Related papers: Large mechanical squeezing beyond 3dB of hybrid atom-optomechanical systems in highly unresolved sideband regime

Large mechanical squeezing beyond 3dB of hybrid atom-optomechanical systems in highly unresolved sideband regime

URL: http://arxiv.org/abs/2004.08768v1
Date: Sun, 19 Apr 2020 04:55:29 GMT
Title: Large mechanical squeezing beyond 3dB of hybrid atom-optomechanical systems in highly unresolved sideband regime
Authors: Jian-Song Zhang and Ai-Xi Chen
Abstract summary: We propose a scheme for the generation of strong mechanical squeezing beyond 3dB in hybrid atom-optomechanical systems. Our scheme paves the way toward the implementation of strong mechanical squeezing beyond 3dB in hybrid atom-optomechanical systems in experiments.
Score: 1.3564037908388413
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: We propose a scheme for the generation of strong mechanical squeezing beyond 3dB in hybrid atom-optomechanical systems in the highly unresolved sideband (HURSB) regime where the decay rate of cavity is much larger than the frequency of the mechanical oscillator. The system is formed by two two-level atomic ensembles and an optomechanical system with cavity driven by two lasers with different amplitudes. In the HURSB regime, the squeezing of the movable mirror can not be larger than 3dB if no atomic ensemble or only one atomic ensemble is put into the optomechanical system. However, if two atomic ensembles are put into the optomechanical system, the strong mechanical squeezing beyond 3dB is achieved even in the HURSB regime. Our scheme paves the way toward the implementation of strong mechanical squeezing beyond 3dB in hybrid atom-optomechanical systems in experiments.

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