Co含量对熔体快淬Fe55-xCoxPt15B30合金的组织结构与磁性能的影响

doi:10.11900/0412.1961.2016.00485

金属学报

2017, Vol. 53

Issue (5): 609-614 DOI: 10.11900/0412.1961.2016.00485

论文

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Co含量对熔体快淬Fe_55-_xCo_xPt₁₅B₃₀合金的组织结构与磁性能的影响

马殿国¹,王英敏¹,李艳辉¹,张伟¹(

)

1 大连理工大学材料科学与工程学院辽宁省凝固控制与数字化制备技术重点实验室大连 116024
2 Institute for Materials Research, Tohoku University, Sendai 980-8577, Japan

Effect of Co Content on the Structure and Magnetic Properties of Melt-Spun Fe_55-_xCo_xPt₁₅B₃₀ Alloys

Dianguo MA¹,Yingmin WANG¹,Kunio YUBUTA²,Yanhui LI¹,Wei ZHANG¹(

)

1 Key Laboratory of Solidification Control and Digital Preparation Technology (Liaoning Province), School of Materials Science and Engineering, Dalian University of Technology, Dalian 116024, China
2 Institute for Materials Research, Tohoku University, Sendai 980-8577, Japan

引用本文:

马殿国,王英敏,李艳辉,张伟. Co含量对熔体快淬Fe_55-_xCo_xPt₁₅B₃₀合金的组织结构与磁性能的影响[J]. 金属学报, 2017, 53(5): 609-614.
Dianguo MA, Yingmin WANG, Kunio YUBUTA, Yanhui LI, Wei ZHANG. Effect of Co Content on the Structure and Magnetic Properties of Melt-Spun Fe_55-_xCo_xPt₁₅B₃₀ Alloys[J]. Acta Metall Sin, 2017, 53(5): 609-614.

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摘要:

研究了Co含量对熔体快淬Fe_55-_xCo_xPt₁₅B₃₀ (x=0~45,原子分数,%)合金热处理前后的组织结构和磁性能的影响。结果表明,添加Co可提高Fe_55-_xCo_xPt₁₅B₃₀合金的非晶形成能力,使x=15~45的快淬合金形成非晶态。经适当热处理后,合金中形成了由有序面心四方结构的永磁(Fe, Co)-Pt (L1₀)相和软磁(Fe, Co)₂B相及(Fe, Co)B相组成的纳米复相组织,显示出永磁性;添加Co的合金组织得到明显细化,x=15~45合金平均晶粒尺寸均约为18 nm;其中x=15合金具有最佳的永磁性能,磁能积达到94.4 kJ/m³。合金的矫顽力随Co含量的增加而增大,在x=30时达到最大值413.7 kA/m后,随Co含量的进一步增加而减小;这是由于不同Co含量使L1₀相的c/a值发生变化而导致其磁晶各向异性变化的结果。

关键词 ：非晶态合金, 纳米复相永磁材料, L10-FePt相, 结晶化, 磁性能

Abstract：

Fe-Pt-B nanocomposite magnets have attracted much attention because of their excellent hard magnetic properties, in which the face-centered-tetragonal FePt (L1₀) phase ensures high coercivity (_iH_c) and the Fe₂B phase provides high magnetic saturation. A high _iH_c, however, is hard to reach at low Pt concentrations in these nanocomposite magnets. It is known that a high concentration of B favors the formation of L1₀ phase in Fe-Pt-B alloys with low Pt concentration, but the annealed microstructure is usually coarse-grained due to their low amorphous-forming abilities, and the magnetic properties get deteriorated. Replacement of Fe with Co is expected to enhance the amorphous-forming ability of Fe-Pt-B alloys with low Pt and high B concentrations, and to improve their magnetic properties. In this work, the structure and magnetic properties of as-quenched and annealed Fe_55-_xCo_xPt₁₅B₃₀ (x=0~45, atomic fraction, %) alloys have been investigated. Melt-spun ribbons were prepared by melt spinning, followed by vacuum annealing at different temperatures. The structure and magnetic properties of the samples were examined by XRD, TEM and a vibrating sample magnetometer (VSM). The results indicate that single amorphous phase is formed in the alloys at x=15~45. After appropriate annealing, a nanocomposite structure consisting of L1₀ and (Fe, Co)₂B phases is obtained at x=0 and 15, and an additional (Fe, Co)B phase gets formed at x=30 and 45. A fine microstructure with mean grain size of ~18 nm has been obtained in the annealed alloys with x=15~45. In these nanocomposite alloys, the best hard magnetic property with an energy product of 94.4 kJ/m³ is reached at x=15. With increasing Co content, the _iH_c gradually increases to a maximum value of 413.7 kA/m at x=30, and then decreases at higher Co contents, which are attributed to the change of the magnetocrystalline anisotropy in L1₀ phases with different c/a ratios.

Key words： amorphous alloy nanocomposite magnet L10-FePt phase crystallization magneticproperty

收稿日期: 2016-11-02

基金资助:国家自然科学基金项目Nos.51571047和51171034

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图1 Fe55-xCoxPt15B30快淬条带的XRD谱

图2 Fe40Co15Pt15B30非晶合金在不同温度热处理900 s后的XRD谱

图3 Fe40Co15Pt15B30合金在不同温度热处理900 s后的退磁曲线

表1 Fe55-xCoxPt15B30合金经823 K热处理900 s后L10相的晶格常数

表2 Fe55-xCoxPt15B30合金经823 K热处理900 s后相的磁性能

图4 Fe55-xCoxPt15B30合金在823 K热处理900 s后的XRD谱

图5 Fe55-xCoxPt15B30合金在823 K热处理900 s后的磁滞回线

图6 Fe55-xCoxPt15B30合金在823 K热处理900 s 后的TEM明场像和SAED谱

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