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Frequency stabilization of self-sustained oscillations in a sideband-driven electromechanical resonator

B. Zhang, Yingming Yan, X. Dong, M. I. Dykman, H. B. Chan

2024Physical Review Applied14 citationsDOIOpen Access PDF

Abstract

We present a method to stabilize the frequency of self-sustained vibrations in micromechanical and nanomechanical resonators. The method refers to a two-mode system with the vibrations at significantly different frequencies. The signal from one mode is used to control the other mode. In the experiment, self-sustained oscillations of micromechanical modes are excited by pumping at the blue-detuned sideband of the higher-frequency mode. Phase fluctuations of the two modes show near-perfect anticorrelation. They can be compensated in either of the modes by a stepwise change of the pump phase. The phase change of the controlled mode is proportional to the pump phase change, with the proportionality constant independent of the pump amplitude and frequency. This finding allows us to stabilize the phase of one mode against phase diffusion using the measured phase of the other mode. We demonstrate that phase fluctuations of either the high-frequency mode or the low-frequency mode can be significantly reduced. The results open new opportunities in generating stable vibrations in a broad frequency range via parametric down-conversion in nonlinear resonators. Published by the American Physical Society 2024

Topics & Concepts

ResonatorSidebandPhysicsSelf-oscillationAcousticsOscillation (cell signaling)Control theory (sociology)OpticsComputer scienceQuantum mechanicsControl (management)MicrowaveGeneticsArtificial intelligenceBiologyMechanical and Optical ResonatorsAcoustic Wave Resonator TechnologiesAdvanced MEMS and NEMS Technologies
Frequency stabilization of self-sustained oscillations in a sideband-driven electromechanical resonator | Litcius