Current Control of Magnetic Anisotropy via Stress in a Ferromagnetic Metal Waveguide

TL;DR

This paper demonstrates that in-plane charge current can modulate magnetic anisotropy in a ferromagnetic metal waveguide through stress, affecting spin precession resonance, with implications for spintronic device control.

Contribution

It reveals that stress-induced modifications of magnetic anisotropy via current are effective for controlling spin dynamics in ferromagnetic heterostructures.

Findings

Current controls spin precession resonance via magnetic anisotropy modification.

Joule heating-induced stress significantly influences magnetic anisotropy.

Experimental and simulation results confirm stress as a key factor.

Abstract

We demonstrate that in-plane charge current can effectively control the spin precession resonance in an Al2O3/CoFeB/Ta heterostructure. Brillouin Light Scattering (BLS) was used to detect the ferromagnetic resonance field under microwave excitation of spin waves at fixed frequencies. The current control of spin precession resonance originates from modification of the in-plane uniaxial magnetic anisotropy field H_k, which changes symmetrically with respect to the current direction. Numerical simulation suggests that the anisotropic stress introduced by Joule heating plays an important role in controlling H_k. These results provide new insights into current manipulation of magnetic properties and have broad implications for spintronic devices.