Generation of multipartite entangled states based on a double-longitudinal-mode cavity optomechanical system

Liu, Xiaomin; Yang, RongGuo; Zhang, Jing; Zhang, Tiancai

doi:10.1364/oe.496528

Opt. Express

2023

DOI: 10.1364/oe.496528

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Generation of multipartite entangled states based on a double-longitudinal-mode cavity optomechanical system

Xiaomin Liu,

RongGuo Yang,

Jing Zhang

et al.

Abstract: An optomechanical system is a promising platform to connect different “notes” of quantum networks. Therefore, entanglements generated from it is also of great importance. In this paper, the parameter dependence of optomechanical and optical-optical entanglements generated from the double-longitudinal-mode cavity optomechanical system are discussed and two quadrapartite entanglement generation schemes based on such a system are proposed. Furthermore, 2N and 4N-partite entangled states of optical modes can be ob… Show more

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Cited by 3 publications

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Quantum entanglement enhanced in hybrid cavity–magnon optomechanical systems

Wan,

Lin,

Cong

et al. 2024

Results in Physics

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Quantum entanglement enhanced in hybrid cavity–magnon optomechanical systems

Wan,

Lin,

Cong

et al. 2024

Results in Physics

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Enhanced force sensitivity based on Duffing nonlinearity in a dissipatively coupled optomechanical system

Zhu,

Han,

Wang

et al. 2024

Opt. Express

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The study of force sensitivity based on a cavity optomechanical system plays a prominent role in quantum precision measurement and provides an ideal platform for precision sensing technology. Here, we propose a scheme to enhance the force sensitivity of a dissipatively coupled optomechanical system by inducing Duffing nonlinearity. The numerical analysis shows that inducing Duffing nonlinearity significantly improves the force sensitivity compared to the system without Duffing nonlinearity, even surpassing the standard quantum limit (SQL) by more than five orders of magnitude. Moreover, we demonstrated that the sensitivity of force sensing is robust to temperature when Duffing nonlinearity is induced. More interestingly, the induction of Duffing nonlinearity broadens the detection bandwidth. At the same time, the detection frequency below the SQL also experiences a significant frequency shift with changes in the nonlinear amplitude. Our scheme not only holds potential for applications in quantum manipulation but also realizes macroscopic quantum effects.

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Generation of microwave-mechanics and magnon-optics entangled states

Xu Ming-Hui,

Liu Xiao-Min,

Shi Jia-Jia

et al. 2025

Acta Phys. Sin.

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Quantum entanglement is a key resource for performing quantum computing and building quantum communication networks. By injecting a microwave-optical dual-mode entanglement field into the system, as well as pumping the optical and microwave cavities, and by appropriately choosing the detuning relation between the pumping field and the modes, the paper shows that microwave-mechanics entanglement Eaband magnon-optics entanglement Ecmcan be generated simultaneously in the cavity opto-magnomechanics system, and the entanglement can be in a steady state. Specifically, the model is based on a hybrid quantum system of magnons, where a microwave-light entanglement generated by an optically pulsed superconducting electro-optical device through spontaneous parametric down-conversion process is injected as the intracavity field, and a blue-detuned microwave field is used to excite the magnon modes to produce magnon-phonon entanglement. By interacting with an optomechanical beam splitter and microwave-magnon state-swap interaction, steady microwave-mechanics entanglement Eab and magnon-optics entanglement Ecm are successfully realized. The entanglement Eaband Ecm in the system is analyzed using the logarithmic negativity. This paper mainly investigates the effect of several parameters of the system, such as environment temperature, coupling strength and dissipation rate, on the degree of entanglement. In particular, the entanglement Eab and Ecm generated in this system can exist both simultaneously and individually. Especially when gam=0, the entanglement Eab and Ecm still exist. Moreover, directly injecting entangled microwave-light into the system can significantly enhance the robustness of the entanglement against temperature, which will have broad application prospects in quantum information processing in quantum networks and hybrid quantum systems. Notably, the entanglement Eab and Ecm exist even at a temperature of 1.3K. The implications of our research has potential value for applications in the field of quantum information processing and quantum networks.

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Generation of multipartite entangled states based on a double-longitudinal-mode cavity optomechanical system

Cited by 3 publications

References 50 publications

Quantum entanglement enhanced in hybrid cavity–magnon optomechanical systems

Quantum entanglement enhanced in hybrid cavity–magnon optomechanical systems

Enhanced force sensitivity based on Duffing nonlinearity in a dissipatively coupled optomechanical system

Generation of microwave-mechanics and magnon-optics entangled states

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