School of Humanities and Sciences


Showing 1-19 of 19 Results

  • Shamit Kachru

    Shamit Kachru

    Professor of Physics and Director, Stanford Institute for Theoretical Physics, Emeritus

    Current Research and Scholarly InterestsMy current research is focused in three directions:

    — Mathematical aspects of string theory (with a focus on BPS state counts, black holes, and moonshine)

    — Quantum field theory approaches to condensed matter physics (with a focus on physics of non-Fermi liquids)

    — Theoretical biology, with a focus on evolution and ecology

  • Renata Kallosh

    Renata Kallosh

    Stanford W. Ascherman, MD Professor, Emerita

    BioWhat is the mathematical structure of supergravity/string theory and its relation to cosmology?

    Professor Kallosh works on the general structure of supergravity and string theory and their applications to cosmology. Her main interests are related to the models early universe inflation and dark energy in string theory. She develops string theory models explaining the origin of the universe and its current acceleration. With her collaborators, she has recently constructed de Sitter supergravity, which is most suitable for studies of inflation and dark energy and spontaneously broken supersymmetry.

    She is analyzing possible consequences of the expected new data from the Large Hadron Collider (LHC) and the results of current and future cosmological observations, including Planck satellite CMB data. These results may affect the relationship between superstring theory and supergravity, and the real world. Professor Kallosh works, in particular, on future tests of string theory by CMB data and effective supergravity models with flexible amplitude of gravitational waves produced during inflation.

  • Matthew Kanan

    Matthew Kanan

    Professor of Chemistry

    BioAssociate Professor of Chemistry Matthew Kanan develops new catalysts and chemical reactions for applications in renewable energy conversion and CO2 utilization. His group at Stanford University has recently developed a novel method to create plastic from carbon dioxide and inedible plant material rather than petroleum products, and pioneered the study of “defect-rich” heterogeneous electro-catalysts for converting carbon dioxide and carbon monoxide to liquid fuel.

    Matthew Kanan completed undergraduate study in chemistry at Rice University (B.A. 2000 Summa Cum Laude, Phi Beta Kappa). During doctoral research in organic chemistry at Harvard University (Ph.D. 2005), he developed a novel method for using DNA to discover new chemical reactions. He then moved into inorganic chemistry for his postdoctoral studies as a National Institutes of Health Postdoctoral Research Fellow at the Massachusetts Institute of Technology, where he discovered a water oxidation catalyst that operates in neutral water. He joined the Stanford Chemistry Department faculty in 2009 to continue research into energy-related catalysis and reactions. His research and teaching have already been recognized in selection as one of Chemistry & Engineering News’ first annual Talented 12, the Camille Dreyfus Teacher-Scholar Award, Eli Lilly New Faculty Award, and recognition as a Camille and Henry Dreyfus Environmental Mentor, among other honors.

    The Kanan Lab addresses fundamental challenges in catalysis and synthesis with an emphasis on enabling new technologies for scalable CO2 utilization. The interdisciplinary effort spans organic synthesis, materials chemistry and electrochemistry.

    One of the greatest challenges of the 21st century is to transition to an energy economy with ultra-low greenhouse gas emissions without compromising quality of life for a growing population. The Kanan Lab aims to help enable this transition by developing catalysts and chemical reactions that recycle CO2 into fuels and commodity chemicals using renewable energy sources. To be implemented on a substantial scale, these methods must ultimately be competitive with fossil fuels and petrochemicals. With this requirement in mind, the group focuses on the fundamental chemical challenge of making carbon–carbon (C–C) bonds because multi-carbon compounds have higher energy density, greater value, and more diverse applications that one-carbon compounds. Both electrochemical and chemical methods are being pursued. For electrochemical conversion, the group studies how defects known as grain boundaries can be exploited to improve CO2/CO electro-reduction catalysis. Recent work has unveiled quantitative correlations between grain boundaries and catalytic activity, establishing a new design principle for electrocatalysis, and developed grain boundary-rich copper catalysts with unparalleled activity for converting carbon monoxide to liquid fuel. For chemical CO2 conversion, the group is developing C–H carboxylation and CO2 hydrogenation reactions that are promoted by simple carbonate salts. These reactions provide a way to make C–C bonds between un-activated substrates and CO2 without resorting to energy-intensive and hazardous reagents. Among numerous applications, carbonate-promoted carboxylation enables the synthesis of a monomer used to make polyester plastic from CO2 and a feedstock derived from agricultural waste.

    In addition to CO2 chemistry, the Kanan group is pursuing new strategies to control selectivity in molecular catalysis for fine chemical synthesis. Of particular interest in the use of electrostatic interactions to discriminate between competing reaction pathways based on their charge distributions. This effort uses ion pairing or interfaces to control the local electrostatic environment in which a reaction takes place. The group has recently shown that local electric fields can control regioselectivity in isomerization reactions catalyzed by gold complexes.

  • Aharon Kapitulnik

    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).

  • Hemamala Karunadasa

    Hemamala Karunadasa

    J.G. Jackson and C.J. Wood Professor of Chemistry
    On Leave from 10/01/2024 To 12/31/2024

    BioProfessor Hema Karunadasa works with colleagues in materials science, earth science, and applied physics to drive the discovery of new materials with applications in clean energy. Using the tools of synthetic chemistry, her group designs materials that couple the structural tunability of organic molecules with the diverse electronic and optical properties of extended inorganic solids. This research targets materials such as sorbents for capturing environmental pollutants, phosphors for solid-state lighting, and absorbers for solar cells.

    Hemamala Karunadasa studied chemistry and materials science at Princeton University (A.B. with high honors 2003; Certificate in Materials Science and Engineering 2003), where her undergraduate thesis project with Professor Robert J. Cava examined geometric magnetic frustration in metal oxides. She moved from solid-state chemistry to solution-state chemistry for her doctoral studies in inorganic chemistry at the University of California, Berkeley (Ph.D. 2009) with Professor Jeffrey R. Long. Her thesis focused on heavy atom building units for magnetic molecules and molecular catalysts for generating hydrogen from water. She continued to study molecular electrocatalysts for water splitting during postdoctoral research with Berkeley Professors Christopher J. Chang and Jeffrey R. Long at the Lawrence Berkeley National Lab. She further explored molecular catalysts for hydrocarbon oxidation as a postdoc at the California Institute of Technology with Professor Harry B. Gray. She joined the Stanford Chemistry Department faculty in September 2012. Her research explores solution-state routes to new solid-state materials.

    Professor Karunadasa’s lab at Stanford takes a molecular approach to extended solids. Lab members gain expertise in solution- and solid-state synthetic techniques and structure determination through powder- and single-crystal x-ray diffraction. Lab tools also include a host of spectroscopic and electrochemical probes, imaging methods, and film deposition techniques. Group members further characterize their materials under extreme environments and in operating devices to tune new materials for diverse applications in renewable energy.

    Please visit the lab website for more details and recent news.

  • Chaitan Khosla

    Chaitan Khosla

    Wells H. Rauser and Harold M. Petiprin Professor and Professor of Chemistry and, by courtesy, of Biochemistry

    Current Research and Scholarly InterestsResearch in this laboratory focuses on problems where deep insights into enzymology and metabolism can be harnessed to improve human health.

    For the past two decades, we have studied and engineered enzymatic assembly lines called polyketide synthases that catalyze the biosynthesis of structurally complex and medicinally fascinating antibiotics in bacteria. An example of such an assembly line is found in the erythromycin biosynthetic pathway. Our current focus is on understanding the structure and mechanism of this polyketide synthase. At the same time, we are developing methods to decode the vast and growing number of orphan polyketide assembly lines in the sequence databases.

    For more than a decade, we have also investigated the pathogenesis of celiac disease, an autoimmune disorder of the small intestine, with the goal of discovering therapies and related management tools for this widespread but overlooked disease. Ongoing efforts focus on understanding the pivotal role of transglutaminase 2 in triggering the inflammatory response to dietary gluten in the celiac intestine.

  • Steven Kivelson

    Steven Kivelson

    Prabhu Goel Family Professor

    Current Research and Scholarly InterestsPast Graduate Students:

    Assa Auerbach - Professor of Physics, Technion University
    Weikang Wu - deceased.
    Shoucheng Zhang (final year) - deceased.
    Shivaji Sondhi - Wykham Professor of Physics, Oxford University
    Markku Salkola - Facebook, Menlo Park
    Vadim Oganesyan - Professor of Physics CUNY
    Kyrill Shtengle - Professor of Physics, UC Riverside
    Oron Zachar
    Zohar Nussinov - Professor of Physics, Washington University
    Erica W. Carlson - Professor of Physics, Purdue University
    Edward Sleva
    John Robertson - Citadel, Austin
    Wei-Feng Tsai
    Ian Bindloss
    Paul Oreto - Head of Machine Learning at Cantor Fitzgerald, New York
    Erez Berg - Professor of Physics, Weizmann Institute
    Hong Yao - Professor of Physics, Tsinghua University
    Li Liu
    George Karakonstantakis
    Sam Lederer
    Laimei Nie - Assistant Professor of Physics, Purdue University
    Ilya Esterlis - Assistant Professor, University of Wisconsin, Madison
    John Dodaro
    Chao Wang - Citadel LLC, New York
    Yue Yu - Post Doctoral Fellow, University of Wisconsin, Milwaukee
    Yuval Gannot - Google,

    Past Post Docs:

    Douglas Stone - Professor of Physics, Yale University
    Gergeley Zimanyi - Professor of Physics, UC Davis
    Dror Orgad - Professor of Physics, Tel Aviv University
    Hae-Young Kee - Professor of Physics, University of Toronto
    Oskar Vafek - Professor of Physics, University of Florida
    Eun-Ah Kim - Professor of Physics, Cornell University
    Srinivas Raghu - Professor of Physics, Stanford University
    Maisam Barkeshli - Professor of Physics, University of Maryland
    Michael Mulligan - Associate Professor of Physics, UC Riverside
    Pavan Hosur - Professor of Physics, University of Houston
    Yi Zhang - Professor of Physics, Tsinghua University
    Abulhassan Vaezi - Professor of Physics, Sharifi University
    Tomas Bzdusek - Professor of Physics, University of Zurich
    Jingyuan Chen - Assistant Professor of Physics, Tsinghua University
    Yoni Schattner - Research Scientist, Quantum Computing at the Amazon Center for
    Quantum Computing at Caltech, Pasadena
    John Sous - Assistant Professor of Chemistry, UCSD

    Past Undergraduate Research Assistants:

    Kevin S. Wang - Graduate student, Princeton University
    Jeffrey Chang - Graduate student, Harvard University
    Vijay Nathan Josephs - Undergraduate, Stanford University

    Unofficial Past Students and Post Docs:

    (i.e. where I believe I played the corresponding mentoring role, but the connection
    was unofficial - a shameless attempt to claim partial credit):
    Shoucheng Zhang - (did his final year of PhD work, the part in CMT, under my direction and
    worked with me extensively while a post doc)
    Jainendra Jain - (did the final portion of his PhD work, the part relevant to the quantum
    Hall effect, under my guidance and worked with me extensively while a post doc)
    Daniel Rokhsar - (No official connection at all, but did significant portion of both his
    graduate and post-doctoral research in collaboration with me.)
    Akash Maharaj - (was a student of Srinivas Raghu with whom he worked extensively, but
    he also did a significant portion of his graduate research in collaboration with me.)

  • Matthias Kling

    Matthias Kling

    Professor of Photon Science and, by courtesy, of Applied Physics

    Current Research and Scholarly InterestsKling's research focuses on ultrafast electronics and nanophotonics employing ultrashort flashes of light from table-top and free-electron laser sources.

  • Eric Kool

    Eric Kool

    George A. and Hilda M. Daubert Professor of Chemistry

    Current Research and Scholarly Interests• Design of cell-permeable reagents for profiling, modifying, and controlling RNAs
    • Developing fluorescent probes of DNA repair pathways, with applications in cancer, aging, and neurodegenerative disease
    • Discovery and development of small-molecule modulators of DNA repair enzymes, with focus on cancer and inflammation

  • Ron Kopito

    Ron Kopito

    Professor of Biology

    Current Research and Scholarly InterestsOur laboratory use state-of-the-art cell biological, genetic and systems-level approaches to understand how proteins are correctly synthesized, folded and assembled in the mammalian secretory pathway, how errors in this process are detected and how abnormal proteins are destroyed by the ubiquitin-proteasome system.

  • Chao-Lin Kuo

    Chao-Lin Kuo

    Professor of Physics and of Particle Physics and Astrophysics

    Current Research and Scholarly Interests1. Searching/measuring primordial gravitational waves in the CMB (Cosmic Microwave Background) through experiments at the South Pole (BICEP and SPT), high plateaus in Tibet (AliCPT) and Atacama (Simons Observatory), as well as in space (LiteBIRD).

    2. Development and applications of superconducting detector and readout systems in astrophysics, cosmology, and other areas.

    3. Novel detector concepts for axion searches (https://youtu.be/UBscQSFzpLE)