Tolerance Analysis of Comb-Driving Double Ended Tuning Fork Resonator Fabricated by DRIE Technology

Rui Li Meng; Hong Qun Zhang; Heng Liu

doi:10.4028/www.scientific.net/KEM.609-610.1375

Paper Titles

Design and Research of Dynamical Property Testing System for Nano and Micron Inertial Components
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Kinematic Analysis of Ultrasonic Vibration Assisted Micro End Grinding
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Artifacts in KPFM in FM, AM and Heterodyne AM Modes
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Research on Natural Frequency of MEMS Structure with Meander Suspensions by Mechanical Character Analysis
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Tolerance Analysis of Comb-Driving Double Ended Tuning Fork Resonator Fabricated by DRIE Technology
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Effects of Structure and Air Damping on Quality Factor under Various Pressure Environments Based on Experimental Research
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Effects of Droplets' Collision on Heat and Mass Transfer between High-Temperature Gas and Micron Water Droplets
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Observation of Ferromagnetic Resonance in Magnetic Exchange Force Microscopy (MExFM)
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Investigation on Multi-Piezoelectric Effects from the First Positive Piezoelectric Effect
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Tolerance Analysis of Comb-Driving Double Ended Tuning Fork Resonator Fabricated by DRIE Technology

Abstract:

Deep reactive ion etching (DRIE) process is specially invented for bulk micromachining fabrication with the objective of realizing high aspect ratio microstructures. However, various tolerances, such as slanted etched profile, uneven deep beams and undercut, cannot be avoided during the fabrication process. In this paper, the slanted etched profile fabrication tolerance with its effect on the performances of lateral comb-driving resonator, in terms of electrostatic force, mechanical stiffness, and resonance frequency, are discussed. It shows that comb finger with positive slope generates larger electrostatic force. The mechanical stiffness along lateral direction increases when the suspended beam slants negatively. The resonance frequency is 1.116 times larger if the comb finger and beam are tapered to -2⁰ and + 2⁰, respectively. These analytical results can be used to compensate the fabrication tolerances at design stage and allow the resonator to provide more predictable performance.