Tightness of discrete Gibbsian line ensembles with exponential interaction Hamiltonians

Abstract

In this paper we introduce a framework to prove tightness of a sequence of discrete Gibbsian line ensembles LN = \LkN(x), k ∈ N, x ∈ 1NZ\, which is a collection of countable random curves. The sequence of discrete line ensembles LN we consider enjoys a resampling invariance property, which we call (HN,HRW,N)-Gibbs property. We also assume that LN satisfies technical assumptions A1-A4 on (HN,HRW,N) and the assumption that the lowest labeled curve with a parabolic shift, L1N(x) + x22, converges weakly to a stationary process in the topology of uniform convergence on compact sets. Under these assumptions, we prove our main result Theorem 2.18 that LN is tight as a line ensemble and that H-Brownian Gibbs property holds for all subsequential limit line ensembles with H(x)= ex. As an application of Theorem 2.18, under weak noise scaling, we show that the scaled log-gamma line ensemble LN is tight, which is a sequence of discrete line ensembles associated with the inverse-gamma polymer model via the geometric RSK correspondence. The H-Brownian Gibbs property (with H(x) = ex) of its subsequential limits also follows.