Bounds for distances and geodesic dimension in Liouville first passage percolation

Abstract

For ≥ 0, Liouville first passage percolation (LFPP) is the random metric on Z2 obtained by weighting each vertex by e h(z), where h(z) is the average of the whole-plane Gaussian free field h over the circle ∂ B(z). Ding and Gwynne (2018) showed that for γ ∈ (0,2), LFPP with parameter = γ/dγ is related to γ-Liouville quantum gravity (LQG), where dγ is the γ-LQG dimension exponent. For > 2/d2, LFPP is instead expected to be related to LQG with central charge greater than 1. We prove several estimates for LFPP distances for general ≥ 0. For ≤ 2/d2, this leads to new bounds for dγ which improve on the best previously known upper (resp.\ lower) bounds for dγ in the case when γ > 8/3 (resp.\ γ ∈ (0.4981, 8/3)). These bounds are consistent with the Watabiki (1993) prediction for dγ. However, for > 1/ 3 (or equivalently for LQG with central charge larger than 17) our bounds are inconsistent with the analytic continuation of Watabiki's prediction to the >2/d2 regime. We also obtain an upper bound for the Euclidean dimension of LFPP geodesics.