An Interferometrically Robust Opto-Mechanical Coupler to Beam Polarisation

In this work, we investigate a tool for hybrid quantum systems that implements a transducer to map small position changes of a micro-mechanical membrane onto the polarization of a laser beam. This is achieved with an interferometric setup that has reduced needs for stabilization. Specifically, an os...

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Bibliographic Details
Published in:arXiv.org 2023-01
Main Authors: Hayat Abbas, Fernholz, Thomas
Format: Article
Language:English
Subjects:
Hybrid systems
Laser beams
Mechanical oscillators
Membranes
Polarization
Robustness
Signal to noise ratio
Silicon nitride
Online Access:Get full text
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Summary:In this work, we investigate a tool for hybrid quantum systems that implements a transducer to map small position changes of a micro-mechanical membrane onto the polarization of a laser beam. This is achieved with an interferometric setup that has reduced needs for stabilization. Specifically, an oscillating silicon nitride membrane placed in the middle of an asymmetric optical cavity causes phase shifts in the reflected, near-resonant light field. A beam displacer is used to combine the signal beam with a mode-matched, orthogonally polarized reference beam for polarization encoding. Subsequent balanced homodyne measurement is used to detect thermal membrane noise. Minor improvements in the design should achieve sufficiently high signal-to-noise ratio for the detection of motional quantum noise in the regime of high opto-mechanical coupling strength. This setup can provide a robust quantum link between a micro-mechanical oscillator and other systems such as atomic ensembles.
ISSN:2331-8422