Structural and magnetic study of mechanically alloyed Fe-Ni

M Pȩkała , D Oleszak , E Jartych , J.K Żurawicz
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引用次数: 27

Abstract

The FexNi100-x (x = 50, 65 and 80) alloys were synthesized in a conventional horizontal low energy ball mill. The X-ray diffraction was used to identify and characterise various phases during the milling process of the Fe80Ni20 alloy exhibiting a bcc structure whereas for x = 65 and 50 the fcc structures are found. The steady state grain size is about 10 nm. Magnetisation measurements after various milling periods allow to monitor a rate at which Ni atoms dissolve in the iron lattice. The room temperature values of the effective magnetic moment raise with the increasing milling period. All the alloys studied exhibit the ferromagnetic ordering. The magnitude of the magnetic interactions is moderately suppressed at prolonged milling as revealed by the Curie temperatures reduced down to 950 K. Such variations are caused by the deviations in the interatomic arrangements of atoms especially in the intergrain regions. The Moessbauer spectroscopy confirmed the ferromagnetic ordering and was used to calculate the distribution of hyperfine magnetic fields. The mean hyperfine fields are 33.8 T for Fe80Ni20 and correspond to the one to two Ni atoms in nearest neighbourhood. In the remaining alloys, at most, five Ni atoms are located in a neighbourhood of the Fe atom.

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机械合金化铁-镍的结构和磁性研究
在常规卧式低能球磨机上合成了FexNi100-x (x = 50、65和80)合金。利用x射线衍射对Fe80Ni20合金在铣削过程中表现出bcc结构的不同相进行了识别和表征,而在x = 65和50时则发现了fcc结构。稳态晶粒尺寸约为10 nm。在不同的铣削周期后的磁化测量允许监测镍原子溶解在铁晶格中的速率。有效磁矩的室温值随着磨矿时间的延长而升高。所研究的合金均表现出铁磁有序。在长时间铣削过程中,磁性相互作用的强度被适度抑制,居里温度降低到950 K。这种变化是由原子间排列的偏差引起的,特别是在晶间区域。Moessbauer谱证实了铁磁有序,并用于计算超细磁场的分布。Fe80Ni20的平均超精细场为33.8 T,对应于最邻近的一到两个Ni原子。在其余的合金中,最多有5个Ni原子位于Fe原子附近。
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