Simulation of Magnetization Switching in Biaxial Single-Domain Ferromagnetic Particles

TL;DR

This paper simulates the magnetization switching in biaxial single-domain ferromagnetic particles using a 4-state clock model, analyzing the dynamics, switching times, and effects of asymmetry and field orientation.

Contribution

It extends static mappings to dynamic analysis, providing new insights into switching mechanisms and field dependencies in biaxial ferromagnetic particles.

Findings

Switching times are analyzed using droplet theory.

Asymmetry introduces multiple switching channels with different speeds.

Maximum switching field depends on system size and asymmetry.

Abstract

The magnetization switching dynamics of biaxial single-domain homogeneous ferromagnetic particles, in which the two easy axes are perpendicular to each other, is simulated using a 4-state clock model. A zero-field mapping of the statics between the symmetric 4-state clock model and two decoupled Ising models is extended to non-zero field statics and to the dynamics. This significantly simplifies the analysis of the simulation results. We measure the magnetization switching time of the model and analyze the results using droplet theory. The switching dynamics in the asymmetric model is more complicated. If the easy axis is perpendicular to the stable magnetization direction, the system can switch its magnetization via two different channels, one very fast and the other very slow. A maximum value for the switching field as a function of system size is obtained. The asymmetry affects the switching fields differently, depending on whether the switching involves one single droplet or many droplets of spins in the stable magnetization configuration. The angular dependence of the switching field in symmetric and asymmetric models is also studied.