Quantum strings and black holes

Abstract

The transition between (non supersymmetric) quantum string states and Schwarzschild black holes is discussed. This transition occurs when the string coupling g2 (which determines Newton's constant) increases beyond a certain critical value gc2. We review a calculation showing that self-gravity causes a typical string state of mass M to shrink, as the string coupling g2 increases, down to a compact string state whose mass, size, entropy and luminosity match (for the critical value gc2 (M α')-1) those of a Schwarzschild black hole. This confirms the idea (proposed by several authors) that the entropy of black holes can be accounted for by counting string states. The level spacing of the quantum states of Schwarzschild black holes is expected to be exponentially smaller than their radiative width. This makes it very difficult to conceive (even Gedanken) experiments probing the discreteness of the quantum energy levels of black holes.

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