Simulation and Fabrication of Higher‐Mode Lamb Wave Acoustic Devices for Sensing Applications

Physica status solidi (A): Applied research Pub Date : 2023-05-17 DOI:10.1002/pssa.202200760

M. Bharati, Lokesh Rana, Reema Gupta, Anjali Sharma, P. Jha, M. Tomar

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Abstract

Recently Lamb wave devices have originated as an alternate acoustic device for high‐frequency wireless sensing applications. Their potential for sensing devices, including biomedical diagnostics and environmental monitoring as a wireless and passive device, calls for further analysis of the device with higher sensitivity. ZnO‐based sensor has always been of research interest due to its biocompatibility, sensing abilities, and yet cost‐effectivity. A Lamb wave device based on ZnO/SiO2/Si membrane has been theoretically simulated using finite element analysis method (FEM) to study the higher modes, as higher working frequency leads to higher sensitivity of the device toward sensing applications. Optimized properties are identified and utilized for the fabrication of Lamb wave devices. It is observed that for optimized parameters of ZnO/SiO2/Si Lamb device, higher antisymmetric modes are not only advantageous for high sensitivity applications but also more stable within the given operating conditions. Experimentally obtained results indicate close matching with theoretical results.

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用于传感应用的高模兰姆波声学器件的仿真与制造

最近，兰姆波装置作为高频无线传感应用的替代声学装置而出现。它们在传感设备方面的潜力，包括生物医学诊断和作为无线和无源设备的环境监测，需要对具有更高灵敏度的设备进行进一步分析。由于其生物相容性、传感能力和成本效益，ZnO传感器一直是研究的热点。采用有限元方法对基于ZnO/SiO2/Si薄膜的Lamb波器件进行了理论模拟，研究了器件的高模态，因为工作频率越高，器件对传感应用的灵敏度越高。确定了优化的性能，并将其用于兰姆波器件的制造。结果表明，在优化的ZnO/SiO2/Si Lamb器件参数下，较高的反对称模式不仅有利于高灵敏度应用，而且在给定的工作条件下更稳定。实验结果与理论结果吻合较好。

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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Physica status solidi (A): Applied research

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