Litcius/Paper detail

Tuning the Performance of Acoustically Actuated Magnetoelectric Antenna via Magnetic and Mechanical Stimuli

Yang Shi, Jin Xu, Yongkun Wang, Junjie Ye

2023IEEE Transactions on Antennas and Propagation34 citationsDOI

Abstract

Magnetoelectric (ME) antenna operates at the acoustic wave resonance rather than electromagnetic (EM) wave resonance, thus it shows significant superiority for developing compact antennas and antenna arrays. The simulation of an ME antenna involves the nonlinear coupling of electrostatics, solid mechanics, and magnetic physics, making it difficult to model such devices. This article proposes a fully multifield coupled model for the ME antenna, in which the nonlinear magnetostrictive model is taken into account. The nonlinear magnetization is solved and then ac and dc simulations are performed by coupling different physics. The effects of magnetic bias and pre-stress on the converse ME (CME) coupling and near-field radiation are discussed for the first time, to regulate the performance of the ME antenna with fixed dimensions. The results indicate that the magnetic bias and pre-stress can change the resonance frequency, CME coefficient, and near-field radiation of the ME antenna. Particularly, it should be noted that pre-stress has the opposite effect in the low and high regions of the bias field. The near-field radiation is significantly enhanced by applying a proper magnetic bias or pre-stress. This simulation may facilitate the understanding of nonlinear CME behavior and provide a basis for designing nonlinear active and tunable ME antennae.

Topics & Concepts

Antenna (radio)Nonlinear systemPhysicsAcousticsCoupling (piping)Magnetic fieldMagnetostrictionStress (linguistics)MagnetizationLoop antennaRadiation patternComputational physicsCondensed matter physicsOpticsMaterials scienceAntenna factorComputer scienceTelecommunicationsPhilosophyLinguisticsMetallurgyQuantum mechanicsAcoustic Wave Resonator TechnologiesNumerical methods in engineeringMultiferroics and related materials