SLAC National Accelerator Laboratory
Showing 61-80 of 88 Results
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Dr. Christopher T. Parzyck
Postdoctoral Scholar, Photon Science, SLAC
BioMy research interests lie at the intersection of materials science and condensed matter physics. I work on thin film synthesis of oxide and metal systems by molecular-beam epitaxy (MBE). Applications range from answering fundamental physics questions about high temperature superconductivity to developing practical synthesis routines and new materials for next generation electron sources. In addition, I work on projects involving spectroscopic probes of thin film systems, including angle-resolved photoemission spectroscopy (ARPES) and resonant soft x-ray scattering (RSXS) measurements.
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Laura Pereira Sanchez
Postdoctoral Scholar, Particle Physics and Astrophysics, SLAC National Accelerator Laboratory
BioThe composition of the Universe and the interplay of its various forces and matter have always fascinated me. My journey into particle physics began when I joined the ATLAS Collaboration during master's. Since then, I have analyzed data from proton-proton collisions at the Large Hadron Collider (LHC), where I've been looking for novel particles and deviations from theoretical predictions. At Stanford, I study the shape of the Higgs potential. I apply state-of-the-art machine learning techniques to measure the production of Higgs boson pairs using data from the ongoing LHC run and study if the shape of the Higgs potential differs considerably from that predicted by the Standard Model (SM). Furthermore, I work on the upgrade of the ATLAS inner-tracking detector for the future High Luminosity LHC (HL-LHC), which will be crucial to study the Higgs potential if its shape aligns with the SM predictions.
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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.
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Ruyi Song
Postdoctoral Scholar, Photon Science, SLAC
BioPh.D. in Theoretical and Computational Chemistry / Materials Science
B.S. in Theoretical and Computational Chemistry / Chemical Biology
18+ high-profile publications (Nat. Chem., Nat. Commun., Phys. Rev., JACS, etc.)
1000+ citations.
Proficient in 1) quantum chemistry simulation; 2) quantum chemistry code development; 3) molecular mechanics simulation
6 years of research experience on DFT and solid-state materials/semiconductors;
5 years of research experience on MD and biological systems.
Recently march towards Machine-Learning-aided molecular simulation, property prediction, and material discovery.
Contact: ruyi.song AT stanford.edu