Percolation of discrete GFF in dimension two II. Connectivity properties of two-sided level sets

Abstract

We study percolation of two-sided level sets for the discrete Gaussian free field (DGFF) in 2D. For a DGFF φ defined in a box BN with side length N, for C large enough, there exist low crossings in the set of vertices z where |φ(z)| C N, with probability tending to 1 as N ∞, while the average and the maximum of φ are of order N and N, respectively. As a consequence, we also obtain connectivity properties of the set of thick points of a random walk. We rely on an isomorphism between the DGFF and the random walk loop soup (RWLS) with critical intensity α=1/2, and further extend our study to the occupation field of the RWLS for all subcritical intensities α∈(0,1/2). For the RWLS in BN, we show that for λ large enough, there exist low crossings of BN, remaining below λ, even though the average occupation time is of order N. Our results thus uncover a non-trivial phase-transition for this highly-dependent percolation model. For both the DGFF and the occupation field of the RWLS, we further show that such low crossings can be found in the "carpet" of the RWLS - the set of vertices which are not in the interior of any cluster of loops. This work is the second part of a series of two papers. It relies heavily on tools and techniques developed for the RWLS in the first part, especially surgery arguments on loops, which were made possible by a separation result in the RWLS. This allowed us, in that companion paper, to derive several useful properties such as quasi-multiplicativity, and obtain a precise upper bound for the probability that two large connected components of loops "almost touch", which is instrumental here.