Improvement of soft magnetic properties of a Nanoperm-type Fe-Hf-B nanocrystalline alloy upon surface crystallization inhibition by Cu addition

Nanoperm-type alloy ribbons suffer from surface crystallization during melt spinning, which degrades their magnetic properties after annealing and limits their commercial application. Here, we investigate the effects of Cu addition on the structure and magnetic properties of a surface-textured Fe87-xHf5B8Cux alloy. Adding Cu (1 <= x <= 2) removes the surface coarse grains in the free surface of the melt-spun precursor, while induces the precipitation of large amounts of the alpha-Fe nanoparticles with similar to 3 nm in size, which contributes a homogeneous ultrafine structure and improved magnetic softness after annealing. The grain size, coercivity, saturation magnetic flux density, and effective permeability at 1 kHz of the Fe86Hf5B8Cu1 nanocrystalline alloy are 13.3 nm, 6.6 A/m, 1.68 T, and 23000, respectively, whereas these are 16.0 nm, 16.8 A/m, 1.70 T, and 15000, respectively, for the Fe87Hf5B8 alloy. The Cu-improved effect is mainly attributed that Cu induces heterogeneous nucleation of the alpha-Fe phase to strengthen the competitive growth among grains.

Automated summary

This study investigates the effects of Cu addition on the structure and magnetic properties of Fe-based alloys. It is found that Cu can improve the alloy's structure and magnetic properties, thus enhancing its commercial application value.