Related papers: Synthetic magnetism enhanced mechanical squeezing in Brillouin optomechanical system

Synthetic magnetism enhanced mechanical squeezing in Brillouin optomechanical system

URL: http://arxiv.org/abs/2405.04508v2
Date: Thu, 20 Jun 2024 17:06:43 GMT
Title: Synthetic magnetism enhanced mechanical squeezing in Brillouin optomechanical system
Authors: D. R. Kenigoule Massembele, P. Djorwé, Souvik Agasti, K. S. Nisar, A. K. Sarma, A. H. Abdel-Aty,
Abstract summary: We propose a scheme to generate large amount of mechanical squeezing, far beyond the $rm3dB$ limit. Our scheme is based on synthetic magnetism in optomechanical system that hosts a BSBS process. Such a generated squeezed states can be used for quantum applications including quantum information processing.
Score: 0.0
License: http://creativecommons.org/licenses/by/4.0/
Abstract: We propose a scheme to generate large amount of mechanical squeezing, far beyond the $\rm{3dB}$ limit, which is based on synthetic magnetism in optomechanical system that hosts a Backward Stimulated Brillouin Scattering (BSBS) process. Our benchmark system consists of an acoustic mode coupled to two optical modes through the BSBS process, and a Duffing mechanical oscillator that couples to the same optical modes through the standard optomechanical radiation pressure. The synthetic magnetism comes from the modulation of the mechanical coupling between the acoustic and the mechanical mode. When there is no synthetic magnetism, a given amount of mechanical squeezing is generated in the system. This squeezing is mainly dependent on the BSBS process, and it is fragile against thermal noise. By switching on the synthetic magnetism, the degree of the generated squeezing is greatly enhanced and goes far beyond the limit of the $\rm{3dB}$. This large magnetism induced squeezing persists even when there is no BSBS process in the system. Moreover, this generated squeezing is robust enough against thermal noise in comparison to the one induced when the synthetic magnetism is off. Furthermore, both the mechanical variance squeezing and effective phonon number exhibit series of peaks and dips depending on the phase modulation of the mechanical coupling. This oscillatory feature is reminiscent of a sudden death and revival of squeezing phenomenon, which can be used to maintain a desired magnitude of squeezing by tuning this phase. Our proposal provides a path toward a flexible scheme that generates large amount of squeezing, far beyond the $\rm{3dB}$ limit. Such a generated squeezed states can be used for quantum applications including quantum information processing, quantum sensing and metrology, and quantum computing.

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