Electron holography of ferromagnetic nanowires

C. Beeli
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引用次数: 10

Abstract

Off-axis electron holography has been applied in order to investigate quantitatively the remanent magnetization state of single ferromagnetic Co93Cu7 and Ni nanowires, respectively. The magnetization reversal of an individual Co93Cu7 nanowire has been followed by observing a series of remanent states, obtained ex-situ by applying different external magnetic field sweeps parallel to the nanowire axis. The relation between mis-oriented crystal grains and non-uniform magnetization states has been studied by the combination of electron holography and conventional transmission electron microscopy. Nickel nanowires have been heated in-situ to temperatures above the Curie temperature and cooled down again. The magnetic state during the heating experiment was followed by a series of electron holograms. A single Ni nanowire was examined in detail. It was observed to be uniformly magnetized before the heating cycle. The ferromagnetic state spontaneously formed upon cooling from above the Curie temperature, exhibited a magnetic state with two antiparallel magnetic domains.

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铁磁纳米线的电子全息
本文采用离轴电子全息技术,分别定量研究了单根铁磁Co93Cu7和Ni纳米线的剩余磁化状态。在Co93Cu7纳米线磁化逆转之后,观察了一系列的剩余状态,这些状态是通过施加不同的平行于纳米线轴线的外磁场扫描而获得的。采用电子全息与普通透射电镜相结合的方法,研究了晶体错取向与非均匀磁化态的关系。镍纳米线被就地加热到高于居里温度的温度,然后再次冷却。加热实验过程中的磁性状态被一系列的电子全息图所跟踪。对单根Ni纳米线进行了详细的研究。在加热循环前观察到其磁化均匀。在居里温度以上冷却后自发形成铁磁态,表现出具有两个反平行磁畴的磁性态。
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