Magnetocrystalline anisotropy of FeNi and FeCo along the Bain path

TL;DR

This study uses ab initio and analytical models to explore how the magnetocrystalline anisotropy of FeCo and FeNi varies along the Bain transformation path, revealing element-dependent behaviors relevant for permanent magnet design.

Contribution

It provides a combined theoretical and analytical analysis of MCA variation in FeCo and FeNi during Bain transformation, highlighting element-specific effects and underlying physics.

Findings

MCA varies differently for FeCo and FeNi along the Bain path.

Structural phase and electron occupation influence MCA trends.

Element pairing with Fe affects magnetic anisotropy behavior.

Abstract

We theoretically investigate magnetic anisotropy in materials with non-critical elements to determine which symmetry conditions and atomic shell filling favor enhanced magnetic anisotropy. We study the magnetocrystalline anisotropies (MCA) of the equiatomic ferrous compounds FeCo and FeNi using ab initio calculations and analytical approaches via the diatomic pair model. We find that when these materials undergo a Bain transformation, that is, the variation of the a and c lattice parameters adjust to interpolate between the B2 and L10 structural phases while keeping the unit cell volume constant, the MCA versus r = c/a ratio varies differently for FeCo and FeNi despite Co and Ni differing only by one valence electron. To uncover the physics governing these trends, we use a diatomic pair model to perform a theoretical analysis of the ab initio results. We find that the MCA variation along the Bain path is correlated with the structural phase of the material as well as the occupation of (l, m)-resolved states for each equiatomic ferrous compound. Accordingly, the MCA was found to differ depending on the element paired with Fe to form the Fe-X compound (X = Co, Ni). Our work could help guide the scientific community in solving the supply crisis of hard/strong permanent magnets that are crucial for various technological applications such as those depending on motors and generators for energy conversion and clean energy applications.