Acoustic wavelength effects on the propagation of SAW on piezo-crystal and polymer substrates

RSM 2013 IEEE Regional Symposium on Micro and Nanoelectronics Pub Date : 2013-09-01 DOI:10.1109/RSM.2013.6706501

A. F. Malik, Z. A. Burhanudin, V. Jeoti, U. Hashim, K. L. Foo, M. Ismail

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引用次数: 2

Abstract

The design, fabrication and characterization of Surface Acoustic Wave (SAW) delay lines on piezo-crystalline and polymer substrate is outlined in this paper. The SAW delay lines consist of two sets of Inter-Digital Transducers (IDT) separated by a certain distance on the surface of the piezoelectric substrate. Initially, the design parameters of the SAW delay lines are obtained using Impulse Response model. Then, the device is fabricated using conventional lithography process. The transmission coefficients (S21) of the SAW devices fabricated on 500 μm-thick Lithium Niobate (LiNbO3) and on 110 μm-thick polyvinyldeneflouride (PVDF) substrates are then observed using vector network analyzer. It is found that SAW devices designed to operate at 55-196 MHz on LiNbO3 has S21 with losses within 10-20 dB. On the other hand, SAW devices designed to operate on PVDF, do not show any credible signal. The successful transmission of SAW on LiNbO3 shows that appropriate design, fabrication and characterization methodology has been adopted. Unfortunately, due to the thin PVDF layer, the acoustic signal transverse downward beyond the thickness of the PVDF rendering the SAW devices non-operational. From the data collected, it is therefore believed that successful generation of SAW on piezo-crystal and polymer substrate could only be realized if the thickness of the PVDF is at least six times the acoustic wavelength of the SAW itself.

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声波波长对声表面波在压电晶体和聚合物衬底上传播的影响

本文概述了压电晶体和聚合物衬底表面声波延迟线的设计、制作和性能表征。SAW延迟线由压电衬底表面间隔一定距离的两组数字间换能器(IDT)组成。首先，利用脉冲响应模型得到SAW延迟线的设计参数。然后，采用常规光刻工艺制作该器件。利用矢量网络分析仪测量了在500 μm厚的铌酸锂(LiNbO3)和110 μm厚的聚偏氟乙烯(PVDF)衬底上制备的SAW器件的透射系数S21。研究发现，在LiNbO3上工作在55-196 MHz的SAW器件具有S21，损耗在10-20 dB之间。另一方面，设计用于PVDF的SAW设备不会显示任何可靠的信号。SAW在LiNbO3上的成功传输表明采用了合适的设计、制造和表征方法。不幸的是，由于PVDF层很薄，声信号横向向下超过PVDF的厚度，使得SAW设备无法工作。因此，从收集到的数据来看，只有PVDF的厚度至少是SAW本身声波波长的6倍，才能在压电晶体和聚合物衬底上成功产生SAW。

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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RSM 2013 IEEE Regional Symposium on Micro and Nanoelectronics

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