English

Quantitative approximate independence for continuous mean field Gibbs measures

Probability 2021-05-10 v1

Abstract

Many Gibbs measures with mean field interactions are known to be chaotic, in the sense that any collection of kk particles in the nn-particle system are asymptotically independent, as nn\to\infty with kk fixed or perhaps k=o(n)k=o(n). This paper quantifies this notion for a class of continuous Gibbs measures on Euclidean space with pairwise interactions, with main examples being systems governed by convex interactions and uniformly convex confinement potentials. The distance between the marginal law of kk particles and its limiting product measure is shown to be O((k/n)c2)O((k/n)^{c \wedge 2}), with cc proportional to the squared temperature. In the high temperature case, this improves upon prior results based on subadditivity of entropy, which yield O(k/n)O(k/n) at best. The bound O((k/n)2)O((k/n)^2) cannot be improved, as a Gaussian example demonstrates. The results are non-asymptotic, and distance is quantified via relative Fisher information, relative entropy, or the squared quadratic Wasserstein metric. The method relies on an a priori functional inequality for the limiting measure, used to derive an estimate for the kk-particle distance in terms of the (k+1)(k+1)-particle distance.

Keywords

Cite

@article{arxiv.2105.03238,
  title  = {Quantitative approximate independence for continuous mean field Gibbs measures},
  author = {Daniel Lacker},
  journal= {arXiv preprint arXiv:2105.03238},
  year   = {2021}
}
R2 v1 2026-06-24T01:52:32.666Z