JT gravity with matter, generalized ETH, and Random Matrices

TL;DR

This paper explores a duality between JT gravity coupled to matter and a two-matrix model, analyzing how matrix elements relate to gravitational correlators and generalizing ETH, with implications for understanding quantum gravity and matrix model stability.

Contribution

It introduces a duality between JT gravity with matter and a two-matrix model, and develops methods to reproduce gravitational correlators using matrix models, including a generalized ETH framework.

Findings

Matching of matrix model correlators to gravitational path integrals.

Construction of matrix models reproducing disk and cylinder correlators.

Identification of UV divergences indicating perturbative instability.

Abstract

We present evidence for a duality between Jackiw-Teitelboim gravity minimally coupled to a free massive scalar field and a single-trace two-matrix model. One matrix is the Hamiltonian $H$ of a holographic disorder-averaged quantum mechanics, while the other matrix is the light operator $\cal O$ dual to the bulk scalar field. The single-boundary observables of interest are thermal correlation functions of $\cal O$. We study the matching of the genus zero one- and two-boundary expectation values in the matrix model to the disk and cylinder Euclidean path integrals. The non-Gaussian statistics of the matrix elements of $\cal O$ correspond to a generalization of the ETH ansatz. We describe multiple ways to construct double-scaled matrix models that reproduce the gravitational disk correlators. One method involves imposing an operator equation obeyed by $H$ and $\cal O$ as a constraint on the two matrices. Separately, we design a model that reproduces certain double-scaled SYK correlators that may be scaled once more to obtain the disk correlators. We show that in any single-trace, two-matrix model, the genus zero two-boundary expectation value, with up to one $\cal O$ insertion on each boundary, can be computed directly from all of the genus zero one-boundary correlators. Applied to the models of interest, we find that these cylinder observables depend on the details of the double-scaling limit. To the extent we have checked, it is possible to reproduce the gravitational double-trumpet, which is UV divergent, from a systematic classification of matrix model `t Hooft diagrams. The UV divergence indicates that the matrix integral saddle of interest is perturbatively unstable. A non-perturbative treatment of the matrix models discussed in this work is left for future investigations.