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Main Authors: Brown, Sofia C., Shaniv, Ravid, Zhang, Ruomu, Reetz, Chris, Regal, Cindy A.
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2510.13041
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author Brown, Sofia C.
Shaniv, Ravid
Zhang, Ruomu
Reetz, Chris
Regal, Cindy A.
author_facet Brown, Sofia C.
Shaniv, Ravid
Zhang, Ruomu
Reetz, Chris
Regal, Cindy A.
contents Sensing via a mechanical frequency shift is a powerful measurement tool, and, therefore, understanding and mitigating frequency noise affecting mechanical resonators is imperative. Thermomechanical noise fundamentally limits mechanical frequency stability, and its impact can be reduced with increased coherent amplitude of mechanical motion. However, large enough actuation places the resonator in the nonlinear (Duffing) regime, where conversion of amplitude noise (AM) into frequency noise (FM) can worsen sensor performance. Here, we present an experimentally straightforward method to evade this amplitude tradeoff in micromechanical sensors. Combining knowledge of the Duffing coefficients with readily available amplitude measurements, we avoid AM-FM conversion. Our approach uses dual-mechanical-mode operation on a tensioned thin-film resonator to set a baseline thermomechanically-limited stability by eliminating correlated single-mode frequency drifts. Thus, we cleanly observe AM-FM conversion at high drive, and reduce it using our method. The resulting high-stability operation beyond the linear regime contrasts long-standing perspectives in the field.
format Preprint
id arxiv_https___arxiv_org_abs_2510_13041
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle High Stability Mechanical Frequency Sensing beyond the Linear Regime
Brown, Sofia C.
Shaniv, Ravid
Zhang, Ruomu
Reetz, Chris
Regal, Cindy A.
Mesoscale and Nanoscale Physics
Sensing via a mechanical frequency shift is a powerful measurement tool, and, therefore, understanding and mitigating frequency noise affecting mechanical resonators is imperative. Thermomechanical noise fundamentally limits mechanical frequency stability, and its impact can be reduced with increased coherent amplitude of mechanical motion. However, large enough actuation places the resonator in the nonlinear (Duffing) regime, where conversion of amplitude noise (AM) into frequency noise (FM) can worsen sensor performance. Here, we present an experimentally straightforward method to evade this amplitude tradeoff in micromechanical sensors. Combining knowledge of the Duffing coefficients with readily available amplitude measurements, we avoid AM-FM conversion. Our approach uses dual-mechanical-mode operation on a tensioned thin-film resonator to set a baseline thermomechanically-limited stability by eliminating correlated single-mode frequency drifts. Thus, we cleanly observe AM-FM conversion at high drive, and reduce it using our method. The resulting high-stability operation beyond the linear regime contrasts long-standing perspectives in the field.
title High Stability Mechanical Frequency Sensing beyond the Linear Regime
topic Mesoscale and Nanoscale Physics
url https://arxiv.org/abs/2510.13041