Topological phase transitions at finite temperature

TL;DR

This paper investigates topological phase transitions at finite temperature in noninteracting fermionic systems using the ensemble geometric phase (EGP), revealing temperature-induced topological changes and quantization conditions under symmetries.

Contribution

It introduces a novel framework for understanding topology at finite temperature through the EGP, including the discovery of temperature-driven topological phase transitions and symmetry-induced quantization.

Findings

Topological phase transitions occur as temperature varies, changing the winding number of the EGP.

The non-equilibrium steady state at the transition can have a nontrivial structure.

The EGP becomes quantized under certain symmetries, enabling topological classification at finite temperature.

Abstract

The ground states of noninteracting fermions in one-dimension with chiral symmetry form a class of topological band insulators, described by a topological invariant that can be related to the Zak phase. Recently, a generalization of this quantity to mixed states - known as the ensemble geometric phase (EGP) - has emerged as a robust way to describe topology at non-zero temperature. By using this quantity, we explore the nature of topology allowed for dissipation beyond a Lindblad description, to allow for coupling to external baths at finite temperatures. We introduce two main aspects to the theory of mixed state topology. First, we discover topological phase transitions as a function of the temperature T, manifesting as changes in winding number of the EGP accumulated over a closed loop in parameter space. We characterize the nature of these transitions and reveal that the corresponding non-equilibrium steady state at the transition can exhibit a nontrivial structure - contrary to previous studies where it was found to be in a fully mixed state. Second, we demonstrate that the EGP itself becomes quantized when key symmetries are present, allowing it to be viewed as a topological marker which can undergo equilibrium topological transitions at non-zero temperatures.