Exceptional Combination of Large Magnetostriction, Low Hysteresis and Wide Working Temperature Range in (1-x)TbFe2-xDyCo2 Alloys

AMI: Acta Materialia Pub Date : 2021-11-01 DOI:10.2139/ssrn.3890355

Hui Zhao, Yuanchao Ji, T. Ma, Minxia Fang, Yanshuang Hao, Tianzi Yang, Chao Zhou, Sen Yang, X. Ren

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引用次数: 8

Abstract

Magnetostrictive materials with large magnetostriction, low hysteresis and wide working temperature range are desired for applications, but rarely obtained so far. In this work, we report a surprising finding in (1-x)TbFe2-xDyCo2 alloys: the composition of x=0.5 exhibits a low hysteretic magnetostriction, λ//, max ~2066 ppm, which is 159% larger than that of the commercial giant magnetostrictive alloy of Terfenol-D, λ//, max ~1298 ppm. Moreover, its temperature range for λ// >1298 ppm is even larger than 240 K, and another working temperature window for λ// >1000 ppm is from 40 K to 324 K, which can cover a large temperature fluctuation in space environments (e.g. 120-290 K in Mars). The established phase diagram of (1-x)TbFe2-xDyCo2 by systematic studies of magnetic susceptibility, X-ray diffraction and convergent-beam electron diffraction results, shows an emergence of morphotropic phase boundary (MPB) between rhombohedral (R) and orthorhombic (O) ferromagnetic phases, which is different from the MPB between R and T (tetragonal) phases in (1-x)TbFe2-xDyFe2 . We reveal that the exceptional combination of giant magnetostriction, low hysteresis and wide working temperature range is caused by this R-O MPB. The comparison between R-O MPB and R-T MPB further shows the O phase plays a vital role in the property enhancement of R-O MPB composition. Our work indicates the construction of R-O MPB may provide a new way to find high-performance magnetostrictive materials.

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(1-x)TbFe2-xDyCo2合金具有大磁致伸缩、低磁滞和宽工作温度范围的优异组合

具有大磁致伸缩、低磁滞和宽工作温度范围的磁致伸缩材料是应用所需要的，但迄今为止很少得到。在这项工作中，我们报告了在(1-x)TbFe2-xDyCo2合金中一个令人惊讶的发现:x=0.5的成分表现出低磁致伸缩，λ//，最大~2066 ppm，比商用Terfenol-D巨磁致伸缩合金λ//，最大~1298 ppm大159%。λ// >1298 ppm的温度范围甚至大于240 K， λ// >1000 ppm的另一个工作温度窗口是40 - 324 K，可以覆盖空间环境中较大的温度波动(如火星120-290 K)。通过对(1-x)TbFe2-xDyFe2的磁化率、x射线衍射和会聚束电子衍射结果的系统研究，建立了(1-x)TbFe2-xDyFe2的相图，发现(1-x)TbFe2-xDyFe2中出现了不同于(1-x)TbFe2-xDyFe2中R相和T(四方)相之间的相变相界(MPB)，在菱形(R)和正交(O)铁磁相之间出现了相变相界(MPB)。研究结果表明，这种R-O磁致伸缩材料具有超磁致伸缩、低磁滞和宽工作温度范围的优异组合。对R-O MPB和R-T MPB的对比进一步表明，O相对R-O MPB组成的性能增强起着至关重要的作用。我们的工作表明，R-O磁致伸缩结构的构建可能为寻找高性能磁致伸缩材料提供了一条新的途径。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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AMI: Acta Materialia

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