Theoretical Analysis of Mechanical Displacement Measurement Using a Multiple Cavity Mode Transducer

We present an optomechanical displacement transducer that relies on three cavity modes parametrically coupled to a mechanical oscillator and whose frequency spacing matches the mechanical resonance frequency. The additional resonances allow reaching the standard quantum limit at a substantially lower input power (compared to the case of a single cavity mode), as both sensitivity and quantum backaction are enhanced. Furthermore, it is shown that in the case of multiple cavity modes, coupling between the modes is induced via reservoir interaction, e. g., enabling quantum backaction noise cancellation. Experimental implementation of the schemes is discussed in both the optical and microwave domain.

Theoretical Analysis of Mechanical Displacement Measurement Using a Multiple Cavity Mode Transducer

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Nanomechanical resonators with low dissipation for quantum optomechanics

FEM simulation: Thermal properties of thin film quartz and silicon resonators

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