Abstract
It has long been known that the coarse-grained approximation to the black hole density of states can be computed using classical Euclidean gravity. In this work we argue for another entry in the dictionary between Euclidean gravity and black hole physics, namely that Euclidean wormholes describe a coarse-grained approximation to the energy level statistics of black hole microstates. To do so we use the method of constrained instantons to obtain an integral representation of wormhole amplitudes in Einstein gravity and in full-fledged AdS/CFT. These amplitudes are non-perturbative corrections to the two-boundary problem in AdS quantum gravity. The full amplitude is likely UV sensitive, dominated by small wormholes, but we show it admits an integral transformation with a macroscopic, weakly curved saddle-point approximation. The saddle is the “double cone” geometry of Saad, Shenker, and Stanford, with fixed moduli. In the boundary description this saddle appears to dominate a smeared version of the connected two-point function of the black hole density of states, and suggests level repulsion in the microstate spectrum. Using these methods we further study Euclidean wormholes in pure Einstein gravity and in IIB supergravity on Euclidean AdS5× S5. We address the perturbative stability of these backgrounds and study brane nucleation instabilities in 10d supergravity. In particular, brane nucleation instabilities of the Euclidean wormholes are lifted by the analytic continuation required to obtain the Lorentzian spectral form factor from gravity. Our results indicate a factorization paradox in AdS/CFT.
Highlights
String theory and the AdS/CFT correspondence provide powerful frameworks for studying quantum mechanical aspects of black holes
In this work we argue for another entry in the dictionary between Euclidean gravity and black hole physics, namely that Euclidean wormholes describe a coarse-grained approximation to the energy level statistics of black hole microstates
Consider the original version of AdS/CFT for type IIB string theory on AdS5 ×S5 [3], where the AdS factor has an S3 spatial boundary. String theory on this background is dual to N = 4 super Yang-Mills on S3; this CFT has a large number of heavy states dual to black hole microstates, labeled by quantum numbers whose details are beyond our reach
Summary
String theory and the AdS/CFT correspondence provide powerful frameworks for studying quantum mechanical aspects of black holes. This technology allows us to obtain Euclidean wormhole amplitudes in four and higher dimensions that generalize those of JT and pure AdS3 gravity, and appear to encode the two-point energy level statistics of black hole microstates in a way consistent with level repulsion. Albeit more involved analysis for the paradigmatic example of AdS/CFT, type IIB string theory on AdS5×S5; we find gravitational constrained instantons in type IIB supergravity with N units of 5-form flux These are likewise wormholes which appear to encode level repulsion in black hole microstate statistics. As this manuscript was nearing completion we were made aware of the work of [30] which studies aspects of double cones and brane nucleation
Sign-in/Register to view highlights & summary Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a callDisclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.
