The influence of antiphase boundary of the MnAl $Ï$-phase on the energy product
arXiv:1903.06518 · doi:10.1103/PhysRevMaterials.3.064412
Abstract
In this work we use a multiscale approach toward a realistic design of a permanent magnet based on MnAl $Ï$-phase and elucidate how the antiphase boundary defects present in this material affect the energy product. We show how the extrinsic properties of a microstructure depend on the intrinsic properties of a structure with defects by performing micromagnetic simulations. For an accurate estimation of the energy product of a realistic permanent magnet based on the MnAl $Ï$-phase with antiphase boundaries, we quantify for the first time the exchange interaction strength across the antiphase boundary defect with a simple approach derived from the first-principles calculations. These two types of calculations performed at different scales are linked via atomistic spin dynamic simulations performed at an intermediate scale.