Non-Abelian eigenstate thermalization hypothesis
Abstract
The eigenstate thermalization hypothesis (ETH) explains why chaotic quantum many-body systems thermalize internally if the Hamiltonian lacks symmetries. If the Hamiltonian conserves one quantity ("charge"), the ETH implies thermalization within a charge sector -- in a microcanonical subspace. But quantum systems can have charges that fail to commute with each other and so share no eigenbasis; microcanonical subspaces may not exist. Furthermore, the Hamiltonian will have degeneracies, so the ETH need not imply thermalization. We adapt the ETH to noncommuting charges by positing a non-Abelian ETH and invoking the approximate microcanonical subspace introduced in quantum thermodynamics. Illustrating with SU(2) symmetry, we apply the non-Abelian ETH in calculating local observables' time-averaged and thermal expectation values. In many cases, we prove, the time average thermalizes. However, we also find cases in which, under a physically reasonable assumption, the time average converges to the thermal average unusually slowly as a function of the global-system size. This work extends the ETH, a cornerstone of many-body physics, to noncommuting charges, recently a subject of intense activity in quantum thermodynamics.
Keywords
Cite
@article{arxiv.2206.05310,
title = {Non-Abelian eigenstate thermalization hypothesis},
author = {Chaitanya Murthy and Arman Babakhani and Fernando Iniguez and Mark Srednicki and Nicole Yunger Halpern},
journal= {arXiv preprint arXiv:2206.05310},
year = {2023}
}
Comments
5 pages (+Supplementary Material: 11 pages). Final version published in Physical Review Letters