矫顽力
材料科学
磁铁
微观结构
各向异性
凝聚态物理
晶间腐蚀
晶界
消磁场
热的
扩散
复合材料
核磁共振
冶金
领域(数学)
磁场
扩散过程
磁各向异性
微磁学
晶界扩散系数
作者
Xin Tang,Z.H. Kautsar,H. Sepehri-Amin,T. Kajiwara,Hironori Miyawaki,T. Ohkubo,K. Hono
标识
DOI:10.1016/j.scriptamat.2026.117265
摘要
We demonstrate that a high coercivity of 2.8 T can be achieved in a 5-mm-thick anisotropic Nd-Fe-B magnet by applying a Pr–Cu grain boundary diffusion process to a hot-deformed Nd-Fe-B-based magnet. Microstructural analysis reveals two key changes; the formation of an Fe-lean intergranular phase, which weakens magnetic exchange coupling, and the development of a Pr-rich shell around the matrix grains, which enhances the local anisotropy field after the diffusion process. These modifications shift the angular dependence of coercivity from the Kondorsky type to the Stoner–Wohlfarth type, and persist even at elevated temperatures. This explains the observed high coercivity and its improved thermal stability. Benchmarking the performance against 8–9 wt.% Dy-containing sintered magnets confirms that these Dy-free magnets exhibit comparable high-temperature performance due to improved thermal stability. Our findings highlight that ultrafine-grained, Dy-free, hot-deformed magnets are a promising alternative to commercial Dy-containing magnets for high-performance applications.
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