3D Gravity in a Box
Abstract
The quantization of pure 3D gravity with Dirichlet boundary conditions on a finite boundary is of interest both as a model of quantum gravity in which one can compute quantities which are "more local" than S-matrices or asymptotic boundary correlators, and for its proposed holographic duality to -deformed CFTs. In this work we apply covariant phase space methods to deduce the Poisson bracket algebra of boundary observables. The result is a one-parameter nonlinear deformation of the usual Virasoro algebra of asymptotically AdS gravity. This algebra should be obeyed by the stress tensor in any -deformed holographic CFT. We next initiate quantization of this system within the general framework of coadjoint orbits, obtaining - in perturbation theory - a deformed version of the Alekseev-Shatashvili symplectic form and its associated geometric action. The resulting energy spectrum is consistent with the expected spectrum of -deformed theories, although we only carry out the explicit comparison to in the expansion.
Cite
@article{arxiv.2103.13398,
title = {3D Gravity in a Box},
author = {Per Kraus and Ruben Monten and Richard M. Myers},
journal= {arXiv preprint arXiv:2103.13398},
year = {2021}
}
Comments
59 pages, corrected typos and minus signs. This is the published version