Influence of the electrical extensions in AlN-BAW resonators for in-liquid biosensors

2014 European Frequency and Time Forum (EFTF) Pub Date : 2014-06-23 DOI:10.1109/EFTF.2014.7331492

M. DeMiguel-Ramos, T. Mirea, J. Olivares, M. Clement, J. Sangrador, E. Iborra, M. Barba

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引用次数: 12

Abstract

High frequency electroacoustic biosensors require the use of microfluidic systems to confine the liquid under test on the sensor surface. Owing to frequent conductive character of biochemical solutions, the contacting pads must be isolated from the active areas of the sensors by means of electrical extensions. At working frequencies in the GHz range, the parasitic effects of such extensions can worsen the overall electrical response of the resonators by dramatically reducing the quality factor at the resonant frequency. In this paper, we study the effects of electrical extensions in AlN-based solidly mounted resonators operating in the shear mode at 1.3 GHz. The design of these extensions as a stretch of coplanar waveguide allows us minimizing the parasitic effects and matching the impedance between the resonator and the external circuitry for excitation and readout. We present solutions to lead the contact pads 2 mm away from the active area without distortion of the resonator response. Resonators with electrical extensions of 1.5 mm and quality factors of more than 150 are obtained.

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液体生物传感器中AlN-BAW谐振器电扩展的影响

高频电声生物传感器需要使用微流体系统将被测液体限制在传感器表面。由于生化溶液的频繁导电特性，接触垫必须通过电气扩展与传感器的有源区域隔离。在GHz工作频率范围内，这种扩展的寄生效应会通过显著降低谐振频率处的质量因子而使谐振器的整体电响应恶化。在本文中，我们研究了在1.3 GHz剪切模式下工作的铝基固体谐振器中的电扩展效应。将这些扩展设计为共面波导的延伸，使我们能够最大限度地减少寄生效应，并匹配谐振器与外部电路之间的阻抗，以实现激励和读出。我们提出的解决方案，使接触垫2毫米远离有源区域，而不失真谐振器的响应。谐振器的电延伸为1.5 mm，质量因数大于150。

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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2014 European Frequency and Time Forum (EFTF)

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