Interaction-Driven Instabilities in the Random-Field XXZ Chain
Abstract
Despite enormous efforts devoted to the study of the many-body localization (MBL) phenomenon, the nature of the high-energy behavior of the Heisenberg spin chain in a strong random magnetic field is lacking consensus. Here, we take a step back by exploring the weak interaction limit starting from the Anderson localized (AL) insulator. Through shift-invert diagonalization, we find that below a certain disorder threshold , weak interactions necessarily lead to ergodic instability, whereas at strong disorder the AL insulator directly turns into MBL. This agrees with a simple interpretation of the avalanche theory for restoration of ergodicity. We further map the phase diagram for the generic XXZ model in the disorder -- interaction plane. Taking advantage of the total magnetization conservation, our results unveil the remarkable behavior of the spin-spin correlation functions: in the regime indicated as MBL by standard observables, their exponential decay undergoes a unique inversion of orientation . We find that the longitudinal length is a key quantity for capturing ergodic instabilities, as it increases with system size near the thermal phase, in sharp contrast to its transverse counterpart .
Cite
@article{arxiv.2403.09608,
title = {Interaction-Driven Instabilities in the Random-Field XXZ Chain},
author = {Jeanne Colbois and Fabien Alet and Nicolas Laflorencie},
journal= {arXiv preprint arXiv:2403.09608},
year = {2024}
}
Comments
4+5 pages; 3+5 figures