Surface acoustic wave driven ferromagnetic resonance in (Ga,Mn)(As,P) epilayers

TL;DR

This study demonstrates the use of surface acoustic waves to induce and detect ferromagnetic resonance in (Ga,Mn)(As,P) epilayers, revealing strain-sensitive magnetic properties and magneto-strictive coupling effects.

Contribution

It provides a detailed analytical model of magneto-strictive coupling in dilute magnetic semiconductors under surface acoustic wave excitation.

Findings

Resonant behavior observed near calculated precession frequency

Resonance detected from 5K to 85K below Curie temperature

Velocity variations resonate at lower fields than attenuation

Abstract

Interdigitated transducers were used to generate and detect surface acoustic waves on a thin layer of (Ga,Mn)(As,P). The out-of-plane uniaxial magnetic anisotropy of this dilute magnetic semiconductor is very sensitive to the strain of the layer, making it an ideal test material for the dynamic control of magnetization via magneto-striction. The time-domain measurement of the amplitude and phase of the transmitted SAW during magnetic field sweeps indicated a clear resonant behavior at a field close to the one calculated to give a precession frequency equal to the SAW frequency. A resonance was observed from 5K to 85K, just below the Curie temperature of the layer. A full analytical treatment of the coupled magnetization/acoustic dynamics showed that the magneto-strictive coupling modifies the elastic constants of the material and accordingly the wave-vector solution to the elastic wave equation. The shape and position of the resonance were well reproduced by the calculations, in particular the fact that velocity (phase) variations resonated at lower fields than the acoustic attenuation variations.