A very low frequency (VLF) antenna based on clamped bending-mode structure magnetoelectric laminates
Lizhi Hu, Qianshi Zhang, Hanzhou Wu, Haoran You, Jie Jiao, Haosu Luo, Yaojin Wang, Chungang Duan, Anran Gao
Abstract
Abstract As the development of wireless communication devices tends to be highly integrated, the miniaturization of very low frequency (VLF) antenna units has always been an unresolved issue. Here, a novel VLF mechanical communication antenna using magnetoelectric (ME) laminates with bending-mode structure is realized. ME laminates combines magnetostrictive Metglas amorphous ribbons and piezoelectric 0.7Pb(Mg 1/3 Nb 2/3 )O 3 –0.3PbTiO 3 single crystal plates. From the simulation, we confirmed that the ME laminates can reduce the resonance peak from 18 kHz to 7.5 kHz by bending-mode structure. Experiment results show the resonance frequency can be farther reduced to 6.3 kHz by clamping one end of the ME antenna. The ME laminate exhibits a giant converse ME coefficient of 6 Oe cm V −1 at 6.3 kHz. The magnetic flux density generated by the ME antenna has been tested along with distance ranging from 0 to 60 cm and it is estimated that a 1 fT flux could be detected around 100 m with an excitation power of 10 mW.