Influence of microstructure and anisotropy on the high-frequency soft magnetic properties of nanocrystalline FeSiBNbCuP alloys

•The Fe77.8Si11.6B7Nb2Cu0.6P1 alloys have high Bs of 1.5 T, high µ of 18,400 and low Ps of 209 kW/m3 at 100 kHz.•The  and Ku ratio of ∼ 1 optimized the high-frequency magnetic performance.•The increased anisotropy resulted from texture and high temperature deteriorated soft magnetic properties.•Opti...

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Bibliographic Details
Published in:Journal of magnetism and magnetic materials 2022-10, Vol.560, p.169639, Article 169639
Main Authors: Sun, Yu, Li, Jiawei, He, Aina, Xie, Lei, Dong, Yaqiang, Liu, Yanxin, Zhang, Ruiheng, Zhang, Kewei
Format: Article
Language:English
Subjects:
Averaged magnetocrystalline anisotropy
Field-induced anisotropy
High-frequency soft magnetic properties
Orientation
Transverse magnetic field annealing
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Summary:•The Fe77.8Si11.6B7Nb2Cu0.6P1 alloys have high Bs of 1.5 T, high µ of 18,400 and low Ps of 209 kW/m3 at 100 kHz.•The  and Ku ratio of ∼ 1 optimized the high-frequency magnetic performance.•The increased anisotropy resulted from texture and high temperature deteriorated soft magnetic properties.•Optimizing the  and Ku to small and similar values is beneficial for obtaining excellent high-frequency soft magnetic properties. Several electronic devices require alloys with excellent soft magnetic properties, for further advancement. The effect of anisotropy and microstructure, particularly concerning grain orientation, on the high-frequency (100 kHz) magnetic properties of nanocrystalline Fe77.8Si11.6B7Nb2Cu0.6P1 toroidal cores has been studied. The field-induced anisotropy (Ku) of the cores was induced by applying transverse field annealing (TFA) with a magnetic field of 0.08 T at annealing temperatures ranging from 320 °C to 540 °C after having been optimally nano-crystallized by normal annealing (NA). The high-frequency magnetic properties were found to be affected by the competition between Ku and the averaged magnetocrystalline anisotropy (). The optimal soft magnetic characteristics, i.e., high saturation magnetization of 1.5 T, high permeability of 18,400 (100 kHz, 0.06 A/m), low coercivity of 1.7 A/m, and low core loss of 209 kW/m3 (100 kHz, 0.2 T), were obtained when the /Ku ratio was approximately 1. With further increase in the TFA temperature, the texture of the α-Fe(Si) grains in the 〈100〉 direction became more prominent, leading to an increase in  and consequently deteriorating the soft magnetic properties. A bi-anisotropy and microstructure interaction model was established based on the experimental results, it can provide guidance for optimizing the high-frequency magnetic performance of Fe-based nanocrystalline alloys.
ISSN:0304-8853
DOI:10.1016/j.jmmm.2022.169639