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Bandwidth-enhanced magnetoelectric antenna based on composite bulk acoustic resonators

Xiaofan Yun, Wenkui Lin, Rui Hu, Yizhang Liu, Xiaoyi Wang, Guohao Yu, Zhongming Zeng, Xinping Zhang, Baoshun Zhang

2022Applied Physics Letters41 citationsDOI

Abstract

A bulk acoustic wave (BAW) driven magnetoelectric (ME) antenna has narrow operating bandwidth due to its high Q factor, and an effective mechanism for bandwidth enhancement is yet to be explored. This article presents a bandwidth-enhanced magnetoelectric (BWE-ME) antenna made of a Mo/AlN/FeGa sandwich stack, which is composed of three different resonant regions. These resonant regions in the discrete device can be equated as a parallel connection of dual high-overtone bulk acoustic resonators (HBARs) and single film bulk acoustic resonators (FBARs) with tiny frequency shift among the three resonators resulting in bandwidth broadening of the BWE-ME antenna. The resonant mode and return loss curves (S11) are simulated in a two-dimensional finite element method and fitted with the Mason equivalent circuit model. The frequency domain analysis shows that the magnetic flux density bandwidth generated by the multi-resonant mode interaction is 18 MHz, which matches the bandwidth of the measured reference gain S21 curve of the BWE-ME antenna, and the far-field radiated power characterization also shows the corresponding effective bandwidth distributed. The fabricated microelectromechanical systems antenna achieves a fractional bandwidth of 2.7% while maintaining the advantage of small size (0.49 mm2). Discrete composite BAW resonators that effectively combine the multi-resonant regions of HBARs and FBARs have the potential to realize compact and broadband BAW-ME antennas in the future.

Topics & Concepts

ResonatorBandwidth (computing)Materials scienceBroadbandOptoelectronicsAcousticsPhysicsComputer scienceOpticsTelecommunicationsAcoustic Wave Resonator TechnologiesFerroelectric and Piezoelectric MaterialsMultiferroics and related materials