Crystallization behavior and soft magnetic properties of Fe-B-P-C-Cu ribbons with amorphous/α-Fe hierarchic structure

In this work, Fe83+x(B4P8C4)(16-x)Cu-1 (x = 0, 1, 1.5 and 2 at. %) alloy system with amorphous/alpha-Fe hierarchic structures in as-cast state were artificially designed. The microstructure, crystallization kinetics, nanocrystalline structure, and magnetic properties of the alloys were systematically investigated. And the structural mechanism for the magnetic properties of these alloys was discussed. It is shown that the structure is evolved from full amorphous to amorphous/alpha-Fe dual-phase microstructure in the free surface side, and/or roller side layer with Fe content increasing. The formation of hierarchic structure decreases the activation energies of onset and peak crystallization of alpha-Fe phase, and increases the size of nanocrystalline grains, and subsequently is beneficial to improve the B-s of alloys. The H-c of alloys increases due to the formation of hierarchic structure, whereas this effect is gradually eliminated by the annealing process at the suitable crystallization annealing temperature (T-a). Typically, Fe85B3.5P7C3.5Cu1 nanocrystalline alloy exhibit the B-s of 1.86T and H-c of 5.7 A/m after annealing at 723 K. High Fe bearing alloys have lath domain structure with stronger orientation preference in as-cast state, and transformed into labyrinth packing with thinner spacing after structural relaxation annealing, demonstrating that hierarchic structure leads to the high magnetic anisotropy in the alloys.

Automated summary

By designing alloy systems with amorphous/α-Fe hierarchic structures, the magnetic properties of the alloys can be improved, including enhancing the saturation magnetization and coercivity. Further improvement in the magnetic properties of the alloys can be achieved through appropriate annealing processes.