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Autori principali: Staszewski, Luke, Haldar, Asmi, Claeys, Pieter W., Wietek, Alexander
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2510.19824
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author Staszewski, Luke
Haldar, Asmi
Claeys, Pieter W.
Wietek, Alexander
author_facet Staszewski, Luke
Haldar, Asmi
Claeys, Pieter W.
Wietek, Alexander
contents In isolated quantum many-body systems periodically driven in time, the asymptotic dynamics at late times can exhibit distinct behavior such as thermalization or dynamical freezing. Understanding the properties of and the convergence towards infinite-time (nonequilibrium) steady states however remains a challenging endeavor. We propose a physically motivated Krylov space perspective on Floquet thermalization which offers a natural framework to study rates of convergence towards steady states and, simultaneously, an efficient numerical algorithm to evaluate infinite-time averages of observables within the diagonal ensemble. The effectiveness of our algorithm is demonstrated by applying it to the periodically driven mixed-field Ising model, reaching system sizes of up to 30 spins. Our method successfully resolves the transition between the ergodic and dynamically frozen phases and provides insight into the nature of the Floquet eigenstates across the phase diagram. Furthermore, we show that the long-time behavior is encoded within the localization properties of the Ritz vectors under the Floquet evolution, providing an accurate diagnostic of ergodicity.
format Preprint
id arxiv_https___arxiv_org_abs_2510_19824
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Krylov space dynamics of ergodic and dynamically frozen Floquet systems
Staszewski, Luke
Haldar, Asmi
Claeys, Pieter W.
Wietek, Alexander
Strongly Correlated Electrons
Statistical Mechanics
In isolated quantum many-body systems periodically driven in time, the asymptotic dynamics at late times can exhibit distinct behavior such as thermalization or dynamical freezing. Understanding the properties of and the convergence towards infinite-time (nonequilibrium) steady states however remains a challenging endeavor. We propose a physically motivated Krylov space perspective on Floquet thermalization which offers a natural framework to study rates of convergence towards steady states and, simultaneously, an efficient numerical algorithm to evaluate infinite-time averages of observables within the diagonal ensemble. The effectiveness of our algorithm is demonstrated by applying it to the periodically driven mixed-field Ising model, reaching system sizes of up to 30 spins. Our method successfully resolves the transition between the ergodic and dynamically frozen phases and provides insight into the nature of the Floquet eigenstates across the phase diagram. Furthermore, we show that the long-time behavior is encoded within the localization properties of the Ritz vectors under the Floquet evolution, providing an accurate diagnostic of ergodicity.
title Krylov space dynamics of ergodic and dynamically frozen Floquet systems
topic Strongly Correlated Electrons
Statistical Mechanics
url https://arxiv.org/abs/2510.19824