Black hole thermodynamical entropy
Abstract
As early as 1902, Gibbs pointed out that systems whose partition function diverges, e.g. gravitation, lie outside the validity of the Boltzmann-Gibbs (BG) theory. Consistently, since the pioneering Bekenstein-Hawking results, physically meaningful evidence (e.g., the holographic principle) has accumulated that the BG entropy of a black hole is proportional to its area ( being a characteristic linear length), and not to its volume . Similarly it exists the \emph{area law}, so named because, for a wide class of strongly quantum-entangled -dimensional systems, is proportional to if , and to if , instead of being proportional to (). These results violate the extensivity of the thermodynamical entropy of a -dimensional system. This thermodynamical inconsistency disappears if we realize that the thermodynamical entropy of such nonstandard systems is \emph{not} to be identified with the BG {\it additive} entropy but with appropriately generalized {\it nonadditive} entropies. Indeed, the celebrated usefulness of the BG entropy is founded on hypothesis such as relatively weak probabilistic correlations (and their connections to ergodicity, which by no means can be assumed as a general rule of nature). Here we introduce a generalized entropy which, for the Schwarzschild black hole and the area law, can solve the thermodynamic puzzle.
Keywords
Cite
@article{arxiv.1202.2154,
title = {Black hole thermodynamical entropy},
author = {Constantino Tsallis and Leonardo J. L. Cirto},
journal= {arXiv preprint arXiv:1202.2154},
year = {2013}
}
Comments
7 pages, 2 figures. Accepted for publication in EPJC