Black Hole Emission in String Theory and the String Phase of Black Holes

Abstract

String theory properly describes black-hole evaporation. The quantum string emission by Black Holes is computed. The black-hole temperature is the Hawking temperature in the semiclassical quantum field theory (QFT) regime and becomes the intrinsic string temperature, Ts, in the quantum (last stage) string regime. The QFT-Hawking temperature TH is upper bounded by the string temperature TS. The black hole emission spectrum is an incomplete gamma function of (TH - TS). For TH << TS, it yields the QFT-Hawking emission. For TH TS, it shows highly massive string states dominate the emission and undergo a typical string phase transition to a microscopic `minimal' black hole of mass M or radius r (inversely proportional to TS) and string temperature TS. The string back reaction effect (selfconsistent black hole solution of the semiclassical Einstein equations) is computed. Both, the QFT and string black hole regimes are well defined and bounded.The string `minimal' black hole has a life time taumin simeq (kB c)/(G hbar [TS]3). The semiclassical QFT black hole (of mass M and temperature TH) and the string black hole (of mass Mmin and temperature TS) are mapped one into another by a `Dual' transform which links classical/QFT and quantum string regimes.

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