The influence of ultra-rapid annealing on nanocrystallization and magnetic properties of Fe76-xNi10B14Cux alloys

Soft magnetic materials with a nanocrystalline structure are significant from an application and scientific point of view. This article presents the possibility of obtaining nanocrystalline Fe76-xNi10B14Cux alloy with magnetic properties modified by ultra-rapid annealing (URA). The work is focused on thermodynamic calculations to determine the alloy's optimal copper content and achieving soft magnetic properties of selected material by ultra-rapid annealing. The examined copper concentration was in the range from 0 to 2 at%. The optimal copper concentration was investigated based on the minimization of the Gibbs free energy of amorphization value. Accordingly, the Fe(75.3)Ni(10)B(14)Cu(0.7 )alloy was taken for further experimental analysis. The URA process was performed in a specially designed, home-made apparatus, in which the amorphous precursor in the ribbon shape was annealed between hot blocks at 773 K for the time in the range of 0.5-30 s. The ribbons were examined in detail by differential scanning calorimetry, X-ray diffraction, and Fe-57 Mossbauer spectroscopy. The nucleation mechanisms in the amorphous material upon crystallization have been studied. The dependence of the mean grain size and the content of the crystalline phase on annealing time was determined. The coercivity, H-c, and saturation magnetic polarization, J(s), measurements revealed changes in the alloy's magnetic behavior with increasing the annealing time. Optimal conditions of the URA process were determined in order to obtain soft magnetic Fe75.3Ni10B14Cu0.7nanocrystalline alloy. (C) 2022 Elsevier B.V. All rights reserved.

Automated summary

This article presents the possibility of modifying the magnetic properties of nanocrystalline Fe76-xNi10B14Cux alloy using ultra-rapid annealing (URA). The optimal copper content of the alloy was determined through thermodynamic calculations, and the soft magnetic properties were achieved through URA. Experimental analysis revealed that the alloy's magnetic behavior changes with increasing annealing time.