Thermodynamics of Quadrature Trajectories in Open Quantum Systems

TL;DR

This paper develops a large-deviation framework to analyze quadrature trajectories in open quantum systems, providing new insights into their statistical properties and phase classification, especially when quantum jump statistics are insufficient.

Contribution

It introduces a formalism for studying quadrature trajectories via characteristic operators, enabling phase classification and analysis of rare fluctuations in open quantum systems.

Findings

Quadrature trajectories obey a large-deviation principle in the long-time limit.

Quadrature operators can serve as alternative order parameters for dynamical phase classification.

The approach applies to various systems, including the micromaser and driven two-level systems.

Abstract

We apply a large-deviation method to study the diffusive trajectories of the quadrature operators of light within a reservoir connected to dissipative quantum systems. We formulate the study of quadrature trajectories in terms of characteristic operators and show that in the long time limit the statistics of such trajectories obey a large-deviation principle. We take our motivation from homodyne detection schemes which allow the statistics of quadrature operator of the light field to be measured. We illustrate our approach with four examples of increasing complexity: a driven two-level system, a `blinking' three-level system, a pair of weakly-coupled two-level driven systems, and the micromaser. We discuss how quadrature operators can serve as alternative order parameters for the classification of dynamical phases, which is particularly useful in cases where the statistics of quantum jumps cannot distinguish between such phases. The formalism we introduce also allows us to analyse the properties of the light emitted by quantum jump trajectories which fluctuate far from the typical dynamics.