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Study of loss mechanisms in temperature compensated surface acoustic wave devices based on finite element method analysis using hierarchical cascading technique

机译:基于分层级联技术的有限元方法分析的温度补偿表面声波器件损耗机制研究

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摘要

This paper discusses loss mechanisms of temperature compensated surface acoustic wave (TC-SAW) devices using the SiO2 overcoated 128 degrees YX-LiNbO3 (128-LN) substrate. Analysis is based on the finite element method (FEM) combined with the hierarchical cascading technique and the general purpose graphics processing unit. Three kinds of FEM model, i.e. 2.5D, three dimensional (3D) periodic and full 3D are analyzed without taking additional losses, i.e. material viscous loss, dielectric loss and electrode ohmic loss, and influence of scattering at structural discontinuities is evaluated solely. It is shown that although Q reduction is significant with an increase of the simulation dimension, in other words, that of the number of acoustic scattering mechanisms, estimated Q value is still considerably higher than reported values even for full 3D simulation. This result indicates that acoustic scattering at structural discontinuities is not a dominant loss mechanism in current TC-SAW devices employing the SiO2 overcoated 128-LN substrate. (C) 2020 The Japan Society of Applied Physics.
机译:本文讨论了使用SiO2过涂层128°YX-LIN-LIN-LINO3(128-LN)衬底的温度补偿表面声波(TC锯)装置的损耗机制。分析基于与分层级联技术和通用图形处理单元组合的有限元方法(FEM)。在不采取额外损失的情况下,分析了三种有限元模型,即2.5D,三维(3D)周期性和全3D,即,仅评估了材料粘性损失,介电损耗和电极欧姆损失,以及结构不连续的散射影响。结果表明,尽管Q减小随着模拟尺寸的增加而显着,但是换句话说,即使对于完整的3D模拟,估计Q值的估计Q值仍然远高于报告的值。该结果表明,结构不连续的声学散射不是采用SiO2过涂层128-LN基板的当前TC锯器件中的主要损耗机制。 (c)2020日本应用物理学会。

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  • 来源
    《Japanese journal of applied physics》 |2020年第sk期|SKKC06.1-SKKC06.5|共5页
  • 作者

    Matsuoka Naoto; Li Xinyi; Omori Tatsuya; Hashimoto Ken-ya;

  • 作者单位

    Nihon Dempa Kogyo Co Ltd Shibuya Ku Tokyo 1518569 Japan|Chiba Univ Grad Sch Sci & Engn Chiba 2638522 Japan;

    Chiba Univ Grad Sch Sci & Engn Chiba 2638522 Japan|Univ Elect Sci & Technol China Dept Elect Engn Chengdu 611731 Sichuan Peoples R China;

    Chiba Univ Grad Sch Sci & Engn Chiba 2638522 Japan;

    Chiba Univ Grad Sch Sci & Engn Chiba 2638522 Japan|Univ Elect Sci & Technol China Dept Elect Engn Chengdu 611731 Sichuan Peoples R China;

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