Functional perimeter and the dimensional Brunn-Minkowski inequality for log-concave measures

Abstract

This paper is dedicated to two geometric problems associated to log-concave measures on Rn. First, we study the dimensional Brunn-Minkowski inequality for even log-concave probability measures μ on Rn via an analytic approach based on diffusion operators and gradient estimates. We prove that for every pair of symmetric convex sets K,L in Rn and every λ∈(0,1), μ(λK+(1-λ)L)cn ≥ λμ(K)cn+(1-λ)μ(L)cn, where cn≥ c/n3 n for some absolute constant c>0. Secondly, we study the maximal perimeter Γ(μ) of an isotropic log-concave measure μ, without symmetry assumptions. We prove that Γn = \Γ(μ): \ μ\ is an isotropic log-concave measure on Rn \ ≈ n. A key ingredient in both our proofs is a bound due to Eldan and Klartag (2008), which states that ∫Rn |∇ψ|\,dμ≤ Cn for every isotropic log-concave probability measure μ on Rn with density e-ψ. We also present further applications of this estimate to projections of log-concave functions projections, moment and surface area measures of isotropic log-concave functions, highlighting the central role of the gradient of the logarithmic potential in high-dimensional convexity.