A Rigorous Theory of Many-Body Prethermalization for Periodically Driven and Closed Quantum Systems

TL;DR

This paper establishes a rigorous theoretical framework demonstrating long-lived prethermalization in periodically driven and energy-scale separated quantum spin systems, showing the emergence of effective conserved quantities over exponentially long times.

Contribution

It provides a rigorous proof of prethermalization and effective conserved quantities in quantum spin systems under high-frequency driving and energy scale separation, extending understanding of non-equilibrium quantum dynamics.

Findings

Prethermalization persists for quasi-exponential times under high-frequency driving.

Effective local Hamiltonians govern system dynamics up to long times.

Conserved quantities emerge in systems with energy scale separation, like the Fermi-Hubbard model.

Abstract

Prethermalization refers to the transient phenomenon where a system thermalizes according to a Hamiltonian that is not the generator of its evolution. We provide here a rigorous framework for quantum spin systems where prethermalization is exhibited for very long times. First, we consider quantum spin systems under periodic driving at high frequency $\nu$. We prove that up to a quasi-exponential time $\tau_* \sim e^{c \frac{\nu}{\log^3 \nu}}$, the system barely absorbs energy. Instead, there is an effective local Hamiltonian $\hat D$ that governs the time evolution up to $\tau_*$, and hence this effective Hamiltonian is a conserved quantity up to $\tau_*$. Next, we consider systems without driving, but with a separation of energy scales in the Hamiltonian. A prime example is the Fermi-Hubbard model where the interaction $U$ is much larger than the hopping $J$. Also here we prove the emergence of an effective conserved quantity, different from the Hamiltonian, up to a time $\tau_*$ that is (almost) exponential in $U/J$.