Standing spin wave excitation in Bi:YIG films via temperature induced anisotropy changes and magnetoacoustic coupling

TL;DR

This study investigates how temperature-induced anisotropy changes and magnetoacoustic coupling excite standing spin waves in Bi:YIG films, combining simulations and experiments to disentangle their effects.

Contribution

It provides a detailed analysis of the separate roles of magnetic anisotropy and magnetoelastic coupling in spin wave excitation in Bi:YIG films.

Findings

Both mechanisms drive the fundamental mode with opposite phase.

Both mechanisms are substantially active in exciting higher order modes.

Experimental and simulated results show good agreement.

Abstract

Based on micromagnetic simulations and experimental observations of the magnetization and lattice dynamics following the direct optical excitation of the magnetic insulator Bi:YIG or indirect excitation via an optically opaque Pt/Cu double layer, we disentangle the dynamical effects of magnetic anisotropy and magnetoelastic coupling. The strain and temperature of the lattice are quantified via modeling ultrafast x-ray diffraction data. Measurements of the time-resolved magneto-optical Kerr effect agree well with the magnetization dynamics simulated according to the excitation via two mechanisms: The magneto-acoustic coupling to the experimentally verified strain dynamics and the ultrafast temperature-induced transient change in the magnetic anisotropy. The numerical modeling proves that for direct excitation both mechanisms drive the fundamental mode with opposite phase. The relative ratio of standing spin-wave amplitudes of higher order modes indicates that both mechanisms are substantially active.