Probe Microscopy in the Investigation of Ni/Cu and FeNi Magnetic Nanowires

IF 0.8 Q3 Engineering Nanotechnologies in Russia Pub Date : 2024-03-23 DOI:10.1134/S263516762360150X
D. A. Bizyaev, D. L. Zagorskiy, D. R. Khairetdinova
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Abstract

Тhe work is devoted to studying the magnetic properties of one-dimensional nanostructures: nanowires (NWs). Two types of NWs are obtained by matrix synthesis and studied by probe microscopy. The combination of probe-microscopy modes makes it possible to determine the topography of the nanocrystals and the nature of their magnetization. The change in the magnetization during the application of an external magnetic field (varying in magnitude and direction) is investigated. It is shown that magnetization reversal in an external magnetic field depends on the relative position of the nanowire. Samples of the first type are Ni/Cu layered NWs: their magnetization reversal in an external magnetic field is studied and the magnitude of this field is determined. It is shown that the latter depends on the relative position and interaction of NWs with each other. For a single NW this is 4–5 mT, and for double NWs it is noticeably higher (12–15 mT). An agglomerate consisting of several interacting NWs is undergoes magnetization reversal in stages. The second type of samples are arrays of homogeneous NWs made of FeNi alloy located directly in the growth matrix. The field of magnetization reversal of isolated NWs in all cases is 7–14 mT. On the contrary, in groups of closely located NWs, the switching of magnetization occurs in stages. In this case, the range of switching fields depends on the density of NWs in the matrix and, in general, is much broader than for isolated NWs. In general, it is shown that the magnetic properties of NWs change significantly as the distance between them decreases: their magnetization reversal becomes more difficult, and various intermediate states appear, including those with opposite (antiferromagnetic) magnetization in neighboring NWs.

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探针显微镜在镍/铜和铁镍磁纳米线研究中的应用
这项工作致力于研究一维纳米结构:纳米线(NWs)的磁特性。通过基质合成获得了两种类型的纳米线,并通过探针显微镜进行了研究。探针-显微镜模式的结合使确定纳米晶体的形貌及其磁化性质成为可能。研究了在施加外部磁场(大小和方向不同)时磁化的变化。研究表明,外磁场中的磁化反转取决于纳米线的相对位置。第一种类型的样品是镍/铜层状纳米线:研究了它们在外加磁场中的磁化反转,并确定了磁场的大小。研究表明,后者取决于纳米线的相对位置和它们之间的相互作用。单个 NW 的磁场为 4-5 mT,而双 NW 的磁场明显更高(12-15 mT)。由多个相互作用的 NW 组成的团块会分阶段发生磁化反转。第二类样品是由铁镍合金制成的均匀 NWs 阵列,直接位于生长基体中。在所有情况下,孤立 NW 的磁化反转磁场均为 7-14 mT。相反,在位置紧密的 NWs 组中,磁化切换是分阶段发生的。在这种情况下,切换磁场的范围取决于基体中 NW 的密度,一般来说,比孤立的 NW 要宽得多。一般来说,NWs 的磁性能会随着它们之间距离的减小而发生显著变化:它们的磁化反转变得更加困难,并且会出现各种中间状态,包括相邻 NWs 中具有相反(反铁磁性)磁化的状态。
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来源期刊
Nanotechnologies in Russia
Nanotechnologies in Russia NANOSCIENCE & NANOTECHNOLOGY-
CiteScore
1.20
自引率
0.00%
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0
期刊介绍: Nanobiotechnology Reports publishes interdisciplinary research articles on fundamental aspects of the structure and properties of nanoscale objects and nanomaterials, polymeric and bioorganic molecules, and supramolecular and biohybrid complexes, as well as articles that discuss technologies for their preparation and processing, and practical implementation of products, devices, and nature-like systems based on them. The journal publishes original articles and reviews that meet the highest scientific quality standards in the following areas of science and technology studies: self-organizing structures and nanoassemblies; nanostructures, including nanotubes; functional and structural nanomaterials; polymeric, bioorganic, and hybrid nanomaterials; devices and products based on nanomaterials and nanotechnology; nanobiology and genetics, and omics technologies; nanobiomedicine and nanopharmaceutics; nanoelectronics and neuromorphic computing systems; neurocognitive systems and technologies; nanophotonics; natural science methods in a study of cultural heritage items; metrology, standardization, and monitoring in nanotechnology.
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