A probabilistic approach of ultraviolet renormalisation in the boundary Sine-Gordon model

Abstract

The Sine-Gordon model is obtained by tilting the law of a log-correlated Gaussian field X defined on a subset of Rd by the exponential of its cosine, namely (α (β X)). It is an important model in quantum field theory or in statistic physics like in the study of log-gases. In spite of its relatively simple definition, the model has a very rich phenomenology. While the integral (β X) can properly be defined when β2<d using the standard Wick normalisation of (β X), a more involved renormalization procedure is needed when β2∈ [d,2d). In particular it exhibits a countable sequence of phase transition accumulating to the left of β=2d, each transitions corresponding to the addition of an extra term in the renormalization scheme. The final threshold β=2 corresponds to the Kosterlitz-Thouless (KT) phase transition of the -gas. In this paper, we present a novel probabilistic approach to renormalization of the two-dimensional boundary (or 1-dimensional) Sine-Gordon model up to the KT threshold β=2. The purpose of this approach is to propose a simple and flexible method to treat this problem which, unlike the existing renormalization group techniques, does not rely on translation invariance for the covariance kernel of X or the reference measure along which (β X) is integrated. To this purpose we establish by induction a general formula for the cumulants of a random variable. We apply this formula to study the cumulants of (approximations of) (β X). To control all terms produced by the induction proceedure, we prove a refinement of classical electrostatic inequalities, which allows to bound the energy of configurations in terms of the Wasserstein distance between + and - charges.