Abstract

In various applications, damping from the surrounding fluid severely degrades the performance of micro-electro-mechanical systems (MEMS). In this paper, mechanical amplification through parametric resonance was investigated in a piezoelectrically actuated MEMS to overcome the effects of damping. The device was fabricated using the PiezoMUMPS process, which is based on a Silicon-on-Insulator (SOI) process with an additional aluminum nitride (AlN) layer. Here, a double-clamped cantilever beam with a concentrated mass at the center was excited at its first resonance mode (out-of-plane motion) in air and at atmospheric conditions. A parametric signal modulating the stiffness of the beam was added at twice the frequency of the excitation signal, which was swept through the resonance frequency of the mode. The displacement at the center of the device was detected optically. A four-fold increase in the quality-factor, Q, of the resonator was obtained at the highest values in amplitude used for the parametric excitation. The spring modulation constant was obtained from the effective quality-factor, , versus parametric excitation voltage curve. This study demonstrates that through these methods, significant improvements in performance of MEMS in fluids can be obtained, even for devices fabricated using standard commercial processes.

Highlights

  • Micro-electro-mechanical systems (MEMS) have enabled the miniaturization of a wide variety of sensor elements, allowing their integration into ever-smaller sensing platforms accross industries

  • Parametric amplification was evaluated in this device when operated in air and at atmospheric conditions

  • A four-fold increase in the quality-factor was obtained at the highest parametric excitations used

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Summary

Introduction

Micro-electro-mechanical systems (MEMS) have enabled the miniaturization of a wide variety of sensor elements, allowing their integration into ever-smaller sensing platforms accross industries. Likewise, their small size and mass makes them very sensitive to weak forces that change their resonant properties. While electronic feedback and signal control techniques have been used for dissipation control [12], a less resource demanding solution could potentially be attained through mechanical amplification via parametric resonance [13,14] This effect occurs in a resonant system when a time varying parameter is modulated, typically at twice the resonant frequency of the system.

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