Probing the relaxation towards equilibrium in an isolated strongly correlated 1D Bose gas

TL;DR

This study experimentally and numerically investigates how a strongly correlated 1D Bose gas relaxes towards equilibrium, revealing a power-law relaxation behavior and demonstrating the system's potential as a quantum simulator for complex dynamics.

Contribution

It provides the first detailed experimental observation of non-equilibrium dynamics in a strongly correlated 1D Bose gas and confirms numerical predictions with high fidelity.

Findings

Local observables relax to maximum entropy values

Relaxation follows a power-law with a large exponent

System acts as a quantum simulator for extended times

Abstract

The problem of how complex quantum systems eventually come to rest lies at the heart of statistical mechanics. The maximum entropy principle put forward in 1957 by E. T. Jaynes suggests what quantum states one should expect in equilibrium but does not hint as to how closed quantum many-body systems dynamically equilibrate. A number of theoretical and numerical studies accumulate evidence that under specific conditions quantum many-body models can relax to a situation that locally or with respect to certain observables appears as if the entire system had relaxed to a maximum entropy state. In this work, we report the experimental observation of the non-equilibrium dynamics of a density wave of ultracold bosonic atoms in an optical lattice in the regime of strong correlations. Using an optical superlattice, we are able to prepare the system in a well-known initial state with high fidelity. We then follow the dynamical evolution of the system in terms of quasi-local densities, currents, and coherences. Numerical studies based on the time-dependent density-matrix renormalization group method are in an excellent quantitative agreement with the experimental data. For very long times, all three local observables show a fast relaxation to equilibrium values compatible with those expected for a global maximum entropy state. We find this relaxation of the quasi-local densities and currents to initially follow a power-law with an exponent being significantly larger than for free or hardcore bosons. For intermediate times the system fulfills the promise of being a dynamical quantum simulator, in that the controlled dynamics runs for longer times than present classical algorithms based on matrix product states can efficiently keep track of.