Nonreciprocal Mechanical Squeezing in a Spinning Optomechanical System

A nonreciprocal‐amplified scheme for signal transmission is proposed in a coupled rotation‐cavity system, where the two cavities rotate with opposite directions, and an optical parametric amplifier (OPA) is attached to one cavity. The coupling between cavities can effectively compensate and enhance the frequency shift of the Sagnac effect, and a perfect nonreciprocity can be achieved. Owing to the introduction of an OPA medium, eigenvalues of the dynamic matrix exhibit exceptional points (EPs), and the amplified‐nonreciprocal transmission can be obtained around EPs.

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Nonreciprocal Amplification in Coupled‐Rotating Cavities Around Exceptional Points

Peng

Zhao

Yang

et al. 2021

Annalen der Physik

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Bidirectional Optical Non‐Reciprocity in a Multi‐Mode Cavity Optomechanical System

2022

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Optical non‐reciprocity that allows unidirectional flow of optical field is pivoted on time reversal symmetry breaking, which originates from radiation pressure because of light–matter interaction in cavity optomechanical systems. Here, the non‐reciprocal transport of optical signals across two ports via three optical modes optomechanically coupled to the mechanical excitations of two nanomechanical resonators (NMRs) is studied under the influence of strong classical drive fields and weak probe fields. It is found that there exists the conversion of reciprocal to non‐reciprocal signal transmission via tuning the drive fields and perfect non‐reciprocal transmission of output fields is realized when the effective cavity detuning parameters are near resonant to the NMRs' frequencies. The unidirectional non‐reciprocal transport is robust to the optomechanical couplings around resonance conditions. Moreover, the loss rates of cavities play an inevitable role in the unidirectional flow of signal across the two ports. Bidirectional transmission can also be controlled by the phase changes associated with the probe and drive fields along with their relative phase. This scheme may provide a foundation for the compact non‐reciprocal communication and quantum information processing, thus enabling novel devices that route photons in unconventional ways such as all‐optical diodes, optical transistors, and optical switches.

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Probe Response of an Optomechanical System with Optomechanical Coupling Modulated Periodically

Chen,

Hong,

Yang

2023

Annalen der Physik

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In this study, the probe response of a cavity optomechanical system with periodic modulation of the optomechanical coupling is investigated. The modulation arises from the beat effect between two external coherent driving lights, with the beat frequency matching the modulation frequency. The transmission coefficient is derived for the probe field and significant amplification, rather than absorption in the conventional optomechanically induced transparency schemes, is observed near the transparent point when the modulation is introduced. In addition, the coupling modulation can also enhance the slow light effect.

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Nonreciprocal Mechanical Squeezing in a Spinning Optomechanical System

Cited by 12 publications

References 58 publications

Nonreciprocal Amplification in Coupled‐Rotating Cavities Around Exceptional Points

Nonreciprocal Amplification in Coupled‐Rotating Cavities Around Exceptional Points

Bidirectional Optical Non‐Reciprocity in a Multi‐Mode Cavity Optomechanical System

Probe Response of an Optomechanical System with Optomechanical Coupling Modulated Periodically

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