Stephen Hart Shenker (born 1953) is an American theoretical physicist who works on string theory. He is a professor at Stanford University and former director of the Stanford Institute for Theoretical Physics. His brother Scott Shenker is a computer scientist.
Stephen Shenker | |
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Born | 1953[1] |
Nationality | American |
Alma mater | Harvard University (B.A.) Cornell University (Ph.D.) |
Known for | string theory phase transitions |
Awards | MacArthur Fellowship American Academy of Arts and Sciences Lars Onsager Prize (2010) National Academy of Sciences Dirac Medal (2023) |
Scientific career | |
Fields | theoretical physics |
Institutions | Stanford University Rutgers University University of Chicago |
Doctoral advisor | John Kogut |
Doctoral students | Joanne Cohn Matthew Kleban |
Work
editShenker's contributions to physics include:
- Basic results on the phase structure of gauge theories (with Eduardo Fradkin)
- Basic results on two dimensional conformal field theory and its relation to string theory (with Daniel Friedan, Emil Martinec, Zongan Qiu, and others)
- The nonperturbative formulation of matrix models of low-dimensional string theory, the first nonperturbative definitions of string theory (with Michael R. Douglas)
- The discovery of distinctively stringy nonperturbative effects in string theory, later understood to be caused by D-branes. These effects play a major role in string dynamics
- The discovery of Matrix Theory, the first nonperturbative definition of String/M theory in a physical number of dimensions. Matrix Theory (see Matrix string theory) is an example of a gauge/gravity duality and is now understood to be a special case of the AdS/CFT correspondence (with Tom Banks, Willy Fischler and Leonard Susskind)
- Basic results on the connection between quantum gravity and quantum chaos (with Douglas Stanford, Juan Maldacena and others)
Selected works
edit- Fidkowski, Lukasz; Hubeny, Veronika; Kleban, Matthew; Shenker, Stephen (6 February 2004). "The Black Hole Singularity in AdS/CFT". Journal of High Energy Physics. 2004 (2): 014. arXiv:hep-th/0306170. Bibcode:2004JHEP...02..014F. doi:10.1088/1126-6708/2004/02/014. S2CID 119363210.