Biaxial film bulk acoustic resonator magnetic sensor based on the Fe 80 Ga 20 anisotropic ΔE effect

With the increasing application of personal navigation systems in consumer electronics, the demand for multi-axis magnetic sensors based on MEMS is growing. We report a biaxial MEMS DC magnetic sensor consisting of an Mo/AlN/Fe 80 Ga 20 film bulk acoustic resonator, with anisotropy Δ E effect-based...

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Bibliographic Details
Published in:Journal of physics. D, Applied physics Applied physics, 2022-03, Vol.55 (13), p.135002
Main Authors: Yun, Xiaofan, Lin, Wenkui, Hu, Rui, Wang, Xiaoyi, Zeng, Zhongming, Zhang, Xinping, Zhang, Baoshun
Format: Article
Language:English
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Summary:With the increasing application of personal navigation systems in consumer electronics, the demand for multi-axis magnetic sensors based on MEMS is growing. We report a biaxial MEMS DC magnetic sensor consisting of an Mo/AlN/Fe 80 Ga 20 film bulk acoustic resonator, with anisotropy Δ E effect-based sensing principle. Different from the previously reported 1D magnetic sensor based on the Δ E effect, the anisotropic Δ E effect was used to realize in-plane and out-of-plane 2D magnetic field responses on a discrete sensor, and the sensor had two readout methods: resonant frequency f and return loss S11. The magnetic sensor realized the resonant frequency f shifted by 1.03 MHz and 0.2 MHz in the 567 Oe in-plane magnetic field and 720 Oe out-of-plane magnetic field, respectively, and the S11 changes by −30.2 dB and −0.92 dB. As the applied magnetic field increases, the −3 dB bandwidth quality factor Q 3dB of the S11 curve gradually increases, and its maximum values in the in-plane and out-of-plane magnetic fields are 77 143 and 1828, respectively, which reduces the detection limit of the magnetic sensor. The resonant magnetic sensor has stable high linear temperature and frequency drift characteristics, and its temperature frequency coefficient is −48.7 ppm °C −1 .
ISSN:0022-3727
1361-6463
DOI:10.1088/1361-6463/ac4452