# Theoretical Study on Anisotropic Magnetoresistance Effects of I//[100],   I//[110], and I//[001] for Ferromagnets with A Crystal Field of Tetragonal   Symmetry

**Authors:** Satoshi Kokado, Masakiyo Tsunoda

arXiv: 1903.01317 · 2019-03-05

## TL;DR

This paper provides an analytical theoretical framework for understanding anisotropic magnetoresistance (AMR) ratios in tetragonally distorted ferromagnets, revealing the origin of angular dependencies and relations among coefficients, with implications for Ni.

## Contribution

It derives explicit formulas for AMR ratios considering tetragonal symmetry and explains experimental observations, including a specific relation among coefficients for different current directions.

## Key findings

- Derived analytic expressions for AMR ratios with angular dependence.
- Identified the relation C_4^{[100]} = -C_4^{[110]} for Ni.
- Qualitatively explained experimental AMR coefficients at 293 K for Ni.

## Abstract

Using the electron scattering theory, we obtain analytic expressions for anisotropic magnetoresistance (AMR) ratios for ferromagnets with a crystal field of tetragonal symmetry. Here, a tetragonal distortion exists in the [001] direction, the magnetization ${\mbox{\boldmath $M$}}$ lies in the (001) plane, and the current ${\mbox{\boldmath $I$}}$ flows in the [100], [010], or [001] direction. When the ${\mbox{\boldmath $I$}}$ direction is denoted by $i$, we obtain the AMR ratio as ${\rm AMR}^i (\phi_i)= C_0^i + C_2^i \cos 2\phi_i + C_4^i \cos 4 \phi_i \ldots = \sum_{j=0,2,4,\ldots} C_j^i \cos j\phi_i$, with $i=[100]$, $[110]$, and $[001]$, $\phi_{[100]} = \phi_{[001]}=\phi$, and $\phi_{[110]}=\phi'$. The quantity $\phi$ ($\phi'$) is the relative angle between ${\mbox{\boldmath $M$}}$ and the $[100]$ ($[110]$) direction, and $C_j^i$ is a coefficient composed of a spin--orbit coupling constant, an exchange field, the crystal field, and resistivities. We elucidate the origin of $C_j^i \cos j\phi_i$ and the features of $C_j^i$. In addition, we obtain the relation $C_4^{[100]} = -C_4^{[110]}$, which was experimentally observed for Ni, under a certain condition. We also qualitatively explain the experimental results of $C_2^{[100]}$, $C_4^{[100]}$, $C_2^{[110]}$, and $C_4^{[110]}$ at 293 K for Ni.

## Full text

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## Figures

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## References

51 references — full list in the complete paper: https://tomesphere.com/paper/1903.01317/full.md

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Source: https://tomesphere.com/paper/1903.01317