Intrinsic Kerr amplification for microwave electromechanics

Scarano, Ermes; Arvidsson, Elisabet K.; Roos, August K.; Holmgren, Erik; Haviland, David B.

doi:10.1063/5.0201936

Applied Physics Letters

2024

DOI: 10.1063/5.0201936

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Intrinsic Kerr amplification for microwave electromechanics

Ermes Scarano,

Elisabet K. Arvidsson,

August K. Roos

et al.

Abstract: Electromechanical transduction gain of 21 dB is realized in a micro-cantilever resonant force sensor operated in the unresolved-sideband regime. Strain-dependent kinetic inductance weakly couples cantilever motion to a superconducting nonlinear resonant circuit. A single pump generates motional sidebands and parametrically amplifies them via four-wave mixing. We study the gain and added noise, and we analyze potential benefits of this integrated amplification process in the context force sensitivity.

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Self-sustained optomechanical state destruction triggered by the Kerr nonlinearity

Delattre,

Golokolenov,

Pedurand

et al. 2024

Phys. Rev. Research

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Cavity optomechanics implements a unique platform where moving objects can be probed by quantum fields, either laser light or microwave signals. With a pump tone driving at a frequency above the cavity resonance, self-sustained oscillations can be triggered at large injected powers. These limit-cycle dynamics are particularly rich, presenting hysteretic behaviors, broad comb signals, and especially large motion amplitudes. All of these features can be exploited for both fundamental quantum research and engineering. Here we present low-temperature microwave experiments performed on a high-Q cavity resonance capacitively coupled to the flexure of a beam resonator. We study the limit-cycle dynamics parameter space as a function of pump parameters (detuning, power). Unexpectedly, we find that in a region of this parameter space the microwave resonance is irremediably destroyed: Only a dramatic power reset can restore the dynamics to its original state. The phenomenon can be understood as an optical instability linked to the Kerr nonlinearity of the cavity. A theory supporting this claim is presented, reproducing almost quantitatively the measurement. This remarkable feature might be further optimized and represents a new resource for quantum microwave circuits. Published by the American Physical Society 2024

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Self-sustained optomechanical state destruction triggered by the Kerr nonlinearity

Delattre,

Golokolenov,

Pedurand

et al. 2024

Phys. Rev. Research

View full text Add to dashboard Cite

show abstract

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Intrinsic Kerr amplification for microwave electromechanics

Cited by 1 publication

References 30 publications

Self-sustained optomechanical state destruction triggered by the Kerr nonlinearity

Self-sustained optomechanical state destruction triggered by the Kerr nonlinearity

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