Temporally correlated quantum noise in driven quantum systems

TL;DR

This paper introduces a new quantum master equation for driven quantum systems that accounts for temporally correlated environmental effects and field-dependent dissipation, improving the accuracy of open-system dynamics modeling.

Contribution

The authors develop a non-Markovian quantum master equation that captures temporally correlated and field-dependent dissipative effects in driven quantum systems, surpassing traditional approximations.

Findings

Correlated and field-dependent dissipation can enhance single-qubit gate performance.

The new method accurately tracks decay channels and generalized rates.

Application demonstrated on a driven two-level system.

Abstract

The ubiquitous effects of the environment on quantum-mechanical systems generally cause temporally correlated fluctuations. This particularly holds for systems of interest for quantum computation where such effects lead to correlated errors. The Markovian approximation neglects these correlations and thus fails to accurately describe open-system dynamics where these correlations become relevant. In driven open systems, yet another approximation is persistently used, often unknowingly, in which one describes the decay effects independently from the time-dependent controlling fields acting on the system, thereby ignoring further temporally correlated effects. To overcome these shortcomings, we develop a quantum master equation for driven systems weakly coupled to quantum environments that avoids the aforementioned field-independent approximation, as well as the Markovian approximation. Our method makes it possible to track all occurring decay channels and their time-dependent generalized rates which we illustrate in the example of a generally driven two-level system. We also demonstrate that correlated and field-dependent dissipative effects can lead to an increase in the performance of single-qubit gate operations.