Interaction-correlated random matrices
Abstract
We introduce a family of random matrices where correlations between matrix elements are induced via interaction-derived Boltzmann factors. Varying these yields access to different ensembles. We find a universal scaling behavior of the finite-size statistics characterized by a heavy-tailed eigenvalue distribution whose extremes are governed by the Fr\'echet extreme value distribution for the case corresponding to a ferromagnetic Ising transition. The introduction of a finite density of nonlocal interactions restores standard random-matrix behavior. Suitably rescaled average extremes, playing a physical role as an order parameter, can thus discriminate aspects of the interaction structure; they also yield further nonuniversal information. In particular, the link between maximum eigenvalues and order parameters offers a potential route to resolving long-standing problems in statistical physics, such as deriving the exact magnetization scaling function in the two-dimensional Ising model at criticality.
Cite
@article{arxiv.2503.03472,
title = {Interaction-correlated random matrices},
author = {Abbas Ali Saberi and Sina Saber and Roderich Moessner},
journal= {arXiv preprint arXiv:2503.03472},
year = {2025}
}
Comments
4 figures