Canonical Quantum Statistics of an Isolated Schwarzschild Black Hole with a Spectrum En = sigma sqrtn EP

Abstract

Many authors - beginning with Bekenstein - have suggested that the energy levels En of a quantized isolated Schwarzschild black hole have the form En = sigma sqrtn EP, n=1,2,..., sigma =O(1), with degeneracies gn. In the present paper properties of a system with such a spectrum, considered as a quantum canonical ensemble, are discussed: Its canonical partition function Z(g,beta=1/kT), defined as a series for g<1, obeys the 1-dimensional heat equation. It may be extended to values g>1 by means of an integral representation which reveals a cut of Z(g,beta) in the complex g-plane from g=1 to infinity. Approaching the cut from above yields a real and an imaginary part of Z. Very surprisingly, it is the (explicitly known) imaginary part which gives the expected thermodynamical properties of Schwarzschild black holes: Identifying the internal energy U with the rest energy Mc2 requires beta to have the value (in natural units) beta = 2M(lng/sigma2)[1+O(1/M2)], (4pi sigma2=lng gives Hawking's betaH), and yields the entropy S=[lng/(4pi sigma2)] A/4 + O(lnA), where A is the area of the horizon.

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