Optomechanics Driven by Noisy and Narrowband Fields

We report a study of a cavity optomechanical system driven by narrowband electromagnetic fields, which are applied either in the form of uncorrelated noise, or as a more structured spectrum. The bandwidth of the driving spectra is smaller than the mechanical resonant frequency, and thus we can descr...

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Bibliographic Details
Published in:Journal of low temperature physics 2024, Vol.217 (5-6), p.720-734
Main Authors: Banniard, Louise, Wang, Cheng, Stirpe, Davide, Børkje, Kjetil, Massel, Francesco, Mercier de Lépinay, Laure, Sillanpää, Mika A.
Format: Article
Language:English
Subjects:
Bandwidths
Characterization and Evaluation of Materials
Condensed Matter Physics
Damping
Electromagnetic fields
Magnetic Materials
Magnetism
Mechanical oscillators
Narrowband
Noise threshold
Opto-mechanics
Physics
Physics and Astronomy
Resonant frequencies
Self oscillation
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Summary:We report a study of a cavity optomechanical system driven by narrowband electromagnetic fields, which are applied either in the form of uncorrelated noise, or as a more structured spectrum. The bandwidth of the driving spectra is smaller than the mechanical resonant frequency, and thus we can describe the resulting physics using concepts familiar from regular cavity optomechanics in the resolved-sideband limit. With a blue-detuned noise driving, the noise-induced interaction leads to anti-damping of the mechanical oscillator, and a self-oscillation threshold at an average noise power that is comparable to that of a coherent driving tone. This process can be seen as noise-induced dynamical amplification of mechanical motion. However, when the noise bandwidth is reduced down to the order of the mechanical damping, we discover a large shift of the power threshold of self-oscillation. This is due to the oscillator adiabatically following the instantaneous noise profile. In addition to blue-detuned noise driving, we investigate narrowband driving consisting of two coherent drive tones nearby in frequency. Also in these cases, we observe deviations from a naive optomechanical description relying only on the tones’ frequencies and powers.
ISSN:0022-2291
1573-7357
DOI:10.1007/s10909-024-03220-z