Entanglement generation in periodically driven integrable systems: dynamical phase transitions and steady state

Abstract

We study a class of periodically driven d-dimensional integrable models and show that after n drive cycles with frequency ω, pure states with non-area-law entanglement entropy Sn(l) lα(n,ω) are generated, where l is the linear dimension of the subsystem, and d-1 α(n,ω) d. We identify and analyze the crossover phenomenon from an area (S l d-1 for d≥1) to a volume (S ld) law and provide a criterion for their occurrence which constitutes a generalization of Hastings' theorem to driven integrable systems in one dimension. We also find that Sn generically decays to S∞ as (ω/n)(d+2)/2 for fast and (ω/n)d/2 for slow periodic drives; these two dynamical phases are separated by a topological transition in the eigensprectrum of the Floquet Hamiltonian. This dynamical transition manifests itself in the temporal behavior of all local correlation functions and does not require a critical point crossing during the drive. We find that these dynamical phases show a rich re-entrant behavior as a function of ω for d=1 models, and also discuss the dynamical transition for d>1 models. Finally, we study entanglement properties of the steady state and show that singular features (cusps and kinks in d=1) appear in S∞ as a function of ω whenever there is a crossing of the Floquet bands. We discuss experiments which can test our theory.