Symmetry and linear stability in Serrin's overdetermined problem via the stability of the parallel surface problem

Abstract

We consider the solution of the problem - u=f(u) \ and \ u>0 \ \ in \ , \ \ u=0 \ on \ , where is a bounded domain in RN with boundary of class C2,τ, 0<τ<1, and f is a locally Lipschitz continuous non-linearity. Serrin's celebrated symmetry theorem states that, if the normal derivative u is constant on , then must be a ball. In [CMS2], it has been conjectured that Serrin's theorem may be obtained by stability in the following way: first, for a solution u prove the estimate re-ri Cδ\,[u]δ for some constant Cδ depending on δ>0, where re and ri are the radii of a spherical annulus containing , δ is a surface parallel to at distance δ and sufficiently close to , and [u]δ is the Lipschitz semi-norm of u on δ; secondly, if in addition u is constant on , show that [u]δ=o(Cδ)\ as \ δ 0+. In this paper, we prove that this strategy is successful. As a by-product of this method, for C2,τ-regular domains, we also obtain a linear stability estimate for Serrin's symmetry result. Our result is optimal and greatly improves the similar logarithmic-type estimate of [ABR] and the H\"older estimate of [CMV] that was restricted to convex domains.