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

Abstract

There is a substantial literature concerning Liouville quantum gravity (LQG) in two dimensions with conformal matter field of central charge c M∈(-∞,1]. Via the DDK ansatz, LQG can equivalently be described as the random geometry obtained by exponentiating γ times a variant of the planar Gaussian free field (GFF), where γ∈(0,2] satisfies c M=25-6(2/γ+γ/2)2. Physics considerations suggest that LQG should also make sense in the regime when c M>1. However, the behavior in this regime is rather mysterious in part because the corresponding value of γ is complex, so analytic continuations of various formulas give complex answers which are difficult to interpret in a probabilistic setting. We introduce and study a discretization of LQG which makes sense for all values of c M∈(-∞,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 the GFF. We prove that several formulas for dimension-related quantities are still valid for c M∈(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 (geometric) KPZ formula for c M∈(1,25), which gives a finite quantum dimension iff the Euclidean dimension is at most (25- c M)/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 is infinite for c M∈(1,25)). We include a substantial list of open problems.