Dynamical Equilibration of Topological Properties

TL;DR

This paper investigates how topological properties in quantum many-body systems dynamically evolve and equilibrate after a parameter quench, highlighting the role of single particle density matrix level crossings in this process.

Contribution

It reveals the dynamical change and equilibration of topological properties via the single particle density matrix in interacting systems, supported by numerical analysis of a 1D topological insulator.

Findings

Topological properties of the single particle density matrix change dynamically after a quench.

Level crossing in the density matrix signals topological equilibration.

Numerical demonstration in an interacting 1D topological insulator.

Abstract

We study the dynamical process of equilibration of topological properties in quantum many-body systems undergoing a parameter quench between two topologically inequivalent Hamiltonians. This scenario is motivated by recent experiments on ultracold atomic gases, where a trivial initial state is prepared before the Hamiltonian is ramped into a topological insulator phase. While the many-body wave function must stay topologically trivial in the coherent post-quench dynamics, here we show how the topological properties of the single particle density matrix dynamically change and equilibrate in the presence of interactions. In this process, the single particle density matrix goes through a characteristic level crossing as a function of time, which plays an analogous role to the gap closing of a Hamiltonian in an equilibrium topological quantum phase transition. As an exact case study exemplifying this mechanism, we numerically solve the quench dynamics of an interacting one-dimensional topological insulator.