Modal interactions of flexural and torsional vibrations in a microcantilever

TL;DR

This study experimentally investigates nonlinear modal interactions in a microcantilever, revealing how flexural and torsional modes couple and influence each other's dynamics at high amplitudes, with implications for scanning probe microscopy.

Contribution

It provides the first detailed experimental analysis of nonlinear flexural-torsional modal interactions in microcantilevers, including tuning of nonlinear responses.

Findings

Nonlinear coupling affects resonance frequencies at high amplitudes.

Torsional modes exhibit frequency stiffening due to nonlinearities.

Balancing nonlinearities can linearize the response of driven modes.

Abstract

The nonlinear interactions between flexural and torsional modes of a microcantilever are experimentally studied. The coupling is demonstrated by measuring the frequency response of one mode, which is sensitive to the motion of another resonance mode. The flexural-flexural, torsional-torsional and flexural-torsional modes are coupled due to nonlinearities, which affect the dynamics at high vibration amplitudes and cause the resonance frequency of one mode to depend on the amplitude of the other modes. We also investigate the nonlinear dynamics of torsional modes, which cause a frequency stiffening of the response. By simultaneously driving another torsional mode in the nonlinear regime, the nonlinear response is tuned from stiffening to weakening. By balancing the positive and negative cubic nonlinearities a linear response is obtained for the strongly driven system. The nonlinear modal interactions play an important role in the dynamics of multi-mode scanning probe microscopes