English

A unifying model for random matrix theory in arbitrary space dimensions

Disordered Systems and Neural Networks 2018-03-21 v2 Soft Condensed Matter Statistical Mechanics Mathematical Physics math.MP

Abstract

A sparse random block matrix model suggested by the Hessian matrix used in the study of elastic vibrational modes of amorphous solids is presented and analyzed. By evaluating some moments, benchmarked against numerics, differences in the eigenvalue spectrum of this model in different limits of space dimension dd, and for arbitrary values of the lattice coordination number ZZ, are shown and discussed. As a function of these two parameters (and their ratio Z/dZ/d), the most studied models in random matrix theory (Erdos-Renyi graphs, effective medium, replicas) can be reproduced in the various limits of block dimensionality dd. Remarkably, the Marchenko-Pastur spectral density (which is recovered by replica calculations for the Laplacian matrix) is reproduced exactly in the limit of infinite size of the blocks, or dd\rightarrow\infty, which for the first time clarifies the physical meaning of space dimension in these models. The approximate results for d=3d=3 provided by our method have many potential applications in the future, from the vibrational spectrum of glasses and elastic networks, to wave-localization, disordered conductors, random resistor networks and random walks.

Keywords

Cite

@article{arxiv.1710.02850,
  title  = {A unifying model for random matrix theory in arbitrary space dimensions},
  author = {Giovanni M. Cicuta and Johannes Krausser and Rico Milkus and Alessio Zaccone},
  journal= {arXiv preprint arXiv:1710.02850},
  year   = {2018}
}
R2 v1 2026-06-22T22:06:58.209Z