Quantitative Determination of the Mechanical Properties of Nanomembrane Resonators by Vibrometry In Continuous Light
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We present an experimental study of the bending waves of freestanding Si3N4 nanomembranes using optical profilometry in varying environments such as pressure and temperature. We introduce a method, named Vibrometry in Continuous Light (VICL) that enables us to disentangle the response of the membrane from the one of the excitation system, thereby giving access to the eigenfrequency and the quality (Q) factor of the membrane by fitting a model of a damped driven harmonic oscillator to the experimental data. The validity of particular assumptions or aspects of the model such as damping mechanisms, can be tested by imposing additional constraints on the fitting procedure. We verify the performance of the method by studying two modes of a 478 nm thick Si3N4 freestanding membrane and find Q factors of 2 x 104 for both modes at room temperature. Finally, we observe a linear increase of the resonance frequency of the ground mode with temperature which amounts to 550 Hz=/°C for a ground mode frequency of 0:447 MHz. This makes the nanomembrane resonators suitable as high-sensitive temperature sensors.
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YANG, Fan, Reimar WAITZ, Elke SCHEER, 2017. Quantitative Determination of the Mechanical Properties of Nanomembrane Resonators by Vibrometry In Continuous LightBibTex
@unpublished{Yang2017-04-18T13:23:20ZQuant-43575,
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title={Quantitative Determination of the Mechanical Properties of Nanomembrane Resonators by Vibrometry In Continuous Light},
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<dcterms:abstract xml:lang="eng">We present an experimental study of the bending waves of freestanding Si<sub>3</sub>N<sub>4</sub> nanomembranes using optical profilometry in varying environments such as pressure and temperature. We introduce a method, named Vibrometry in Continuous Light (VICL) that enables us to disentangle the response of the membrane from the one of the excitation system, thereby giving access to the eigenfrequency and the quality (Q) factor of the membrane by fitting a model of a damped driven harmonic oscillator to the experimental data. The validity of particular assumptions or aspects of the model such as damping mechanisms, can be tested by imposing additional constraints on the fitting procedure. We verify the performance of the method by studying two modes of a 478 nm thick Si<sub>3</sub>N<sub>4</sub> freestanding membrane and find Q factors of 2 x 10<sup>4</sup> for both modes at room temperature. Finally, we observe a linear increase of the resonance frequency of the ground mode with temperature which amounts to 550 Hz=/°C for a ground mode frequency of 0:447 MHz. This makes the nanomembrane resonators suitable as high-sensitive temperature sensors.</dcterms:abstract>
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