# Mixed state dynamical quantum phase transition and emergent topology

**Authors:** Utso Bhattacharya, Souvik Bandopadhyay, Amit Dutta

arXiv: 1705.04555 · 2017-11-29

## TL;DR

This paper investigates mixed state dynamical quantum phase transitions (MSDQPTs) in thermal systems after a quench, revealing persistent non-analyticities and emergent topology characterized by a quantized index up to a critical temperature.

## Contribution

It introduces a novel framework for identifying MSDQPTs using a generalized Loschmidt overlap amplitude and topological index based on Pancharatnam geometry, applicable to thermal states.

## Key findings

- MSDQPTs exhibit non-analyticities in dynamical free energy density.
- A topological index quantifies MSDQPTs and remains quantized up to a critical temperature.
- Analysis of a thermal transverse Ising chain confirms theoretical predictions.

## Abstract

Preparing an integrable system in a mixed state described by a thermal density matrix , we subject it to a sudden quench and explore the subsequent unitary dynamics. Defining a version of the generalised Loschmidt overlap amplitude (GLOA) through the purifications of the time evolved density matrix, we claim that non-analyiticies in the corresponding "dynamical free energy density" persist and is referred to as mixed state dynamical quantum phase transitions (MSDQPTs). Furthermore, these MSDQPTs are uniquely characterised by a topological index constructed by the application of the Pancharatnam geometry on the purifications of the thermal density matrix; the quantization of this index however persists up to a critical temperature. These claims are corroborated analysing the non-equilibrium dynamics of a transverse Ising chain initially prepared in a thermal state and subjected to a sudden quench of the transverse field.

## Full text

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## Figures

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## References

91 references — full list in the complete paper: https://tomesphere.com/paper/1705.04555/full.md

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Source: https://tomesphere.com/paper/1705.04555