Quantum and classical Floquet prethermalization

Time-periodic (Floquet) driving is a powerful way to control the dynamics of complex systems, which can be used to induce a plethora of new physical phenomena. However, when applied to many-body systems, Floquet driving can also cause heating, and lead to a featureless infinite-temperature state, hindering most useful applications. It is therefore important to find mech-anisms to suppress such effects. Floquet prethermalization refers to the phenomenon where many-body systems subject to a high-frequency periodic drive avoid heating for very long times, instead tending to transient states that can host interesting physics. Its key signature is a strong parametric suppression of the heating rate as a function of the driving frequency. Here, we review our present understanding of this phenomenon in both quantum and classical systems, and across various models and methods. In particular, we present rigorous theorems underpin-ning Floquet prethermalization in quantum spin and fermionic lattice systems and extensions to systems with degrees of free-dom that have unbounded local dimension. Further, we briefly describe applications to novel nonequilibrium phases of matter, and recent experiments probing prethermalization with quan-tum simulators. We close by describing the frontiers of Floquet prethermalization beyond strictly time-periodic drives, includ-ing time-quasiperiodic driving and long-lived quasi-conserved quantities enabled by large separation of energy scales.& COPY; 2023 Elsevier Inc. All rights reserved.