Critical level-set percolation on finite graphs and spectral gap

Abstract

We study the bond percolation on finite graphs induced by the level-sets of zero-average Gaussian free field on the associated metric graph above a given height (level) parameter h ∈ R. We characterize the near- and off-critical phases of this model for any expanders family Gn = (Vn, En) with uniformly bounded degrees. In particular, we show that the volume of the largest open cluster at level hn is of the order |Vn|23 when hn lies in the corresponding critical window which we identify as |hn| = O(|Vn|-13). Outside this window, the volume starts to deviate from (|Vn|23) culminating into a linear order in the supercritical phase hn = h < 0 (the giant component) and a logarithmic order in the subcritical phase hn = h > 0. We deduce these from effective estimates on tail probabilities for the maximum volume of an open cluster at any level h for a generic base graph G. The estimates depend on G only through its size and upper and lower bounds on its degrees and spectral gap respectively. To the best of our knowledge, this is the first instance where a mean-field critical behavior is derived under such general setup for finite graphs. The generality of these estimates preclude any local approximation of G by regular infinite trees -- a standard approach in the area. Instead, our methods rely on exploiting the connection between spectral gap of the graph G and its connection to the level-sets of zero-average Gaussian free field mediated via a set function we call the zero-average capacity.