Related papers: Macroscopic quantumness of optically conditioned mechanical systems

Macroscopic quantumness of optically conditioned mechanical systems

URL: http://arxiv.org/abs/2004.11400v1
Date: Thu, 23 Apr 2020 18:01:04 GMT
Title: Macroscopic quantumness of optically conditioned mechanical systems
Authors: Hannah McAleese, Mauro Paternostro
Abstract summary: We address the macroscopic quantumness of the state of mechanical systems subjected to conditional protocols devised for state engineering in cavity optomechanics. We show how measurements performed over the cavity field are able to steer the latter towards large quantum coherent states. Our study is relevant for and applicable to a broad range of settings, from clamped to levitated mechanical systems.
Score: 0.0
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: We address the macroscopic quantumness of the state of mechanical systems subjected to conditional protocols devised for state engineering in cavity optomechanics. We use a measure of macroscopicity based on phase-space methods. We cover the domain from weak to strong optomechanical coupling, illustrating how measurements performed over the cavity field that drives the dynamics of a mechanical system are able to steer the latter towards large quantum coherent states. The effect of losses is evaluated for the case of an open cavity, and analyzed in terms of the features of the Wigner functions of the state of the mechanical system. We also address the case of engineered phonon-subtracted mechanical systems, in full open-system configuration, demonstrating the existence of optimal working points for the sake of mesoscopic quantumness. Our study is relevant for and applicable to a broad range of settings, from clamped to levitated mechanical systems.

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