Computing black hole partition functions from quasinormal modes
Abstract
We propose a method of computing one-loop determinants in black hole spacetimes (with emphasis on asymptotically anti-de Sitter black holes) that may be used for numerics when completely-analytic results are unattainable. The method utilizes the expression for one-loop determinants in terms of quasinormal frequencies determined by Denef, Hartnoll and Sachdev in \cite{Denef:2009kn}. A numerical evaluation must face the fact that the sum over the quasinormal modes, indexed by momentum and overtone numbers, is divergent. A necessary ingredient is then a regularization scheme to handle the divergent contributions of individual fixed-momentum sectors to the partition function. To this end, we formulate an effective two-dimensional problem in which a natural refinement of standard heat kernel techniques can be used to account for contributions to the partition function at fixed momentum. We test our method in a concrete case by reproducing the scalar one-loop determinant in the BTZ black hole background. We then discuss the application of such techniques to more complicated spacetimes.
Cite
@article{arxiv.1603.08994,
title = {Computing black hole partition functions from quasinormal modes},
author = {Peter Arnold and Phillip Szepietowski and Diana Vaman},
journal= {arXiv preprint arXiv:1603.08994},
year = {2016}
}
Comments
49 pages, 2 figures. v2: Minor clarifications added to abstract and main text