Black Hole Quantum Mechanics and Generalized Error Functions

Abstract

In Type II Calabi-Yau string compactifications, S-duality predicts that suitable generating series of BPS indices counting microstates of D4-D2-D0 black holes are in general mock modular forms of higher depth. The non-holomorphic contributions needed to cancel the anomaly under modular transformations involve certain indefinite theta series with kernels constructed from generalized error functions. Physically, these contributions are expected to arise from a spectral asymmetry in the continuum of scattering states of n BPS dyons with mutually non-local charges. For n=2, the (standard, depth one) error function completion was derived long ago by explicitly computing the bosonic and fermionic density of states in the two-body supersymmetric quantum mechanics. Here we derive the general non-holomorphic completion for an arbitrary number of centers by evaluating the refined Witten index of the supersymmetric quantum mechanics using localization. In a nutshell, the index reduces to an integral over R3n-3 (the relative location of the centers), and splits into an integral over the 2n-2 dimensional phase space of BPS ground states times an integral over n-1 transverse directions, which ultimately produces the expected generalized error functions.