Quantum buoyancy, generalized second law, and higher-dimensional entropy bounds
Abstract
Bekenstein has presented evidence for the existence of a universal upper bound of magnitude to the entropy-to-energy ratio of an arbitrary {\it three} dimensional system of proper radius and negligible self-gravity. In this paper we derive a generalized upper bound on the entropy-to-energy ratio of a -dimensional system. We consider a box full of entropy lowered towards and then dropped into a -dimensional black hole in equilibrium with thermal radiation. In the canonical case of three spatial dimensions, it was previously established that due to quantum buoyancy effects the box floats at some neutral point very close to the horizon. We find here that the significance of quantum buoyancy increases dramatically with the number of spatial dimensions. In particular, we find that the neutral (floating) point of the box lies near the horizon only if its length is large enough such that , where is the Compton length of the body and for . A consequence is that quantum buoyancy severely restricts our ability to deduce the universal entropy bound from the generalized second law of thermodynamics in higher-dimensional spacetimes with . Nevertheless, we find that the universal entropy bound is always a sufficient condition for operation of the generalized second law in this type of gedanken experiments.
Cite
@article{arxiv.1101.3151,
title = {Quantum buoyancy, generalized second law, and higher-dimensional entropy bounds},
author = {Shahar Hod},
journal= {arXiv preprint arXiv:1101.3151},
year = {2011}
}
Comments
6 pages