Existence of Bianchi-Egnell stability extremizer for the Hardy-Sobolev inequality

Abstract

In this article, we prove the best Bianchi-Egnell constant for the Hardy-Sobolev (HS) inequality align* CBE(γ) := ∈fu \ not an optimizer ∫Rn (|∇ u|2 - γ|x|2u2) \ dx - Sγ\|u\|L2^2dist (u, \ set of optimizers)2, align* is attained, extending the result of K\"onig [arXiv:2211.14185] for the classical Sobolev inequality (that corresponds to γ = 0). One of the main difficulties is that the third eigenspace of the linearized operator may contain only spherical harmonics of degree 1, and hence, an essential non-vanishing criterion fails [arXiv:2210.08482]. This non-vanishing criterion is indispensable for proving the best Bianchi-Egnell constant CBE(γ) < CBEloc(γ) that prevents a minimizing sequence converging to one of the optimizers. In addition, not being translation invariant, extracting a non-zero weak limit from a minimizing sequence presents difficulties. We found another hidden critical level CBE(γ) <1 - SγS, where S is the best Sobolev constant that plays a significant role in proving the existence of an extremizer. In particular, we show that there exists a γ0>0 such that for γ ≥ γ0,\ CBE(γ) is attained. Moreover, we remark that there is a region γ0 ≤ γ < γc, where the third eigenspace of the linearized operator contains only spherical harmonics of degree 1. Our result improves some of the results in Wei-Wu [arXiv:2308.04667] corresponding to the HS inequality.