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Structure and Magnetic Properties of Thermodynamically Predicted Rapidly Quenched Fe 85-x Cu x B 15 Alloys.

Lukasz HawelekTymon WarskiAdrian RadonAdam PilsniakWojciech MaziarzMaciej SzlezyngerMariola Kadziolka-GawelAleksandra Kolano-Burian
Published in: Materials (Basel, Switzerland) (2021)
In this work, based on the thermodynamic prediction, the comprehensive studies of the influence of Cu for Fe substitution on the crystal structure and magnetic properties of the rapidly quenched Fe 85 B 15 alloy in the ribbon form are performed. Using thermodynamic calculations, the parabolic shape dependence of the Δ G amoprh with a minimum value at 0.6% of Cu was predicted. The Δ G amoprh from the Cu content dependence shape is also asymmetric, and, for Cu = 0% and Cu = 1.5%, the same Δ G amoprh value is observed. The heat treatment optimization process of all alloys showed that the least lossy (with a minimum value of core power losses) is the nanocomposite state of nanocrystals immersed in an amorphous matrix obtained by annealing in the temperature range of 300-330 °C for 20 min. The minimum value of core power losses P 10/50 (core power losses at 1T@50Hz) of optimally annealed Fe 85-x Cu x B 15 x = 0,0.6,1.2% alloys come from completely different crystallization states of nanocomposite materials, but it strongly correlates with Cu content and, thus, a number of nucleation sites. The TEM observations showed that, for the Cu-free alloy, the least lossy crystal structure is related to 2-3 nm short-ordered clusters; for the Cu = 0.6% alloy, only the limited value of several α-Fe nanograins are found, while for the Cu-rich alloy with Cu = 1.2%, the average diameter of nanograins is about 26 nm, and they are randomly distributed in the amorphous matrix. The only high number of nucleation sites in the Cu = 1.2% alloy allows for a sufficient level of grains' coarsening of the α-Fe phase that strongly enhances the ferromagnetic exchange between the α-Fe nanocrystals, which is clearly seen with the increasing value of saturation induction up to 1.7T. The air-annealing process tested on studied alloys for optimal annealing conditions proves the possibility of its use for this type of material.
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