Gary Horowitz

Gary T. Horowitz (born April 14, 1955 in Washington, D.C.) is an American theoretical physicist who works on string theory and quantum gravity.

Biography

Horowitz studied at Princeton University (Bachelor 1976) and obtained his Ph.D. in 1979 at the University of Chicago with Robert Geroch. Subsequently, he was a post-doc at the University of California, Santa Barbara and Oxford University (as a NATO Fellow). In 1981-1983 he worked as an Einstein Fellow at the Institute for Advanced Study. He became an Assistant Professor in 1983, Associate Professor in 1986, and finally Professor in 1990 at the University of California at Santa Barbara.

Horowitz investigates gravitational phenomena, such as black holes, in string theory. In the 1990s, he worked with, among others, Andrew Strominger[1] and Joseph Polchinski showing that string theory provides a description of the quantum microstates of certain black holes (following earlier work of Strominger and Cumrun Vafa ).[2]

In 1985 Horowitz published an influential paper with Philip Candelas, Andrew Strominger and Edward Witten on the compactification of superstrings in Calabi-Yau spaces.[3] In the early 1990s, Horowitz and Strominger found black brane solutions in string theory.[4] Horowitz also works on the AdS/CFT correspondence and (together with Sean Hartnoll and Chris Herzog) discovered holographic superconductors.[5]

In 1982 Horowitz and M. Perry won first prize in the Gravity Research Foundation essay competition. From 1985 to 1989 he was a Sloan Fellow. In 1993 he was awarded the Xanthopoulos Prize. He has been a Fellow of the American Physical Society since 2001 [6], Member of the National Academy of Sciences since 2010, and Fellow of the American Academy of Arts and Sciences since 2013.

Selected papers

  • Spacetime in string theory, 2004
  • Quantum gravity at the turn of the millennium, 9. Marcel Grossmann Meeting 2000
  • Horowitz, Gary T.; Hubeny, Veronika E. (2000). "Quasinormal modes of AdS black holes and the approach to thermal equilibrium". Physical Review D. 62 (2). arXiv:hep-th/9909056. Bibcode:2000PhRvD..62b4027H. doi:10.1103/PhysRevD.62.024027.
  • With S. Teukolsky: Black Holes, in S. Bederson (ed.): More things in heaven and earth - a celebration of physics at the millennium, Springer 1999
  • Quantum states of black holes, in Robert Wald (ed.): Black holes and relativistic stars, University of Chicago Press 1998
  • With Joseph Polchinski: Gauge/gravity duality, in D. Oriti: Approaches to quantum gravity, Cambridge University Press 2009

References

  1. Counting states of near extremal black holes, Phys. Rev. Lett., Bd.77, 1996, S.2368
  2. For general black holes, one can only show the proportionality of the logarithm of the number of string states to the surface area (which corresponds to the entropy), Horowitz, Polchinski A correspondence principle for black holes and strings, Physical Review D, Bd.55, 1997, S.6189
  3. Vacuum configuration of superstrings, Nuclear Physics B, Bd.258, 1985, S.46-76
  4. Horowitz, Strominger Black strings and p-branes, Nuclear Physics B, Bd.360, 1991, S.197-209
  5. Horowitz, Introduction to Holographic Superconductors, 2001, 5. Aegean Summer School
  6. "APS Fellow Archive". APS. Retrieved 18 September 2020.
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