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Main Authors: Ma, M., Welles, N., Svitelskiy, O., Yanik, C., Kaya, I. I., Hanay, M. S., Paul, M. R., Ekinci, K. L.
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2408.13429
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author Ma, M.
Welles, N.
Svitelskiy, O.
Yanik, C.
Kaya, I. I.
Hanay, M. S.
Paul, M. R.
Ekinci, K. L.
author_facet Ma, M.
Welles, N.
Svitelskiy, O.
Yanik, C.
Kaya, I. I.
Hanay, M. S.
Paul, M. R.
Ekinci, K. L.
contents Even a relatively weak drive force is enough to push a typical nanomechanical resonator into the nonlinear regime. Consequently, nonlinearities are widespread in nanomechanics and determine the critical characteristics of nanoelectromechanical systems (NEMS) resonators. A thorough understanding of the nonlinear dynamics of higher eigenmodes of NEMS resonators would be beneficial for progress, given their use in applications and fundamental studies. Here, we characterize the nonlinearity and the linear dynamic range (LDR) of each eigenmode of two nanomechanical beam resonators with different intrinsic tension values up to eigenmode $n=11$. We find that the modal Duffing constant increases as $n^4$, while the critical amplitude for the onset of nonlinearity decreases as $1/n$. The LDR, determined from the ratio of the critical amplitude to the thermal noise amplitude, increases weakly with $n$. Our findings are consistent with our theory treating the beam as a string, with the nonlinearity emerging from stretching at high amplitudes. These scaling laws, observed in experiments and validated theoretically, can be leveraged for pushing the limits of NEMS-based sensing even further.
format Preprint
id arxiv_https___arxiv_org_abs_2408_13429
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Mode-Dependent Scaling of Nonlinearity and Linear Dynamic Range in a NEMS Resonator
Ma, M.
Welles, N.
Svitelskiy, O.
Yanik, C.
Kaya, I. I.
Hanay, M. S.
Paul, M. R.
Ekinci, K. L.
Applied Physics
Even a relatively weak drive force is enough to push a typical nanomechanical resonator into the nonlinear regime. Consequently, nonlinearities are widespread in nanomechanics and determine the critical characteristics of nanoelectromechanical systems (NEMS) resonators. A thorough understanding of the nonlinear dynamics of higher eigenmodes of NEMS resonators would be beneficial for progress, given their use in applications and fundamental studies. Here, we characterize the nonlinearity and the linear dynamic range (LDR) of each eigenmode of two nanomechanical beam resonators with different intrinsic tension values up to eigenmode $n=11$. We find that the modal Duffing constant increases as $n^4$, while the critical amplitude for the onset of nonlinearity decreases as $1/n$. The LDR, determined from the ratio of the critical amplitude to the thermal noise amplitude, increases weakly with $n$. Our findings are consistent with our theory treating the beam as a string, with the nonlinearity emerging from stretching at high amplitudes. These scaling laws, observed in experiments and validated theoretically, can be leveraged for pushing the limits of NEMS-based sensing even further.
title Mode-Dependent Scaling of Nonlinearity and Linear Dynamic Range in a NEMS Resonator
topic Applied Physics
url https://arxiv.org/abs/2408.13429