Improved Coercivity in Cu-Doped SmCo5 Nanocomposite Powders Obtained by Low Temperature Annealing

IF 2.9 2区材料科学 Q2 METALLURGY & METALLURGICAL ENGINEERING

Acta Metallurgica Sinica-English Letters Pub Date : 2025-02-21 DOI:10.1007/s40195-025-01827-z

Longfei Ma, Yingzhengsheng Huang, Wei Quan, Qiang Zheng, Juan Du

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Abstract

In this work, nanocrystalline SmCo₅–Cu nanocomposite powders were fabricated from the ball-milled amorphous matrix by crystallization annealing which is lower than the traditional sintering temperature ~ 1000 °C for bulk SmCo₅ bulk magnets. Annealed Cu-doped SmCo₅ powders have a higher coercivity compared to that of Cu-free SmCo₅ one due to the combined effects of refinement effect of grain size and the pinning effect induced by Cu doping. The peak of coercivity (H_c) is located at 600 °C for annealed Cu-doped SmCo₅, which is ascribed to the improved pinning field. The pinning effect became reduced when the annealing was done at even higher temperatures. More importantly, the best comprehensive magnetic properties, including a maximum magnetic energy product (BH)_max of 12.2 MGOe together with a coercivity of 31.8 kOe and a remanence of 64.3 emu/g, could be achieved for SmCo₅-3 wt% Cu by low temperature annealing. These results demonstrate that isotropic Cu-doped SmCo₅ nanocrystalline powders are promising precursors for the fabrication of high-performance bulk magnets.

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低温退火提高cu掺杂SmCo5纳米复合粉末矫顽力

本研究以球磨非晶态基体为基础，采用结晶退火工艺制备了SmCo5 - cu纳米复合粉体，其烧结温度低于SmCo5块状磁体的传统烧结温度~ 1000℃。由于晶粒尺寸的细化效应和Cu掺杂引起的钉住效应的共同作用，退火后的掺杂Cu的SmCo5粉末矫顽力比未掺杂Cu的SmCo5粉末高。退火后的cu掺杂SmCo5矫顽力（Hc）峰值位于600℃，这是由于强化了钉钉场。在更高的退火温度下，钉住效应降低。更重要的是，SmCo5-3 wt% Cu经低温退火可获得最佳的综合磁性能，包括最大磁能积（BH）max为12.2 MGOe，矫顽力为31.8 kOe，剩余率为64.3 emu/g。这些结果表明，各向同性cu掺杂SmCo5纳米晶粉末是制造高性能体磁铁的有前途的前驱体。

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来源期刊

Acta Metallurgica Sinica-English Letters METALLURGY & METALLURGICAL ENGINEERING-

CiteScore

6.60

自引率

14.30%

发文量

122

审稿时长

2 months

期刊介绍： This international journal presents compact reports of significant, original and timely research reflecting progress in metallurgy, materials science and engineering, including materials physics, physical metallurgy, and process metallurgy.