Exact holography and black hole entropy in N=8 and N=4 string theory

TL;DR

This paper calculates the exact entropy of certain BPS black holes in N=8 and N=4 string theories using localization techniques, linking supergravity, Chern-Simons anomalies, and microscopic models to confirm holographic principles.

Contribution

It provides a first-principles derivation of the localization measure for black hole entropy in supergravity, including instanton effects and matching microscopic results.

Findings

Derived the measure for supergravity localization integrals.

Matched the measure with microscopic black hole entropy calculations.

Included instantonic contributions consistent with microscopic models.

Abstract

We compute the exact entropy of one-eighth and one-quarter BPS black holes in N=8 and N=4 string theory respectively. This includes all the N=4 CHL models in both K3 and T^4 compactifications. The main result is a measure for the finite dimensional integral that one obtains after localization of supergravity on AdS_2xS^2. This measure is determined entirely by an anomaly in supersymmetric Chern-Simons theory on local AdS_3 and takes into account the contribution from all the supergravity multiplets. In Chern-Simons theory on compact manifolds this is the anomaly that computes a certain one-loop dependence on the volume of the manifold. For one-eighth BPS black holes our results are a first principles derivation of a measure proposed in arXiv:1111.1161, while in the case of one-quarter BPS black holes our result computes exactly all the perturbative or area corrections. Moreover, we argue that instantonic contributions can be incorporated and give evidence by computing the measure which matches precisely the microscopics. Along with this, we find an unitary condition that truncates the answer to a finite sum of instantons in perfect agreement with a microscopic formula. Our results solve a number of puzzles related to localization in supergravity and constitute a larger number of examples where holography can be shown to hold exactly.