To 1/2-logconcavity and beyond: Geometric properties of Dirichlet eigenfunctions

Abstract

We prove that, on a bounded open convex domain Ω⊂Rn, the first Dirichlet eigenfunction of the Laplacian or the Ornstein--Uhlenbeck operator is α-logconcave for every α∈(0,1/2]. This extends the recent 1/2-logconcavity theorem of Crasta--Fragalà for the Laplacian to the weighted Gaussian setting and, simultaneously, to a broader range of exponents. More precisely, if u denotes the first eigenfunction normalized by \|u\|∞=1, then for every α∈(0,1/2], the function -(-(κu(x)))α is concave in Ω provided the scaling parameter κ lies below an explicit threshold κα(Ω)∈(0,1), which depends on the first Dirichlet eigenvalue and on the diameter of~Ω. For the Ornstein--Uhlenbeck operator, κα(Ω) also depends on the distance between Ω and the origin. Moreover, we establish a local counterpart: for every κ∈(0,1), the function (-(κu))α is convex on a convex neighborhood Ωκ of the unique maximum point of~u. We also provide counterexamples showing that unscaled 1/2-logconcavity may fail for the first Dirichlet eigenfunction of a Schrödinger operator with a smooth convex potential, and for the first Dirichlet eigenfunction of a weighted Laplacian associated with an affine log-concave weight.