Sharp boundary behaviour of solutions to semilinear nonlocal elliptic equations

Abstract

We investigate quantitative properties of nonnegative solutions u(x) 0 to the semilinear diffusion equation L u= f(u), posed in a bounded domain ⊂ RN with appropriate homogeneous Dirichlet or outer boundary conditions. The operator L may belong to a quite general class of linear operators that include the standard Laplacian, the two most common definitions of the fractional Laplacian (-)s (0<s<1) in a bounded domain with zero Dirichlet conditions, and a number of other nonlocal versions. The nonlinearity f is increasing and looks like a power function f(u) up, with p 1. The aim of this paper is to show sharp quantitative boundary estimates based on a new iteration process. We also prove that, in the interior, solutions are H\"older continuous and even classical (when the operator allows for it). In addition, we get H\"older continuity up to the boundary. Particularly interesting is the behaviour of solution when the number 2s1-p goes below the exponent γ ∈(0,1] corresponding to the H\"older regularity of the first eigenfunction L1=λ1 1. Indeed a change of boundary regularity happens in the different regimes 2s1-p γ, and in particular a logarithmic correction appears in the "critical" case 2s1-p = γ. Indeed a change of boundary regularity happens in the different regimes 2s1-p γ, and in particular a logarithmic correction appears in the "critical" case 2s1-p = γ. For instance, in the case of the spectral fractional Laplacian, this surprising boundary behaviour appears in the range 0<s≤ 1-p2.