Thermalization slowing down of weakly nonintegrable quantum spin dynamics

TL;DR

This paper investigates how thermalization slows down in quantum spin systems near integrability, identifying two diverging timescales related to operator growth and fluctuation statistics, revealing a universal behavior of integrability breaking.

Contribution

It introduces two distinct thermalization timescales in quantum spin systems approaching integrability and demonstrates their universal divergence behavior.

Findings

Both timescales diverge near integrability

Divergence behavior is similar despite different mechanisms

Establishes universality of integrability breaking in quantum spins

Abstract

We study thermalization slowing down of a quantum many-body spin system upon approach to two distinct integrability limits. Motivated by previous studies of classical systems, we identify two thermalization time scales: one quantum Lyapunov time scale is extracted by quantifying operator growth in time on an appropriately defined basis, while another ergodization time scale is related to the statistics of fluctuations of the time-evolved operator around its mean value based on the eigenstate thermalization hypothesis. Using a paradigmatic Quantum Ising chain we find that both timescales diverge upon approach to integrability. We investigate the relative strength of the divergence in the two limits and find that despite significant qualitative differences in the mechanism of integrability breaking, the timescales diverge in a similar fashion. This allows us to establish a universality of integrability breaking in quantum spin dynamics.