Manipulation and enhancement of asymmetric steering via interference effects induced by closed-loop coupling

We present a phase control method for a general three-mode system with closed-loop in coupling that drives the system into an entangled steady state and produces directional steering between two completely symmetric modes via quantum interference effects. In the scheme, two modes are coupled with ea...

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Bibliographic Details
Published inarXiv.org
Main Authors Zheng, Shasha, Sun, Fengxiao, Lai, Yijie, Gong, Qihuang, He, Qiongyi
Format Paper Journal Article
LanguageEnglish
Published Ithaca Cornell University Library, arXiv.org 20.12.2018
Subjects
Antiferromagnetism
Asymmetry
Correlation
Coupled modes
Coupling
Damping
Entanglement
Interference
Phase control
Physics - Quantum Physics
Quantum interference effects
Steady state
Steering
Subsystems
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Summary:We present a phase control method for a general three-mode system with closed-loop in coupling that drives the system into an entangled steady state and produces directional steering between two completely symmetric modes via quantum interference effects. In the scheme, two modes are coupled with each other both by a direct binary interaction and by an indirect interaction through a third intermediate damping mode, creating interference effects determined by the relative phase between the two physical interaction paths. By calculating the populations and correlations of the two modes, we show that depending on the phase, two modes can be prepared into an entangled steady state with asymmetric and directional steering even if they possess completely symmetric decoherence properties. Meanwhile, entanglement and steering can be significantly enhanced due to constructive interference, and thus more robust to thermal noises. This provides an active method to manipulate the asymmetry of steering instead of adding asymmetric losses or noises on subsystems at the cost of reducing steerability. Moreover, we show that the interference effects can also enhance and control the correlations between other pair of modes in the loop with opposite phase dependent behavior, indicating monogamy constraints for distributing correlations among multipartite. The present model could be applied in cavity optomechanical systems or in antiferromagnets where all components can mutually interact.
ISSN:2331-8422
DOI:10.48550/arxiv.1812.08354