School of Humanities and Sciences
Showing 1-100 of 178 Results
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Steven M. Block
The Stanford W. Ascherman, M.D., Professor and Professor of Applied Physics and of Biology, Emeritus
Current Research and Scholarly InterestsSingle molecule biophysics using optical trapping and fluorescence
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Charlotte Bøttcher
Acting Assistant Professor, Applied Physics
BioCharlotte is joining the Stanford faculty in 2025 as an assistant professor of Applied Physics. Charlotte received her BSc degree in physics in 2016 from the Niels Bohr institute in Copenhagen where she focused on studying quantum phases transitions in two-dimensional Josephson junction arrays. She then moved to the US and finished her PhD in physics at Harvard University in 2022. Her general passion is to work at the intersection between condensed matter physics and quantum information, and during her PhD Charlotte also spent time at IBM Quantum. After her PhD, she joined Qulab at Yale University as a postdoc where she worked on hybrid material systems for quantum information.
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Mark Brongersma
Stephen Harris Professor, Professor of Materials Science and Engineering and, by courtesy, of Applied Physics
BioMark Brongersma is a Professor in the Department of Materials Science and Engineering at Stanford University. He received his PhD in Materials Science from the FOM Institute in Amsterdam, The Netherlands, in 1998. From 1998-2001 he was a postdoctoral research fellow at the California Institute of Technology. During this time, he coined the term “Plasmonics” for a new device technology that exploits the unique optical properties of nanoscale metallic structures to route and manipulate light at the nanoscale. His current research is directed towards the development and physical analysis of nanostructured materials that find application in nanoscale electronic and photonic devices. Brongersma received a National Science Foundation Career Award, the Walter J. Gores Award for Excellence in Teaching, the International Raymond and Beverly Sackler Prize in the Physical Sciences (Physics) for his work on plasmonics, and is a Fellow of the Optical Society of America, the SPIE, and the American Physical Society.
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Philip Bucksbaum
Marguerite Blake Wilbur Professor of Natural Science and Professor of Photon Science, of Applied Physics and of Physics
BioPhil Bucksbaum holds the Marguerite Blake Wilbur Chair in Natural Science at Stanford University, with appointments in Physics, Applied Physics, and in Photon Science at SLAC. He conducts his research in the Stanford PULSE Institute (https://web.stanford.edu/~phbuck). He and his wife Roberta Morris live in Menlo Park, California. Their grown daughter lives in Toronto.
Bucksbaum was born and raised in Iowa, and graduated from Harvard in 1975. He attended U.C. Berkeley on a National Science Foundation Graduate Fellowship and received his Ph.D. in 1980 for atomic parity violation experiments under Professor Eugene Commins, with whom he also has co-authored a textbook, “Weak Interactions of Leptons and Quarks.” In 1981 he joined Bell Laboratories, where he pursued new applications of ultrafast coherent radiation from terahertz to vacuum ultraviolet, including time-resolved VUV ARPES, and strong-field laser-atom physics.
He joined the University of Michigan in 1990 and stayed for sixteen years, becoming Otto Laporte Collegiate Professor and then Peter Franken University Professor. He was founding Director of FOCUS, a National Science Foundation Physics Frontier Center, where he pioneered research using ultrafast lasers to control quantum systems. He also launched the first experiments in ultrafast x-ray science at the Advanced Photon Source at Argonne National Lab. In 2006 Bucksbaum moved to Stanford and SLAC, and organized the PULSE Institute to develop research utilizing the world’s first hard x-ray free-electron laser, LCLS. In addition to directing PULSE, he has previously served as Department Chair of Photon Science and Division Director for Chemical Science at SLAC. His current research is in laser interrogation of atoms and molecules to explore and image structure and dynamics on the femtosecond scale. He currently has more than 250 publications.
Bucksbaum is a Fellow of the APS and the Optical Society, and has been elected to the National Academy of Sciences and the American Academy of Arts and Sciences. He has held Guggenheim and Miller Fellowships, and received the Norman F. Ramsey Prize of the American Physical Society for his work in ultrafast and strong-field atomic and molecular physics. He served as the Optical Society President in 2014, and also served as the President of the American Physical Society in 2020. He has led or participated in many professional service activities, including NAS studies, national and international boards, initiatives, lectureships and editorships. -
Robert Byer
William R. Kenan, Jr. Professor, Emeritus
BioRobert L. Byer has served as President of The American Physical Society, of the Optical Society of America and of the IEEE LEOS. He has served as Vice Provost and Dean of Research at Stanford. He has been Chair of the Department of Applied Physics, Director of the Edward L. Ginzton Laboratory and Director of the Hansen Experimental Physics Laboratory. He is a founding member of the California Council on Science and Technology and served as Chair from 1995-1999. He was a member of the Air Force Scientific Advisory Board from 2002-2006 and has been a member of the National Ignition Facility since 2000.
Robert L. Byer has conducted research and taught classes in lasers and nonlinear optics at Stanford University since 1969. He has made extraordinary contributions to laser science and technology including the demonstration of the first tunable visible parametric oscillator, the development of the Q-switched unstable resonator Nd:YAG laser, remote sensing using tunable infrared sources and precision spectroscopy using Coherent Anti Stokes Raman Scattering (CARS). Current research includes precision laser measurements in support of the detection of gravitational waves and laser “Accelerator on a chip”. -
Debadri Das
Ph.D. Student in Applied Physics, admitted Autumn 2021
Current Research and Scholarly InterestsX-Ray Science; Atomic,Molecular and Optical Science; Quantum Information Science
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Xuehao Ding
Ph.D. Student in Applied Physics, admitted Autumn 2018
Current Research and Scholarly InterestsI am an Applied Physics PhD candidate in Baccus lab co-advised by Surya Ganguli. My research focuses on building encoding models of the retina with various biophysical properties especially for natural scenes and answering scientific questions based on computational models. I believe that the core problem in the field of sensory systems is to understand the representation manifold and I am achieving this goal with methods of differential geometry, deep learning, statistical physics, etc.
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Sebastian Doniach
Professor of Applied Physics and of Physics, Emeritus
Current Research and Scholarly InterestsStudy of changes in conformation of proteins and RNA using x-ray scattering
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Shanhui Fan
Joseph and Hon Mai Goodman Professor of the School of Engineering and Professor, by courtesy, of Applied Physics
BioFan's research interests are in fundamental studies of nanophotonic structures, especially photonic crystals and meta-materials, and applications of these structures in energy and information technology applications
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Daniel Fisher
David Starr Jordan Professor
Current Research and Scholarly InterestsEvolutionary & ecological dynamics & diversity, microbial, expt'l, & cancer
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Ian Fisher
Humanities and Sciences Professor, Professor of Applied Physics and, by courtesy, of Materials Science and Engineering
Current Research and Scholarly InterestsOur research focuses on the study of quantum materials with unconventional magnetic & electronic ground states & phase transitions. Emphasis on design and discovery of new materials. Recent focus on use of strain as a probe of, and tuning parameter for, a variety of electronic states. Interests include unconventional superconductivity, quantum phase transitions, nematicity, multipolar order, instabilities of low-dimensional materials and quantum magnetism.
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John Fox
Adjunct Professor
Current Research and Scholarly InterestsStanford University Research areas center on optimal control methods to improve energy
efficiency and resource allocation in plug-in hybrid vehicles. Stanford graduate courses
taught in laboratory techniques and electronic instrumentation. Undergraduate course
"Energy Choices for the 21st Century" -
Benjamin N. Frey
Ph.D. Student in Applied Physics, admitted Autumn 2022
BioIn May of 2022, I graduated as a Schulze Innovation Scholar from the University of St. Thomas (Saint Paul, MN).
I am interested in developing sensing and imaging technologies that can increase access to basic diagnostic healthcare. -
Surya Ganguli
Associate Professor of Applied Physics, Senior Fellow at the Stanford Institute for HAI and Associate Professor, by courtesy, of Neurobiology and of Electrical Engineering
Current Research and Scholarly InterestsTheoretical / computational neuroscience
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Griffin Glenn
Ph.D. Student in Applied Physics, admitted Autumn 2019
BioI am a PhD student in the Stanford Department of Applied Physics. My research, conducted in the SLAC National Accelerator Laboratory High Energy Density Science Division, focuses on developing sources of laser-driven ion and neutron beams using cryogenic liquid jet targets developed by our group.
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David Goldhaber-Gordon
Professor of Physics and, by courtesy, of Applied Physics
Current Research and Scholarly InterestsHow do electrons organize themselves on the nanoscale?
We know that electrons are charged particles, and hence repel each other; yet in common metals like copper billions of electrons have plenty of room to maneuver and seem to move independently, taking no notice of each other. Professor Goldhaber-Gordon studies how electrons behave when they are instead confined to tiny structures, such as wires only tens of atoms wide. When constrained this way, electrons cannot easily avoid each other, and interactions strongly affect their organization and flow. The Goldhaber-Gordon group uses advanced fabrication techniques to confine electrons to semiconductor nanostructures, to extend our understanding of quantum mechanics to interacting particles, and to provide the basic science that will shape possible designs for future transistors and energy conversion technologies. The Goldhaber-Gordon group makes measurements using cryogenics, precision electrical measurements, and novel scanning probe techniques that allow direct spatial mapping of electron organization and flow. For some of their measurements of exotic quantum states, they cool electrons to a fiftieth of a degree above absolute zero, the world record for electrons in semiconductor nanostructures. -
Benjamin Good
Assistant Professor of Applied Physics
BioBenjamin Good is a theoretical biophysicist with a background in experimental evolution and population genetics. He is interested in the short-term evolutionary dynamics that emerge in rapidly evolving microbial populations like the gut microbiome. Technological advances are revolutionizing our ability to peer into these evolving ecosystems, providing us with an increasingly detailed catalog of their component species, genes, and pathways. Yet a vast gap still remains in understanding the population-level processes that control their emergent structure and function. Our group uses tools from statistical physics, population genetics, and computational biology to understand how microscopic growth processes and genome dynamics at the single cell level give rise to the collective behaviors that can be observed at the population level. Projects range from basic theoretical investigations of non-equilibrium processes in microbial evolution and ecology, to the development of new computational tools for measuring these processes in situ in both natural and experimental microbial communities. Through these specific examples, we seek to uncover unifying theoretical principles that could help us understand, forecast, and eventually control the ecological and evolutionary dynamics that take place in these diverse scenarios.
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Areeq Hasan
Ph.D. Student in Applied Physics, admitted Autumn 2024
Current Research and Scholarly InterestsInterested in the fundamental physics of strongly-correlated quantum many-body systems and creating new ways to control their dynamics. Intending to use the experimental platform of ultracold atoms to explore how nature invokes entanglement in the physics of many-body systems and build new ways to control the coherent quantum dynamics of strongly-correlated systems towards the end of quantum information processing.
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Tony Heinz
Professor of Applied Physics, of Photon Science, and, by courtesy, of Electrical Engineering
Current Research and Scholarly InterestsElectronic properties and dynamics of nanoscale materials, ultrafast lasers and spectroscopy.
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Lambertus Hesselink
Professor of Electrical Engineering and, by courtesy of Applied Physics
BioHesselink's research encompasses nano-photonics, ultra high density optical data storage, nonlinear optics, optical super-resolution, materials science, three-dimensional image processing and graphics, and Internet technologies.
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Andrew James Howard
Ph.D. Student in Applied Physics, admitted Autumn 2019
BioAndrew J. Howard received his B.S. in Optics from the University of Rochester in 2019. During his time at Rochester, he served as a Research Assistant in the ultrafast group at the Laboratory for Laser Energetics. He was awarded the Charles L. Newton Prize for his work. In late 2019, Howard enrolled in the Applied Physics Ph.D. program at Stanford University and was named the Albion Walter Hewlett Fellow. Here he studies experimental strong-field physics and ultrafast laser-driven molecular dynamics. He currently specializes in 3D fragment-momentum imaging, in which the three-dimensional momentum of molecular fragments produced during the interaction between a laser and a molecule yields valuable information about femtosecond molecular processes and light-matter interactions.
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Aharon Kapitulnik
Theodore and Sydney Rosenberg Professor of Applied Physics and Professor of Physics
BioAharon Kapitulnik is the Theodore and Sydney Rosenberg Professor in Applied Physics at the Departments of Applied Physics and Physics at Stanford University. His research focuses on experimental condensed matter physics, while opportunistically, also apply his methods to tabletop experimental studies of fundamental phenomena in physics. His recent studies cover a broad spectrum of phenomena associated with the behavior of correlated and disordered electron systems, particularly in reduced dimensions, and the development of effective instrumentation to detect subtle signatures of physical phenomena.
Among other recognitions, his activities earned him the Alfred P. Sloan Fellowship (1986-90), a Presidential Young Investigator Award (1987-92), a Sackler Scholar at Tel-Aviv University (2006), the Heike Kamerlingh Onnes Prize for Superconductivity Experiment (2009), a RTRA (Le Triangle de la Physique) Senior Chair (2010), and the Oliver Buckley Condensed Matter Prize of the American Physical Society (2015). Aharon Kapitulnik is a Fellow of the American Physical Society, a Fellow of the American Academy of Arts and Sciences, a Fellow of the American Association for the Advancement of Science and a member of the National Academy of Sciences. Kapitulnik holds a Ph.D. in Physics from Tel-Aviv University (1984). -
Brian Lantz
Professor (Research) of Applied Physics
Current Research and Scholarly InterestsMeasure gravitational waves
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Benjamin Lev
Professor of Applied Physics and of Physics
Current Research and Scholarly InterestsLevLab is a joint AMO & CM experimental group that explores the question: Can new classes of states and phases of quantum matter be created far away from equilibrium, and if so, what do we learn? We use our new technique, confocal cavity QED, to both engineer out-of-equilibrium quantum gases and 2D materials and to image and control their new properties.
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Qitong Li
Postdoctoral Scholar, Applied Physics
BioI am an experimental and applied physicist, focusing on extreme light-matter interaction at the nanoscale. I am currently working with Prof. Tony F. Heinz as a postdoctoral researcher in the Department of Applied Physics at Stanford University. Before my current position, I obtained my Ph.D. in Materials Science and Engineering from Stanford University in 2022 under the guidance of Prof. Mark L. Brongersma and my B.Sc. in Physics from Peking University in 2016.
My research concentrates on developing platforms with state-of-the-art tailored (optically resonant) nanostructures to achieve improved control over the photon-electron interaction at the nanoscale. This immediately allows us to create novel photonic and optoelectronic device concepts by coupling free-space lights into a series of well-engineered quantized optical modes and co-engineering electronic and optical components together. We therefore foresee a system-level revolution in industry enabled by nanotechnology. On the other hand, by providing a non-trivial and tunable optical, electrical, and mechanical nano-environment, this platform also fundamentally functions as a versatile tool and offers a new degree of freedom to better probe, study, and control various quantum properties and excitations in solids, especially those enhanced ones in low-dimensional materials. This will ultimately lead us to have a clearer understanding of unconventional phenomena in quantum materials and start to utilize them in a more controllable way. -
Kaden Loring
Ph.D. Student in Applied Physics, admitted Autumn 2021
BioKaden Loring began his PhD in Applied Physics at Stanford University in September 2021. Loring's research specialization is laser-based diagnostics for fusion-relevant plasmas. Loring received his bachelor's degree from the University of Florida in May 2020 in Physics. He is passionate about research aimed at the development of nuclear fusion for energy. In his free-time, Loring enjoys spending time in nature whenever possible.
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Brendan Patrick Marsh
Ph.D. Student in Applied Physics, admitted Autumn 2018
BioBrendan Marsh is a Ph.D. candidate in Professor Benjamin Lev’s research group at Stanford University. He investigates light-matter interactions in many-body quantum systems and explores their use as a computational resource. His work more generally includes experimental quantum optics and theoretical methods to describe open quantum systems. He received a master’s degree in applied mathematics and theoretical physics from the University of Cambridge in 2018 and a B.S. in physics and mathematics from the University of Missouri in 2017.
Besides quantum optics and computation, Brendan has worked on problems in the philosophy of quantum theory (with Jeremy Butterfield at the University of Cambridge) and single molecule biophysics (with Gavin King at the University of Missouri). Along with Gavin King, he invented the Hessian blob algorithm, a general-purpose machine vision algorithm which is finding applications in fields ranging from scanning probe microscopy to medical imaging.