Quantitative bounds on vortex fluctuations in 2d Coulomb gas and maximum of the integer-valued Gaussian free field

Abstract

In this paper, we study the influence of the vortices on the fluctuations of 2d systems such as the Coulomb gas, the Villain model or the integer-valued Gaussian free field. In the case of the 2d Villain model, we prove that the fluctuations induced by the vortices are at least of the same order of magnitude as the ones produced by the spin-wave. We obtain the following quantitative upper-bound on the two-point correlation in Z2 when β>1 \[ σx σyβVillain ≤ C \, ( 1 \|x-y\|2) 1 2π β ( 1+β e-(2π)22 β ) \] The proof is entirely non-perturbative. Furthermore it provides a new and algorithmically efficient way of sampling the 2d Coulomb gas. For the 2d Coulomb gas, we obtain the following lower bound on its fluctuations at high inverse temperature \[ EβCoul[ -1q, g] ≥ (-π2 β + o(β)) g,(-)-1g \] This estimate coincides with the predictions based on a RG analysis from [JKKN77] and suggests that the Coulomb potential -1q at inverse temperature β should scale like a Gaussian free field of inverse temperature of order (π2 β). Finally, we transfer the above vortex fluctuations via a duality identity to the integer-valued GFF by showing that its maximum deviates in a quantitative way from the maximum of a usual GFF. More precisely, we show that with high probability when β>1 \[ x∈ [-n,n]2 n(x) ≤ 2βπ (1 - β e- (2π)2β 2 ) n \,. \] where n is an integer-valued GFF in the box [-n,n]2 at inverse temperature β-1. Applications to the free-energies of the Coulomb gas, the Villain model and the integer-valued GFF are also considered.