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Tsvi Piran

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Tsvi Piran
Born (1949-05-06) May 6, 1949 (age 75)
Tel Aviv, Israel
Alma materThe Hebrew University of Jerusalem
SpouseDalia S. Goldwirth
AwardsThe EMET Prize for Art, Science and Culture
Scientific career
FieldsTheoretical Physics and Astrophysics
InstitutionsThe Hebrew University of Jerusalem
Doctoral advisorJacob Shaham and Joseph Katz
Notable studentsAmos Ori

Tsvi Piran (born May 6, 1949) is an Israeli theoretical physicist and astrophysicist, best known for his work on Gamma-ray Bursts (GRBs) and on numerical relativity. The recipient of the 2019 EMET prize award in Physics and Space Research.

At a time when most astronomers believed that GRBs were galactic (see however an earlier suggestion by Bohdan Paczynski [1]) with Eichler, Livio and Schramm, Piran proposed that GRBs originate from cosmological neutron star binary mergers,[2] a model that is generally accepted today. During the early nineties when the cosmological vs. galactic debate took place, Piran was one of the strongest and most vocal proponents of cosmological origin,[3] which was confirmed in 1997 with the discovery of cosmological redshifts from GRB's afterglow. Even before the cosmological origin of GRBs was discovered Piran laid the foundation to the generally accepted cosmic fireball model.[4] He suggested that GRBs herald the formation of a newborn black hole.[5][6] Later on, together with Re'em Sari and other collaborators, Piran further developed the theory of GRB afterglows,[7] in a paper which has by now more than 1000 citations, and of GRB jets.[8] His review papers[9][10] are the standard literature on this subject.

Before working on GRBs, Piran made important contributions to numerical relativity, the numerical solution of Einstein's equations. In 1985 he wrote the first numerical code calculating the collapse and formation of a rotating black hole[11] and the resulting gravitational radiation waveform. This waveform shows relaxation towards the quasinormal modes of the black hole that forms. Detection of this waveform in the future by advanced gravitational radiation detectors might provide the ultimate proof of the existence of a black hole.

In addition to these works, Piran's contributions range over a selection of problems in Relativistic Astrophysics. He demonstrated the critical dependence of the stability of accretion disks on the cooling and heating mechanisms. Piran was the first to point out that inflation is a generic phenomenon involving any scalar field (without requiring a specific potential)[12] and, in particular, that this is so for a free massive scalar field. He went on later to show that, in fact, the onset of inflation is not fully generic and it requires specific initial conditions,[13] a concept whose full implications have not been addressed up to now. He was the first to suggest and show that cosmic biasing depends on galaxy types and that different galaxies are distributed differently in the Universe. This is a concept that seems obvious today but was controversial when proposed in the late eighties.[14] Piran's work includes also contributions to the general theory of relativity such as one of the strongest counter examples to the cosmic censorship hypothesis[15] and the demonstration of the instability of the inner structure of a black hole.[16]

In addition to Piran's work as an astrophysicist, he has served from 2005 until 2009 as the dean of the Hebrew University School of Business Administration. During this term he has made revisions in the school.

Chronology

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  • 1967-1970: (undergraduate student) Mathematics and Physics, Tel Aviv University
  • 1970-1972: Military Service and MSc studies Space Sciences, Tel Aviv University under the guidance of A. Eviatar.
  • 1970-1976: Military Service and PhD thesis under the supervision of J. Shaham and J. Katz at the Hebrew University of Jerusalem: Penrose process and on modeling of GRBs from instabilities around black holes.
  • 1976-1977: Research Associate at Oxford with Dennis Sciama's group: accretion disks instabilities and winds
  • 1977-1979: Research associate and later Assistant Prof. at the University of Texas at Austin with Bryce DeWitt's group: foundation of Numerical Relativity, jets in AGNs.
  • 1980-1987: Long term member at the Institute for Advanced Study in Princeton, NJ and a faculty at the Hebrew University of Jerusalem: Numerical Relativity, Rotating gravitational collapse, Inflation, Galaxy biasing, neutrinos from SN 1987A
  • 1988-1990: The Hebrew University: Gamma-ray Bursts
  • 1990-1993: CFA Harvard: Gamma-Ray Bursts
  • 1998-1999: Visiting Prof. Columbia University and NYU
  • 2000- :Astronomical limits on Lorentz invariance violation
  • 2004-2005: Moore Scholar Caltech
  • 2005-2009: Dean Hebrew University School of Business Administration
  • 2009- :ERC Advanced Research Grant

Honors

[edit]
  • Landau Prize for a distinguished PhD thesis - 1976
  • Distinguished Moore Fellowship Caltech - 2005
  • ERC Advanced Research Grant - 2009
  • ERC Advanced Research Grant - 2016
  • EMET Prize, Israel, 2019

References

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  1. ^ Paczynski, Bohdan (1986). "Gamma-ray bursters at cosmological distances". Astrophysical Journal Letters. 305: L43–L46. Bibcode:1996ApJ...365L..55S. doi:10.1086/184740.
  2. ^ Eichler, D.; Livio, M.; Piran, T. & Schramm, D. (1988). "Nucleosynthesis, neutrino bursts and gamma-rays from coalescing neutron stars". Nature. 340 (6229): 126–128. Bibcode:1989Natur.340..126E. doi:10.1038/340126a0. S2CID 4357406.
  3. ^ Piran, T. (1995). Bahcall, J.; Ostriker J. (eds.). "Towards Understanding Gamma-Ray Bursts". Nature. 340 (6229): 126–128. Bibcode:1989Natur.340..126E. doi:10.1038/340126a0. S2CID 4357406.
  4. ^ Shemi, Amotz; Piran, Tsvi (1990). "The appearance of cosmic fireballs". Astrophysical Journal Letters. 365: 55–88. Bibcode:1990ApJ...365L..55S. doi:10.1086/185887.
  5. ^ Piran, T. (1994). Gerald J. Fishman (ed.). Fireballs. in Proceedings of the 2nd Workshop held in Huntsville, Alabama, October 1993, New York: American Institute of Physics (AIP), AIP Conference Proceedings. Vol. 307. p. 495. Bibcode:1994AIPC..307..495P. doi:10.1063/1.45856.
  6. ^ "In Cosmic Blasts, Clues to Black Holes (Published 1999)". The New York Times.
  7. ^ Sari, Re'em; Piran, Tsvi; Narayan, Ramesh (1998). "Spectra and Light Curves of Gamma-Ray Burst Afterglows". Astrophysical Journal Letters. 497 (1): 17–20. arXiv:astro-ph/9712005. Bibcode:1998ApJ...497L..17S. doi:10.1086/311269. S2CID 16691949.
  8. ^ Sari, Re'em; Piran, Tsvi; Halpern, J. P. (1999). "Jets in gamma-ray bursts". Astrophysical Journal Letters. 519 (1): 17–20. arXiv:astro-ph/9903339. Bibcode:1999ApJ...519L..17S. doi:10.1086/312109. S2CID 120591941.
  9. ^ Piran, Tsvi (1999). "Gamma-ray bursts and the fireball model". Physics Reports. 314 (6): 575–667. arXiv:astro-ph/9810256. Bibcode:1999PhR...314..575P. doi:10.1016/S0370-1573(98)00127-6. S2CID 9868536.
  10. ^ Piran, Tsvi (2004). "The physics of gamma-ray bursts". Reviews of Modern Physics. 76 (4): 1143–1210. arXiv:astro-ph/0405503. Bibcode:2004RvMP...76.1143P. doi:10.1103/RevModPhys.76.1143. S2CID 118941182.
  11. ^ Stark, R. F. & Piran, T. (1985). "Gravitational-wave emission from rotating gravitational collapse". Physical Review Letters. 55 (8): 891–894. Bibcode:1985PhRvL..55..891S. doi:10.1103/PhysRevLett.55.891. PMID 10032474.
  12. ^ Piran, Tsvi & Williams, Ruth M. (1985). "Inflation in universes with a massive scalar field". Physics Letters B. 163 (5–6): 331–335. Bibcode:1985PhLB..163..331P. doi:10.1016/0370-2693(85)90291-6.
  13. ^ Goldwirth, Dalia S. & Piran, Tsvi (1992). "Initial conditions for inflation". Physics Reports. 214 (4): 223–292. Bibcode:1992PhR...214..223G. doi:10.1016/0370-1573(92)90073-9.
  14. ^ Lahav, Ofer; Nemiroff; Robert J. & Piran, Tsvi (1990). "Relative bias parameters from angular correlations of optical and IRAS galaxies". Astrophysical Journal. 350: 119–124. Bibcode:1990ApJ...350..119L. doi:10.1086/168366.
  15. ^ Ori, Amos & Piran, Tsvi (1990). "Naked singularities and other features of self-similar general-relativistic gravitational collapse". Physical Review D. 42 (4): 1068–1090. Bibcode:1990PhRvD..42.1068O. doi:10.1103/PhysRevD.42.1068. PMID 10012941.
  16. ^ Hod, Shahar & Piran, Tsvi (1998). "Mass Inflation in Dynamical Gravitational Collapse of a Charged Scalar Field". Physical Review Letters. 81 (8): 1554–1557. arXiv:gr-qc/9803004. Bibcode:1998PhRvL..81.1554H. doi:10.1103/PhysRevLett.81.1554. S2CID 15288884.