Influence of grain morphology and orientation on saturation magnetostriction of polycrystalline Terfenol-D

TL;DR

This study uses computational modeling to show that crystal orientation significantly influences saturation magnetostriction in polycrystalline Terfenol-D, emphasizing the importance of controlling grain orientation during synthesis.

Contribution

It demonstrates through finite element analysis that crystal orientation impacts magnetostriction more than grain morphology in Terfenol-D.

Findings

Crystal orientation has a greater effect on saturation magnetostriction than grain shape.

Highly oriented grains are crucial for maximizing magnetostriction.

Dispersion in grain orientation reduces magnetostriction significantly.

Abstract

In this work we computationally study the effect of microstructure on saturation magnetostriction of Terfenol-D (Tb$_{0.27}$Dy$_{0.73}$Fe$_{2}$) by means of Finite Element Method. The model is based on the equilibrium magnetoelastic strain tensor at magnetic saturation, and shows that the crystal orientation might play a more significant role on saturation magnetostriction than the morphology of the grains. We also calculate the dependence of saturation magnetostriction on the dispersion angle of the distribution of grains in the oriented growth crystal directions $<011>$ and $<111>$, finding that not highly oriented grain distributions reduce saturation magnetostriction significantly. This result evinces the importance of high-quality control of grain orientation in the synthesis of grain-aligned polycrystalline Terfenol-D, and provides a quantitative estimation for the range of acceptable values for the dispersion angle of the distribution of the oriented grains.