镝
材料科学
矫顽力
磁铁
扩散
相(物质)
晶界
晶界扩散系数
凝聚态物理
有效扩散系数
核磁共振
冶金
相界
坡莫合金
电子工程
作者
Qing Feng,Dong Huang,Li-zhong Zhao,Jinkui Fan,Liang Jin,Yu Pan,Yuan Hong,Xiaolian Liu,Anjian Pan,Haoyang Jia,Shuai Liu,Zhongwu Liu,Xuefeng Zhang
标识
DOI:10.1002/adfm.202525964
摘要
Abstract High‐cerium Nd–Ce–Fe–B magnets suffer from severe coercivity degradation, primarily stemming from the poor intrinsic magnetic properties of the Ce 2 Fe 14 B phase. Although dysprosium (Dy) grain boundary diffusion (GBD) has emerged as a critical strategy for coercivity enhancement, its effectiveness is significantly hindered by the presence of refractory rare‐earth REFe 2 phases. To address this bottleneck, the Dy x Pr 80−x Al 10 Ga 10 (x = 0, 20, 40, 80 at.%) diffusion sources are designed, where Pr (praseodymium), Al, and Ga synergistically transform REFe 2 into low‐melting‐point PrGa‐rich phases, thereby constructing efficient liquid‐phase diffusion pathways for Dy. First‐principles calculations indicate that the positive formation energy of Pr doped CeFe 2 phase destabilizes the (Pr, Ce)Fe 2 phase, facilitating the liquid‐phase transformation below the GBD temperature (930 °C). Correlative microstructural analyses demonstrate that these liquid‐phase pathways enable a higher Dy diffusion coefficient and more uniform core–shell structures, effectively suppressing reversed magnetic domains expansion and enhancing coercivity. For magnets with 26, 39, 45, and 61 wt.% Ce‐substitution, the robust coercivity increments of 7.0, 5.4, 5.5, and 3.9 kOe are achieved, respectively, using only ≈0.39 wt.% Dy. This strategy overcomes the long‐standing barrier of REFe 2 phases in GBD and provides a scalable route for producing Ce‐rich Nd–Ce–Fe–B magnets with high performance.
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