Magnetostrictive strain-sensitivity synergy for laser-beam powder bed fusion processed Fe81Ga19 alloys by magnetic field annealing

Xiong Yao , Desheng Li , Chengde Gao , Youwen Deng , Jing Zhang , Cijun Shuai
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Abstract

Magnetostrictive Fe–Ga alloys have been demonstrated potentialities for numerous applications, whereas, suffering a tradeoff between large magnetostrictive strain and high sensitivity. Herein, bulk polycrystalline Fe81Ga19 alloys were prepared by laser-beam powder bed fusion (LPBF) and then annealed in magnetic field for manipulating the comprehensive magnetostrictive properties. Results indicate that <001> oriented grains are developed in the LPBF-prepared Fe81Ga19 alloys due to high temperature gradient. After magnetic field annealing (MFA), the magnetic domains within the alloys gradually transformed into well-arranged stripe domains, especially, flat and smooth 90° domains were established in the alloys annealed at 2600 ​Oe. As a result, the induced <001> orientation grains and 90° domains contributed to an improved effective magnetic anisotropy constant (57.053 ​kJ/m3), leading to an enhanced magnetostrictive strain of 92 ​ppm. Moreover, the MFA-treated alloys also displayed enhanced magnetostrictive sensitivity (0.097 ​ppm/Oe) owing to the smooth domain structures and low dislocation densities, demonstrating a fruitful strain-sensitivity synergy. In addition, good magnetostrictive dynamic response and enhanced compressive yield strength were also observed for the prepared alloys. This work demonstrates that LPBF and MFA might be an attractive strategy to resolve the tradeoff between strain and sensitivity, providing a basis for the preparation of high-performance magnetostrictive materials.

Abstract Image

通过磁场退火实现激光束粉末床熔融加工 Fe81Ga19 合金的磁致伸缩应变灵敏度协同效应
磁致伸缩铁-镓合金已被证明具有广泛的应用潜力,但在大磁致伸缩应变和高灵敏度之间存在权衡问题。本文通过激光束粉末床熔融(LPBF)制备了块状多晶 Fe81Ga19 合金,然后在磁场中进行退火处理,以操纵其综合磁致伸缩特性。结果表明,在 LPBF 制备的 Fe81Ga19 合金中,由于高温梯度的作用,形成了<001>取向晶粒。经过磁场退火(MFA)后,合金内部的磁畴逐渐转变为排列整齐的条状磁畴,尤其是在 2600 Oe 下退火的合金中形成了平整光滑的 90° 磁畴。因此,诱导的<001>取向晶粒和 90° 磁畴提高了有效磁各向异性常数(57.053 kJ/m3),从而增强了 92 ppm 的磁致伸缩应变。此外,由于畴结构光滑且位错密度低,经 MFA 处理的合金还显示出更高的磁致伸缩灵敏度(0.097 ppm/Oe),显示出富有成效的应变-灵敏度协同作用。此外,制备的合金还具有良好的磁致伸缩动态响应和更高的抗压屈服强度。这项研究表明,LPBF 和 MFA 可能是解决应变和灵敏度之间权衡问题的一种有吸引力的策略,为制备高性能磁致伸缩材料奠定了基础。
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