Hybrid Magnetoacoustic Metamaterials for Ultrasound Control

TL;DR

This paper introduces hybrid magnetoacoustic metamaterials that enable magnetic control of ultrasound waves through magnetoelastic coupling, leading to novel effects like magnetically induced transparency and potential applications in wave computing.

Contribution

It presents a new class of metamaterials with magnetic control of acoustic waves via magnetoelastic coupling, combining Fano resonance and Bragg scattering effects.

Findings

Demonstrates magnetically induced transparency in acoustic reflection

Shows magnetoelastic coupling can overcome magnetic damping

Identifies potential for wave computing applications

Abstract

We propose a class of metamaterials in which propagation of acoustic waves is controlled magnetically through magnetoelastic coupling. The metamaterials are formed by a periodic array of thin magnetic layers ('resonators') embedded in a non-magnetic matrix. Acoustic waves carrying energy through the structure hybridize with the magnetic modes of the resonators ('Fano resonance'). This leads to a rich set of effects, enhanced by Bragg scattering and being most pronounced when the magnetic resonance frequency is close to or lies within acoustic band gaps. The acoustic reflection from the structure exhibits magnetically induced transparency and Borrmann effect. Our analysis shows that the combined effect of the Bragg scattering and Fano resonance may overcome the magnetic damping ubiquitous in realistic systems. This paves a route towards application of such structures in wave computing and signal processing