English

Mock modularity from black hole scattering states

High Energy Physics - Theory 2019-01-30 v1

Abstract

The exact degeneracies of quarter-BPS dyons in Type II string theory on K3×T2K3 \times T^2 are given by Fourier coefficients of the inverse of the Igusa cusp form. For a fixed magnetic charge invariant mm, the generating function of these degeneracies naturally decomposes as a sum of two parts, which are supposed to account for single-centered black holes, and two-centered black hole bound states, respectively. The decomposition is such that each part is separately modular covariant but neither is holomorphic, calling for a physical interpretation of the non-holomorphy. We resolve this puzzle by computing the supersymmetric index of the quantum mechanics of two-centered half-BPS black-holes, which we model by geodesic motion on Taub-NUT space subject to a certain potential. We compute a suitable index using localization methods, and find that it includes both a temperature-independent contribution from BPS bound states, as well as a temperature-dependent contribution due to a spectral asymmetry in the continuum of scattering states. The continuum contribution agrees precisely with the non-holomorphic completion term required for the modularity of the generating function of two-centered black hole bound states.

Keywords

Cite

@article{arxiv.1808.05606,
  title  = {Mock modularity from black hole scattering states},
  author = {Sameer Murthy and Boris Pioline},
  journal= {arXiv preprint arXiv:1808.05606},
  year   = {2019}
}
R2 v1 2026-06-23T03:36:08.100Z