Jaynes-Cummings atoms coupled to a structured environment: Leakage elimination operators and the Petz recovery maps

TL;DR

This paper explores advanced quantum control techniques, including leakage elimination operators and Petz recovery maps, to suppress decoherence and fully recover the dynamics of Jaynes-Cummings atoms in structured environments.

Contribution

It introduces novel control and recovery strategies, particularly the application of Petz maps, for protecting quantum coherence in JC systems affected by complex environments.

Findings

Petz recovery maps enable full dynamics recovery of JC atoms.

Leakage elimination operators effectively suppress decoherence.

Control methods protect various coherence aspects.

Abstract

We consider the Jaynes-Cummings (JC) model embedded in a structured environment, where the atom inside an optical cavity will be affected by a hierarchical environment consisting of the cavity and its environment. We propose several effective strategies to control and suppress the decoherence effects to protect the quantum coherence of the JC atom. We study the non-perturbative control of the system dynamics by means of the leakage elimination operators. We also investigate a full quantum state reversal scheme by engineering the system and its coupling to the bath via the Petz recovery map. Our findings conclude that, with the Petz recovery map, the dynamics of the JC atom can be fully recovered regardless of Markov or non-Markovian noises. Finally, we show that our quantum control and recovery methods are effective at protecting different aspects of the system coherence.