Concentration inequalities for log-concave distributions with applications to random surface fluctuations (2006.05393v2)

Abstract: We derive two concentration inequalities for linear functions of log-concave distributions: an enhanced version of the classical Brascamp--Lieb concentration inequality, and an inequality quantifying log-concavity of marginals in a manner suitable for obtaining variance and tail probability bounds. These inequalities are applied to the statistical mechanics problem of estimating the fluctuations of random surfaces of the $\nabla\varphi$ type. The classical Brascamp--Lieb inequality bounds the fluctuations whenever the interaction potential is uniformly convex. We extend these bounds to the case of convex potentials whose second derivative vanishes only on a zero measure set, when the underlying graph is a $d$-dimensional discrete torus. The result applies, in particular, to potentials of the form $U(x)=|x|^p$ with $p>1$ and answers a question discussed by Brascamp--Lieb--Lebowitz (1975). Additionally, new tail probability bounds are obtained for the family of potentials $U(x) = |x|^p+x^2$, $p>2$. This result answers a question mentioned by Deuschel and Giacomin (2000).