Liouville theorems for p-Laplacian equations in convex cones without finite-energy condition

Abstract

We study the anisotropic Finsler p-Laplacian equation equation* \ aligned &-ΔHpu=f(u) \,\,\, &in \,\, C, &a(∇ u)· ν=0 \,\,\, &on \,\, ∂C, aligned . equation* where N≥3, 1<p<N, C⊂eqRN is an open convex cone and ΔHp is the anisotropic Finsler p-Laplacian operator. If f(u) is nonnegative and subcritical, we prove that every bounded nonnegative solution in C is identically zero. In particular, for f(u)=uq with 0<q<p*-1, we establish a pointwise decay estimate in C via the doubling argument and blowing-up method and prove that all nonnegative solutions must be zero without the boundedness assumption. Our results are the subcritical counterpart of the classification result for the critical case in CFR, and extend the Liouville type theorems in RN for the standard p-Laplacian in SZ and for the anisotropic p-Laplacian in CFV, CHN to general convex cones C. In the critical case f(u)=up*-1 and typical case H(ξ)=|ξ|, for N+13<p<N, we classified the positive solutions of the critical p-Laplacian equation in convex cones C without finite-energy assumption. This extends the classification result of Ou in RN to general convex cones C, and removes the finite-energy assumption in CFR in the typical case H(ξ)=|ξ|.