Black Hole from Entropy Maximization
Abstract
One quantum characterization of a black hole motivated by (local) holography and thermodynamics is that it maximizes thermodynamic entropy for a given surface area. In the context of quantum gravity, this could be more fundamental than the classical characterization by a horizon. As a step, we explore this possibility by solving the 4D semi-classical Einstein equation with many matter fields. For highly-excited spherically-symmetric static configurations, we apply local typicality and estimate the entropy including self-gravity to derive its upper bound. The saturation condition uniquely determines the entropy-maximized configuration: self-gravitating quanta condensate into a radially-uniform dense configuration with no horizon, where the self-gravity and a large quantum pressure induced by the curvatures are balanced and no singularity appears. The interior metric is a self-consistent and non-perturbative solution in Planck's constant. The maximum entropy, given by the volume integral of the entropy density, agrees with the Bekenstein-Hawking formula through self-gravity, deriving the Bousso bound for thermodynamic entropy. Finally, 10 future prospects are discussed, leading to a speculative view that the configuration represents a quantum-gravitational condensate in a semi-classical manner.
Cite
@article{arxiv.2309.00602,
title = {Black Hole from Entropy Maximization},
author = {Yuki Yokokura},
journal= {arXiv preprint arXiv:2309.00602},
year = {2025}
}
Comments
23 pages, 6 figures. The accepted version in Phys. Rev. D. Modified Sec.4-C-1 and 4-C-2; clarified explanations; and added 1 figure, 3 footnotes and 2 references