Extracting the symmetries of nonequilibrium quantum many-body systems

TL;DR

This paper introduces a method to identify and analyze symmetries in nonequilibrium quantum many-body systems using correlation functions, enabling insights into symmetry restoration and breaking far from equilibrium.

Contribution

It develops a novel approach based on nonequilibrium Ward identities to extract effective symmetries from data, applicable to both numerical and experimental systems.

Findings

Effective symmetry restoration occurs before system equilibration.

The method can identify spontaneous symmetry breaking far from equilibrium.

Applicable to diverse systems from quantum gases to cosmology.

Abstract

Symmetries play a pivotal role in our understanding of the properties of quantum many-body systems. While there are theorems and a well-established toolbox for systems in thermal equilibrium, much less is known about the role of symmetries and their connection to dynamics out of equilibrium. This arises due to the direct link between a system's thermal state and its Hamiltonian, which is generally not the case for nonequilibrium dynamics. Here we present a pathway to identify the effective symmetries and to extract them from data in nonequilibrium quantum many-body systems. Our approach is based on exact relations between correlation functions involving different numbers of spatial points, which can be viewed as nonequilibrium versions of (equal-time) Ward identities encoding the symmetries of the system. We derive symmetry witnesses, which are particularly suitable for the analysis of measured or simulated data at different snapshots in time. To demonstrate the potential of the approach, we apply our method to numerical and experimental data for a spinor Bose gas. We investigate the important question of a dynamical restoration of an explicitly broken symmetry of the Hamiltonian by the initial state. Remarkably, it is found that effective symmetry restoration can occur long before the system equilibrates. We also use the approach to define and identify spontaneous symmetry breaking far from equilibrium, which is of great relevance for applications to nonequilibrium phase transitions. Our work opens new avenues for the classification and analysis of quantum as well as classical many-body dynamics in a large variety of systems, ranging from ultracold quantum gases to cosmology.