Symmetry of the Magnetoelastic Interaction of Rayleigh and Shear Horizontal Magnetoacoustic Waves in Nickel Thin Films on LiTaO$_3$

TL;DR

This study investigates how Rayleigh and shear horizontal surface acoustic waves interact with spin waves in nickel thin films on LiTaO$_3$, revealing symmetry differences that enable versatile spin wave excitation and strain characterization.

Contribution

It provides a theoretical and experimental analysis of the symmetry differences in magnetoelastic interactions for different SAW modes on a piezoelectric substrate.

Findings

Symmetries of magnetoelastic response differ for Rayleigh and shear horizontal SAWs.

Both SAW modes can excite spin waves regardless of magnetization orientation.

The results enable characterization of surface strain components in unknown acoustic modes.

Abstract

We study the interaction of Rayleigh and shear horizontal surface acoustic waves (SAWs) with spin waves in thin Ni films on a piezoelectric LiTaO$_3$ substrate, which supports both SAW modes simultaneously. Because Rayleigh and shear horizontal modes induce different strain components in the Ni thin films, the symmetries of the magnetoelastic driving fields, of the magnetoelastic response, and of the transmission nonreciprocity differ for both SAW modes. Our experimental findings are well explained by a theoretical model based on a modified Landau--Lifshitz--Gilbert approach. We show that the symmetries of the magnetoelastic response driven by Rayleigh- and shear horizontal SAWs complement each other, which makes it possible to excite spin waves for any relative orientation of magnetization and SAW propagation direction and, moreover, can be utilized to characterize surface strain components of unknown acoustic wave modes.