Sharp stability of the logarithmic Sobolev inequality in the critical point setting

Abstract

In this paper, we consider the Euclidean logarithmic Sobolev inequality eqnarray* ∫Rd|u|2|u|dx≤d4(2π d e\|∇ u\|L2(Rd)2), eqnarray* where u∈ W1,2(Rd) with d≥2 and \|u\|L2(Rd)=1. It is well known that extremal functions of this inequality are precisely the Gaussians eqnarray* gσ,z(x)=(πσ)-d2g*(σ2(x-z)) g*(x)=e-|x|22. eqnarray* We prove that if u≥0 satisfying (-12)c0<\|u\|H1(Rd)2<(+12)c0 and \|- u+u-2u |u|\|H-1≤δ, where c0=\|g1,0\|H1(Rd)2, ∈ N and δ>0 sufficiently small, then eqnarray* distH1(u, M)\|- u+u-2u |u|\|H-1 eqnarray* which is optimal in the sense that the order of the right hand side is sharp, where eqnarray* M=\(g1,0(·-z1), g1,0(·-z2), ·s, g1,0(·-z)) zi∈d\. eqnarray* Our result provides an optimal stability of the Euclidean logarithmic Sobolev inequality in the critical point setting.