An entropic puzzle in periodic dilaton gravity and DSSYK

Author(s)

Blommaert, Andreas; Levine, Adam; Mertens, Thomas G.; Papalini, Jacopo; Parmentier, Klaas

Abstract

We study 2d dilaton gravity theories with a periodic potential, with special emphasis on sine dilaton gravity, which is holographically dual to double-scaled SYK. The periodicity of the potentials implies a symmetry under (discrete) shifts in the momentum conjugate to the length of geodesic slices. This results in divergences. The correct definition is to gauge this symmetry. This discretizes the geodesic lengths. Lengths below a certain threshold are null states. Because of these null states, the entropy deviates drastically from Bekenstein-Hawking and the Hilbert space becomes finite dimensional. The spacetimes have a periodic radial coordinate. These are toy models of 2d quantum cosmology with a normalizable wavefunction. We study two limiting dualities: one between flat space quantum gravity and the Heisenberg algebra, and one between topological gravity and the Gaussian matrix integral. We propose an exact density of states for certain classes of periodic dilaton gravity models.

Date issued

2025-07-07

URI

https://hdl.handle.net/1721.1/162475

Department

Massachusetts Institute of Technology. Center for Theoretical Physics

Journal

Journal of High Energy Physics

Publisher

Springer Berlin Heidelberg

Citation

Blommaert, A., Levine, A., Mertens, T.G. et al. An entropic puzzle in periodic dilaton gravity and DSSYK. J. High Energ. Phys. 2025, 93 (2025).

Version: Final published version