DLR equations and rigidity for the Sine-beta process
Abstract
We investigate Sine, the universal point process arising as the thermodynamic limit of the microscopic scale behavior in the bulk of one-dimensional log-gases, or -ensembles, at inverse temperature . We adopt a statistical physics perspective, and give a description of Sine using the Dobrushin-Lanford-Ruelle (DLR) formalism by proving that it satisfies the DLR equations: the restriction of Sine to a compact set, conditionally to the exterior configuration, reads as a Gibbs measure given by a finite log-gas in a potential generated by the exterior configuration. Moreover, we show that Sine is number-rigid and tolerant in the sense of Ghosh-Peres, i.e. the number, but not the position, of particles lying inside a compact set is a deterministic function of the exterior configuration. Our proof of the rigidity differs from the usual strategy and is robust enough to include more general long range interactions in arbitrary dimension.
Keywords
Cite
@article{arxiv.1809.03989,
title = {DLR equations and rigidity for the Sine-beta process},
author = {David Dereudre and Adrien Hardy and Thomas Leblé and Mylène Maïda},
journal= {arXiv preprint arXiv:1809.03989},
year = {2019}
}
Comments
46 pages. To appear in Communications on Pure and Applied Mathematics