Investigation of Elastic Properties of WO3 Thin Films Supported on Quartz in Surface Acoustic Wave Sensing Devices

M. Arab, V. Madigou, V. Chevallier, C. Turquat, C. Leroux
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引用次数: 2

Abstract

This study aims to discuss the combined theoretical and experimental results of elastic properties of tungsten trioxide films supported on Quartz (YX)/45°/10° resonator to form surface acoustic wave (SAW) devices. The SAW systems with different thicknesses of WO3 thin films were imaged and structurally characterized by X-ray diffraction, atomic force, and transmission electron microscopy. The deposited WO3 films (100, 200, and 300 nm of thickness) crystallized in a single monoclinic phase. The acoustoelectric properties of the SAW system were obtained by combining theoretical simulations with experimental measurements. The modeling of the SAW devices has been performed by the finite element and boundary element methods (FEM/BEM). The elastic constants of the films at room temperature were assessed via electrical admittances experiments in light of theoretical calculations. The gravimetric effect of the deposited layers is observed by a shift of the resonance frequency to lower values as the thickness of the films increases. Moreover, the acoustic losses are affected by the dielectric losses of the WO3 films while the resonant frequency decreases almost linearly. SAW devices revealed strong displacement fields with low acoustic losses as a function of WO3 thicknesses. For all the deposited layers, the measured Young’s moduli and Poisson’s ratios are 8 GPa and 0.5, respectively.
石英支撑WO3薄膜在表面声波传感器件中的弹性性能研究
本研究旨在讨论石英(YX)/45°/10°谐振腔支撑三氧化钨薄膜形成表面声波(SAW)器件的弹性性能的理论与实验相结合的结果。利用x射线衍射、原子力和透射电镜对不同WO3薄膜厚度的SAW系统进行了成像和结构表征。沉积的WO3薄膜(厚度分别为100nm、200nm和300nm)在单斜相中结晶。通过理论模拟和实验测量相结合,得到了声表面波系统的声电特性。采用有限元法和边界元法(FEM/BEM)对SAW器件进行了建模。在理论计算的基础上,通过电导纳实验确定了薄膜在室温下的弹性常数。随着薄膜厚度的增加,共振频率向较低的值移动,从而观察到沉积层的重力效应。WO3薄膜的介电损耗对声损失有影响,谐振频率几乎呈线性减小。SAW器件显示出强位移场和低声损失,这是WO3厚度的函数。对于所有沉积层,测量的杨氏模量和泊松比分别为8 GPa和0.5。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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