Quantifying magnetic anisotropy dispersion: Theoretical and experimental study of the magnetic properties of anisotropic FeCuNbSiB ferromagnetic films

TL;DR

This paper combines a modified Stoner-Wohlfarth model with experimental data to quantify magnetic anisotropy dispersion in amorphous FeCuNbSiB ferromagnetic films, providing a validated approach for analyzing anisotropic magnetic properties.

Contribution

It introduces a novel procedure to calculate magnetic properties from experimental magnetization data using a modified SW model with anisotropy dispersion, validated on amorphous ferromagnetic films.

Findings

Excellent agreement between theoretical calculations and experimental magnetization curves.

The approach effectively quantifies magnetic anisotropy dispersion.

The model accurately describes the magnetic behavior of anisotropic ferromagnetic films.

Abstract

The Stoner-Wohlfarth model is a traditional and efficient tool to calculate magnetization curves and it can provides further insights on the fundamental physics associated to the magnetic properties and magnetization dynamics. Here, we perform a theoretical and experimental investigation of the quasi-static magnetic properties of anisotropic systems. We consider a theoretical approach which corresponds to a modified version of the Stoner-Wohlfarth model to describe anisotropic systems and a distribution function to express the magnetic anistropy dispersion. We propose a procedure to calculate the magnetic properties for the anisotropic case of the SW model from experimental results of the quadrature of magnetization curves, thus quantifying the magnetic anisotropy dispersion. To test the robustness of the approach, we apply the theoretical model to describe the quasi-static magnetic properties of amorphous FeCuNbSiB ferromagnetic films. We perform calculations and directly compare theoretical results with longitudinal and transverse magnetization curves measured for the films. Thus, our results provide experimental evidence to confirm the validity of the theoretical approach to describe the magnetic properties of anisotropic amorphous ferromagnetic films, revealed by the excellent agreement between numerical calculation and experimental results.