The fate of dynamical phase transitions at finite temperatures and in open systems

TL;DR

This paper investigates how dynamical phase transitions in quantum systems are affected by finite temperatures and open system dynamics, showing that dissipation can preserve these transitions despite thermal effects.

Contribution

It extends the concept of dynamical phase transitions to finite-temperature and open quantum systems, demonstrating conditions under which DPTs can persist.

Findings

Cusps in the return rate are smoothed out at finite temperatures.

Dissipative dynamics can be tuned to preserve DPTs.

DPTs can occur in open systems described by Lindblad equations.

Abstract

When a quantum system is quenched from its ground state, the time evolution can lead to non-analytic behavior in the return rate at critical times $t_c$. Such dynamical phase transitions (DPT's) can occur, in particular, for quenches between phases with different topological properties in Gaussian models. In this paper we discuss Loschmidt echos generalized to density matrices and obtain results for quenches in closed Gaussian models at finite temperatures as well as for open system dynamics described by a Lindblad master equation. While cusps in the return rate are always smoothed out by finite temperatures we show that dissipative dynamics can be fine-tuned such that DPT's persist.