Entropic independence via sparse localization

Abstract

Entropic independence is a structural property of measures that underlies modern proofs of functional inequalities, notably (modified) log-Sobolev inequalities, via ``annealing'' or local-to-global schemes. Existing sufficient criteria for entropic independence typically require spectral independence and/or uniform bounds on marginals under all pinnings, which can fail in natural canonical-ensemble models even when strong mixing properties are expected. We introduce sparse localization: a restricted localization framework, in the spirit of Chen--Eldan, in which one assumes 2-independence only for a sparse family of pinnings (those fixing at most cn coordinates for any c > 0), yet still deduces quadratic entropic stability and entropic independence with an explicit multiplicative loss of order c-1. As an application, we give a rigorous proof of approximate conservation of entropy for the uniform distribution on independent sets of a given size in bounded degree graphs.