particle Physics and Astrophysics
BioProfessor Schuster is a theoretical physicist focused on identifying dark matter and its properties, developing concepts for new experimental tests of physics beyond the Standard Model, and studying novel theories of long-range forces. He is also directly involved in several experimental efforts as co-spokesperson for APEX, a founding member and physics coordinator for LDMX, and as a founding member of HPS.
Prospective graduate students interested in research rotations should contact Professor Schuster directly. Recent research directions include new ideas to detect axions, milli-charge dark matter, the use of novel accelerator experiments to search for light WIMP-like dark matter, and generalizations of gauge theories that include massless particles with continuous spin. Publications are listed on INSPIRE.
Professor Schuster is also chair of the Particle Physics & Astrophysics department at Stanford’s SLAC National Accelerator Laboratory. -
Sadasivan (Sadas) Shankar
Research Technical Manager, SLAC National Accelerator Laboratory
Current Role at StanfordResearch Technology Manager, Microelectronics
SLAC National Accelerator Laboratory
2575 Sand Hill Road
Menlo Park, CA 94025
sshankar@slac.stanford.edu
Adjunct Professor, Materials Science and Engineering
William F. Durand Building
496 Lomita Mall, Suite 102
Stanford University
Stanford, CA 94305
sadasivan.shankar@stanford.edu; sadas.shankar@stanford.edu -
Lingjia Shen
Associate Scientist, SLAC National Accelerator Laboratory
Current Role at StanfordStaff member at the Materials Science Department, Science, Research & Development, Linac Coherent Light Source
Scientist at the qRIXS instrument, Experimental Operations, Linac Coherent Light Source -
Dongjae Shin
Postdoctoral Scholar, Photon Science, SLAC
BioMy current research focuses on the design of catalytic materials. I have studied atomistic phenomena on catalytic surfaces to develop materials with improved catalytic capability under the philosophy of rational design. To achieve this goal, I use computational approaches, e.g., first-principles calculations and artificial intelligence (AI). Applications include heterogeneous catalysis for exhaust emission control, hydrogen production, and utilization of emission gas to realize carbon neutralization.
