Tilted Solid-On-Solid is liquid: scaling limit of SOS with a potential on a slope

Abstract

The (2+1)D Solid-On-Solid (SOS) model famously exhibits a roughening transition: on an N× N torus with the height at the origin rooted at 0, the variance of h(x), the height at x, is O(1) at large inverse-temperature β, vs. |x| at small β (as in the Gaussian free field (GFF)). The former--rigidity at large β--is known for a wide class of |∇φ|p models (p=1 being SOS) yet is believed to fail once the surface is on a slope (tilted boundary conditions). It is conjectured that the slope would destabilize the rigidity and induce the GFF-type behavior of the surface at small β. The only rigorous result on this is by Sheffield (2005): for these models of integer height functions, if the slope θ is irrational, then Var(h(x))∞ with |x| (with no known quantitative bound). We study a family of SOS surfaces at a large enough fixed β, on an N× N torus with a nonzero boundary condition slope θ, perturbed by a potential V of strength εβ per site (arbitrarily small). Our main result is (a) the measure on the height gradients ∇ h has a weak limit μ∞ as N∞; and (b) the scaling limit of a sample from μ∞ converges to a full plane GFF. In particular, we recover the asymptotics Var(h(x)) c|x|. To our knowledge, this is the first example of a tilted |∇φ|p model, or a perturbation thereof, where the limit is recovered at large β. The proof looks at random monotone surfaces that approximate the SOS surface, and shows that (i) these form a weakly interacting dimer model, and (ii) the renormalization framework of Giuliani, Mastropietro and Toninelli (2017) leads to the GFF limit. New ingredients are needed in both parts, including a nontrivial extension of [GMT17] from finite interactions to any long range summable interactions.