Thermal Decay without Information Loss in Horizonless Microstate Geometries

Abstract

We develop a new hybrid WKB technique to compute boundary-to-boundary scalar Green functions in asymptotically-AdS backgrounds in which the scalar wave equation is separable and is explicitly solvable in the asymptotic region. We apply this technique to a family of six-dimensional 18-BPS asymptotically AdS3\,×\,S3 horizonless geometries that have the same charges and angular momenta as a D1-D5-P black hole with a large horizon area. At large and intermediate distances, these geometries very closely approximate the extremal-BTZ\,×\,S3 geometry of the black hole, but instead of having an event horizon, these geometries have a smooth highly-redshifted global-AdS3\,×\,S3 cap in the IR. We show that the response function of a scalar probe, in momentum space, is essentially given by the pole structure of the highly-redshifted global-AdS3 modulated by the BTZ response function. In position space, this translates into a sharp exponential black-hole-like decay for times shorter than N1 N5, followed by the emergence of evenly spaced "echoes from the cap," with period N1 N5. Our result shows that horizonless microstate geometries can have the same thermal decay as black holes without the associated information loss.