# Completely positive master equation for arbitrary driving and small   level spacing

**Authors:** Evgeny Mozgunov, Daniel Lidar

arXiv: 1908.01095 · 2020-02-12

## TL;DR

This paper introduces a generalized, completely positive Markovian master equation suitable for arbitrary driving and small level spacing, expanding the applicability of open quantum system modeling.

## Contribution

It derives a time-dependent coarse-grained master equation from the Redfield equation, valid for fast driving and small level spacings, with rigorous error bounds.

## Key findings

- The new master equation is completely positive and locally generated.
- It applies to arbitrarily fast time-dependent Hamiltonians.
- Dynamical decoupling can extend coherence times in a Markovian framework.

## Abstract

Markovian master equations are a ubiquitous tool in the study of open quantum systems, but deriving them from first principles involves a series of compromises. On the one hand, the Redfield equation is valid for fast environments (whose correlation function decays much faster than the system relaxation time) regardless of the relative strength of the coupling to the system Hamiltonian, but is notoriously non-completely-positive. On the other hand, the Davies equation preserves complete positivity but is valid only in the ultra-weak coupling limit and for systems with a finite level spacing, which makes it incompatible with arbitrarily fast time-dependent driving. Here we show that a recently derived Markovian coarse-grained master equation (CGME), already known to be completely positive, has a much expanded range of applicability compared to the Davies equation, and moreover, is locally generated and can be generalized to accommodate arbitrarily fast driving. This generalization, which we refer to as the time-dependent CGME, is thus suitable for the analysis of fast operations in gate-model quantum computing, such as quantum error correction and dynamical decoupling. Our derivation proceeds directly from the Redfield equation and allows us to place rigorous error bounds on all three equations: Redfield, Davies, and coarse-grained. Our main result is thus a completely positive Markovian master equation that is a controlled approximation to the true evolution for any time-dependence of the system Hamiltonian, and works for systems with arbitrarily small level spacing. We illustrate this with an analysis showing that dynamical decoupling can extend coherence times even in a strictly Markovian setting.

## Full text

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## Figures

20 figures with captions in the complete paper: https://tomesphere.com/paper/1908.01095/full.md

## References

82 references — full list in the complete paper: https://tomesphere.com/paper/1908.01095/full.md

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Source: https://tomesphere.com/paper/1908.01095