Liouville quantum gravity with central charge in $(1,25)$: a probabilistic approach

Ewain Gwynne, Nina Holden, Joshua Pfeffer, Guillaume Remy

Published 2019-03-21Version 1

There is a substantial literature concerning Liouville quantum gravity (LQG) with coupling constant $\gamma \in (0,2]$. In this setting, the central charge of the corresponding matter field satisfies $\mathbf c = 25 - 6(2/\gamma+\gamma/2)^2 \in (-\infty,1]$. Physics considerations suggest that LQG also makes sense for $\mathbf c > 1$, but the behavior in this regime is rather mysterious in part because the corresponding value of $\gamma$ is complex, so analytic continuations of various formulas give non-physical complex answers. We introduce and study a discretization of LQG which makes sense for all $\mathbf c \in (-\infty,25)$. Our discretization consists of a random planar map, defined as the adjacency graph of a tiling of the plane by dyadic squares which all have approximately the same "LQG size" with respect to a Gaussian free field. We prove that several formulas for dimension-related quantities are still valid for $\mathbf c \in (1,25)$, with the caveat that the dimension is infinite when the formulas give a complex answer. In particular, we prove an extension of the KPZ formula for $\mathbf c \in (1,25)$, which gives a finite quantum dimension if and only if the Euclidean dimension is at most $(25-\mathbf c)/12$. We also show that the graph distance between typical points with respect to our discrete model grows polynomially whereas the cardinality of a graph distance ball of radius $r$ grows faster than any power of $r$ (which suggests that the Hausdorff dimension of LQG for $\mathbf c\in(1,25)$ is infinite). We include a substantial list of open problems.