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Mn-20at%Ga纳米复合磁性材料的制备和磁性能研究
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1.东北大学;2.东北大学冶金学院

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国家自然科学基金(项目号:51674083),国家级大学生创新创业训练计划资助项目(项目号:201910145258),中央高校基本科研业务专项资金(项目号:N182410001),高等学校学科创新引智计划项目2.0(项目号:BP0719037)


Fabrication and Magnetic Properties of Mn-20at%Ga Nanoscale Magnetic Materials
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1.Key Laboratory of Electromagnetic Processing of Materials Ministry of Education,Northeastern University;2.School of Metallurgy,Northeastern University

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    摘要:

    Mn-Ga合金具有高矫顽力和较高的磁晶各向异性,是一类具有较大发展前景的磁性材料。本文采用机械合金化方法开展Mn-20at%Ga纳米磁性复合材料的制备研究,高能球磨后合金在300 ~ 415℃温度区间、2 ~ 8小时保温时间进行退火。重点研究了磁性相种类、纳米晶尺寸和磁性能随退火条件的变化规律。研究发现,退火后Mn-20at%Ga磁性材料中的主要磁性相为纳米级尺寸的Mn3Ga相和Mn0.85Ga0.15相,另含有少量氧化导致的MnO2相。适当的提高退火温度和退火时间,可促进剩磁、矫顽力与磁能积的提高。在385℃时进行6小时的热处理,可获得最佳的磁性能:剩磁63.21 emu/cm3、矫顽力8.1 kOe、磁能积0.15 MGOe。通过适当的提高保温温度和保温时间,可使Mn0.85Ga0.15相的尺寸降低,并与矫顽力升高的趋势相一致。Mn0.85Ga0.15相晶粒尺寸的下降有利于提高合金的磁性能。

    Abstract:

    The Mn-Ga alloy displays high coercivity and a relatively large magnetic anisotropy. These characteristics suggest that it is a good potential magnetic material for the future. Herein, we prepared Mn-20at%Ga magnetic nanocomposites through mechanical alloying using high-energy ball milling. After ball milling for a total time of 3.5 h, the powder was placed in a cylindrical die with an inner diameter of 10 mm, and was pressed into a bulk specimen of size ? 10×30 mm. The samples were sintered in the temperature range from 300℃ to 415℃, and annealed from 2h to 8h. This paper focused on the formation of magnetic phases and their sizes, magnetic properties under various heat-treatment conditions. The results showed that the main magnetic phases in Mn-20at%Ga alloys were Mn3Ga and Mn0.85Ga0.15, in addition to the MnO2 phase caused by oxidation. Mn3Ga and Mn0.85Ga0.15 were generated respectively from the high Ga content region and low Ga content region caused by the high-energy ball milling. The high Ga content region appeared to be irregular particles, whereas the low Ga content region appeared to be located in the interparticle region. The magnetic properties were measured at room temperature using a vibrating sample magnetometer. To evaluate the magnetic properties quantitatively, the coercivity, remanence, and energy product were deduced from the data of hysteresis curves. The remanence, coercivity, and maximum energy product can be improved by enhancing the annealing temperature into a proper range. Enhancing the annealing time properly also benefited the improvement of remanence and maximum energy product. However, coercivity change due to the annealing time was negligible. The optimal magnetic properties in this research were obtained at an annealing temperature of 385℃ and annealing time of 6h, which showed a remanence of 63.21 emu/cm3, a coercivity of 8.1 kOe, and a maximum energy product of 0.15 MGOe. The size change of Mn3Ga nanophase due to annealing conditions was small. However, the size of Mn0.85Ga0.15 nanophase was decreased due to a proper enhancement of annealing temperature and annealing time, which corresponded to the increase of coercivity. The crystal size decrease of Mn0.85Ga0.15 benefited the enhancement of magnetic properties.

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张林,陈梦龙,高玉龙,赵晨希,魏浩宇,梁宁,王恩刚. Mn-20at%Ga纳米复合磁性材料的制备和磁性能研究[J].稀有金属材料与工程,2022,51(1):315~320.[Zhang Lin, Chen Menglong, Gao Yulong, Zhao Chenxi, Wei Haoyu, Liang Ning, Wang Engang. Fabrication and Magnetic Properties of Mn-20at%Ga Nanoscale Magnetic Materials[J]. Rare Metal Materials and Engineering,2022,51(1):315~320.]
DOI:10.12442/j. issn.1002-185X.20210064

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  • 收稿日期:2021-01-21
  • 最后修改日期:2021-04-09
  • 录用日期:2021-05-12
  • 在线发布日期: 2022-02-09
  • 出版日期: 2022-01-28