Floquet-Thermalization via Instantons near Dynamical Freezing

TL;DR

This paper investigates the slow approach to thermalization in periodically driven quantum many-body systems exhibiting dynamical freezing, using flow-renormalization and instanton analysis to reveal universal late-time behavior.

Contribution

It introduces a flow-renormalization method to systematically analyze dynamical freezing and thermalization in Floquet systems, revealing universal late-time dynamics and instanton events.

Findings

Flow approaches an unstable fixed point with emergent symmetry.

Thermalization timescales are delayed at freezing.

Flow trajectories feature instanton events.

Abstract

Periodically driven Floquet quantum many-body systems have revealed new insights into the rich interplay of thermalization, and growth of entanglement. The phenomenology of dynamical freezing, whereby a translationally invariant many-body system exhibits emergent conservation laws and a slow growth of entanglement entropy at certain fixed ratios of a drive amplitude and frequency, presents a novel paradigm for retaining memory of an initial state upto late times. Previous studies of dynamical freezing have largely been restricted to a high-frequency Floquet-Magnus expansion, and numerical exact diagonalization, which are unable to capture the slow approach to thermalization (or lack thereof) in a systematic fashion. By employing Floquet flow-renormalization, where the time-dependent part of the Hamiltonian is gradually decoupled from the effective Hamiltonian using a sequence of unitary transformations, we unveil the universal approach to dynamical freezing and beyond, at asymptotically late times. We analyze the fixed-point behavior associated with the flow-renormalization at and near freezing using both exact-diagonalization and tensor-network based methods, and contrast the results with conventional prethermal phenomenon. For a generic non-integrable spin Hamiltonian with a periodic cosine wave drive, the flow approaches an unstable fixed point with an approximate emergent symmetry. We observe that at freezing the thermalization timescales are delayed compared to away from freezing, and the flow trajectory undergoes a series of instanton events. Our numerical results are supported by analytical solutions to the flow equations.