AlScN-on-SiC Diaphragm Multimode Micromechanical Resonators for High-Temperature Sensing Applications

IMAPS symposia and conferences Pub Date : 2023-11-07 DOI:10.4071/001c.89964

Wen Sui, Haoran Wang, Jaesung Lee, Afzaal Qamar, Mina Rais-Zadeh, Philip X.-L. Feng

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Abstract

We demonstrate circular diaphragm multimode micromechanical resonators made of heterostructure thin film of aluminum scandium nitride (AlScN) sputtered on cubic silicon carbide (3C-SiC). We systematically characterize the multimode resonators from room temperature up to 600ºC high-temperature environment. We observe clear consistency in resonances measured in heating up and cooling down processes, validating that the AlScN/SiC diaphragm resonators can operate robustly in high-temperature environment up to 600°C without observable degradation. Raman spectroscopy results indicate that the turning points of the peak positions of the longitudinal optical (LO) phonon modes of both 3C-SiC and AlScN occur in almost the same temperature region where the turning point of temperature coefficient of resonance frequency (TCf) is observed. We calibrate the device temperature by measuring Raman peak of the silicon (Si) substrate of the chip, yielding a crystal lattice temperature of 410ºC at the heater setting temperature being 600ºC. The heating efficiency can be improved by clamping the chip using a clip or jig with lower thermal conductivity.

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用于高温传感应用的AlScN-on-SiC膜片多模微机械谐振器

在立方碳化硅(3C-SiC)上溅射制备了一种由氮化铝钪(AlScN)异质薄膜制成的圆膜片多模微机械谐振器。我们在室温到600℃的高温环境下对多模谐振器进行了系统的表征。我们观察到在加热和冷却过程中测量的共振具有明显的一致性，验证了AlScN/SiC隔膜谐振器可以在高达600°C的高温环境中稳定运行，而不会出现明显的退化。拉曼光谱结果表明，3C-SiC和AlScN的纵向光学声子模式的峰位拐点出现在谐振频率温度系数(TCf)拐点的几乎相同的温度区域。我们通过测量芯片硅(Si)衬底的拉曼峰来校准器件温度，在加热器设置温度为600℃时，晶格温度为410℃。通过使用导热系数较低的夹子或夹具夹紧芯片，可以提高加热效率。

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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IMAPS symposia and conferences

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