P2G-4 Suppression of Acoustic Energy Leakage in FBARs with Al Bottom Electrode: FEM Simulation and Experimental Results

R. Ohara, N. Yanase, T. Yasumoto, M. Kawase, S. Masuko, T. Ohno, K. Sano
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引用次数: 8

Abstract

One of the most challenging issues in designing film bulk acoustic wave resonators (FBARs) is how to realize high-Q resonators. According to our experimental results, an acoustic leakage is the dominant loss factor at antiresonance frequency for FBARs with an aluminum bottom electrode. In this paper, we report simulation results obtained using the 2-dimensional finite element method (2D FEM), which was employed in order to confirm the above-mentioned acoustic loss mechanisms and optimize the design parameters of the resonator. As a result, optimizing the aluminum bottom electrode thickness and properly designing an attenuation structure that reflects the laterally propagating Lamb waves inside the resonator areas suppress the acoustical leakage significantly. Comparisons between FEM simulation and measured results in terms of the relationship between the Q-factors at antiresonance frequency and the structural parameters of the resonators are shown.
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铝底电极抑制fbar中P2G-4声能泄漏:有限元模拟与实验结果
如何实现高q谐振器是膜体声波谐振器设计中最具挑战性的问题之一。根据我们的实验结果,声泄漏是铝底电极fbar在反共振频率下的主要损耗因素。本文报道了利用二维有限元法(2D FEM)进行的仿真结果,以确定上述声损失机理并优化谐振器的设计参数。结果表明,优化铝底电极厚度,合理设计反射腔内横向传播的兰姆波的衰减结构,可显著抑制腔内漏声。对比了有限元模拟结果与实测结果在反共振频率处的q因子与谐振器结构参数的关系。
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