Quantitative symmetry breaking of groundstates for a class of weighted Emden-Fowler equations

Abstract

We consider a class of weighted Emden-Fowler equations equation Pα eqab \arrayll - u=Vα (x) \, up & in \,\,B,\\ u>0 & in \,\,B,\\ u=0 & on\,\,∂ B, array. equation posed on the unit ball B=B(0,1)⊂ RN, N ≥1. We prove that symmetry breaking occurs for the groundstate solutions as the parameter α → ∞. The above problem reads as a possibly large perturbation of the classical H\'enon equation. We consider a radial function Vα having a spherical shell of zeroes at |x|=R ∈ (0,1]. For N ≥ 3, a quantitative condition on R for this phenomenon to occur is given by means of universal constants, such as the best constant for the subcritical Sobolev's embedding H10(B)⊂ Lp+1(B). In the case N=2 we highlight a similar phenomenon when R=R(α) is a function with a suitable decay. Moreover, combining energy estimates and Liouville type theorems we study some qualitative and quantitative properties of the groundstate solutions to (eqab) as α → ∞.