Entropy Corrections for Schwarzschild and Reissner-Nordstr\"om Black Holes

TL;DR

This paper derives entropy correction formulas for Schwarzschild and Reissner-Nordström black holes within a cavity, revealing how thermal fluctuations affect their thermodynamic stability and entropy in various dimensions.

Contribution

It provides the first-order entropy correction expressions for stable black holes in a cavity and extends the analysis to higher-dimensional Reissner-Nordström black holes, highlighting different correction behaviors.

Findings

Entropy corrections depend on cavity radius and black hole parameters.

Stable large-mass solutions have positive specific heat.

Higher-dimensional Reissner-Nordström black holes exhibit distinct correction characteristics.

Abstract

Schwarzschild black hole being thermodynamically unstable, corrections to its entropy due to small thermal fluctuations cannot be computed. However, a thermodynamically stable Schwarzschild solution can be obtained within a cavity of any finite radius by immersing it in an isothermal bath. For these boundary conditions, classically there are either two black hole solutions or no solution. In the former case, the larger mass solution has a positive specific heat and hence is locally thermodynamically stable. We find that the entropy of this black hole, including first order fluctuation corrections is given by: ${\cal S} = S_{BH} - \ln[\f{3}{R} (S_{BH}/4\p)^{1/2} -2]^{-1} + (1/2) \ln(4\p)$, where $S_{BH}=A/4$ is its Bekenstein-Hawking entropy and $R$ is the radius of the cavity. We extend our results to four dimensional Reissner-Nordstr\"om black holes, for which the corresponding expression is: ${\cal S} = S_{BH} - \f{1}{2} \ln [ {(S_{BH}/\p R^2) ({3S_{BH}}/{\p R^2} - 2\sqrt{{S_{BH}}/{\p R^2 -\a^2}}) \le(\sqrt{{S_{BH}}/{\p R^2}} - \a^2 \ri)}/ {\le({S_{BH}}/{\p R^2} -\a^2 \ri)^2} ]^{-1} +(1/2)\ln(4\p).$ Finally, we generalise the stability analysis to Reissner-Nordstr\"om black holes in arbitrary spacetime dimensions, and compute their leading order entropy corrections. In contrast to previously studied examples, we find that the entropy corrections in these cases have a different character.