English

Normal weak eigenstate thermalization

Statistical Mechanics 2025-05-13 v2 Disordered Systems and Neural Networks Strongly Correlated Electrons Quantum Physics

Abstract

Eigenstate thermalization has been numerically shown to occur for few-body observables in a wide range of nonintegrable models. For intensive sums of few-body observables, a weaker version of eigenstate thermalization known as weak eigenstate thermalization has been proved to occur in general. Here, we unveil a stricter weak eigenstate thermalization phenomenon that occurs in quadratic models exhibiting quantum chaos in the single-particle sector (quantum-chaotic quadratic models) and in integrable interacting models. In such models, we argue that few-body observables that have a properly defined system-size independent norm are guaranteed to exhibit at least a polynomially vanishing variance (over the entire many-body energy spectrum) of the diagonal matrix elements, a phenomenon we dub normal weak eigenstate thermalization. We prove that normal weak eigenstate thermalization is a consequence of single-particle eigenstate thermalization, i.e., it can be viewed as a manifestation of quantum chaos at the single-particle level. We report numerical evidence of normal weak eigenstate thermalization for quantum-chaotic quadratic models such as the three-dimensional Anderson model in the delocalized regime and the power-law random banded matrix model, as well as for the integrable interacting spin-1/2 XYZ and XXZ models.

Keywords

Cite

@article{arxiv.2404.02199,
  title  = {Normal weak eigenstate thermalization},
  author = {Patrycja Łydżba and Rafał Świętek and Marcin Mierzejewski and Marcos Rigol and Lev Vidmar},
  journal= {arXiv preprint arXiv:2404.02199},
  year   = {2025}
}

Comments

20 pages, 12 figures, as published

R2 v1 2026-06-28T15:42:10.503Z