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Main Authors: Jia, Jinhao, Li, Yingru, Liang, Ran, Zhang, Mei
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2604.15162
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author Jia, Jinhao
Li, Yingru
Liang, Ran
Zhang, Mei
author_facet Jia, Jinhao
Li, Yingru
Liang, Ran
Zhang, Mei
contents We propose a coherent-control scheme for engineering quantum correlations in a cavity optomechanical (COM) system consisting of a driven optical cavity with an embedded nonlinear medium and a membrane, assisted by a coherent feedback loop. The nonlinear medium and the membrane are pumped to implement optical and mechanical parametric amplifications with controllable modulation frequencies and pump amplitudes. Through the combined modulation of the two parametric amplifications and the coherent feedback loop, we engineer the effective cavity decay rate and the distribution of quantum fluctuations, thereby strengthening quantum correlations and improving their robustness against thermal noise. Our scheme provides an efficient route to realizing highly tunable, strong, thermally robust quantum correlations in COM systems, which is promising for the protection of fragile quantum resources.
format Preprint
id arxiv_https___arxiv_org_abs_2604_15162
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Coherent control of optomechanical entanglement and steering via dual parametric amplification
Jia, Jinhao
Li, Yingru
Liang, Ran
Zhang, Mei
Quantum Physics
We propose a coherent-control scheme for engineering quantum correlations in a cavity optomechanical (COM) system consisting of a driven optical cavity with an embedded nonlinear medium and a membrane, assisted by a coherent feedback loop. The nonlinear medium and the membrane are pumped to implement optical and mechanical parametric amplifications with controllable modulation frequencies and pump amplitudes. Through the combined modulation of the two parametric amplifications and the coherent feedback loop, we engineer the effective cavity decay rate and the distribution of quantum fluctuations, thereby strengthening quantum correlations and improving their robustness against thermal noise. Our scheme provides an efficient route to realizing highly tunable, strong, thermally robust quantum correlations in COM systems, which is promising for the protection of fragile quantum resources.
title Coherent control of optomechanical entanglement and steering via dual parametric amplification
topic Quantum Physics
url https://arxiv.org/abs/2604.15162