Synthesis and magnetic properties of NiCo₂O₄urchin-like nanofibers.

IF 2.9 4区材料科学 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY

Nanotechnology Pub Date : 2024-11-19 DOI:10.1088/1361-6528/ad947f

Ahmed Nashaat, Abdulaziz Abu El-Fadl, Hiroyuki Nakamura, Mohamed Abdelkareem Kassem

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Abstract

Single-phase NiCo2O4 (NCO) nanoparticles (NPs) with an average particle size of 12 (± 3.5) nm were successfully synthesized as aggregates in urchin-like nanofibers via a hydrothermal route. Magnetization data measured as functions of temperature and magnetic field suggest a superparamagnetic-like behavior at room temperature, a ferrimagnetic transition around a Curie temperature TC ~200 K, and a spin blocking transition at a blocking temperature TB ~90 K, as observed at a field of 100 Oe. The spin blocking nature has been investigated by analyses of the field-dependence of TB in the static magnetization and its frequency-dependence in the ac susceptibility data measured in zero-field cooling regime, both indicate a low-temperature spin glass-like state. Below TB, the coercivity increases monotonically up to 1.7 kOe with decreasing temperature down to 5 K. Our results indicate that the magnetic behavior of NCO NPs, which is mainly determined by the cations' ratio, oxidation states, and site-occupancy, can be controlled by a synthesis in appropriate particle size and morphology.

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NiCo2O4urchin-like 纳米纤维的合成与磁性能。

通过水热法成功合成了平均粒径为 12 (± 3.5) nm 的单相镍钴氧化物（NCO）纳米粒子（NPs），并将其聚集在海胆状纳米纤维中。根据温度和磁场函数测量的磁化数据表明，在室温下具有类似超顺磁性的行为，在居里温度 TC ~200 K 附近具有铁磁性转变，在阻塞温度 TB ~90 K 处具有自旋阻塞转变，这是在 100 Oe 磁场下观察到的。通过分析 TB 在静态磁化中的磁场依赖性以及在零磁场冷却条件下测量的交流电感数据中的频率依赖性，研究了自旋阻滞性质。我们的研究结果表明，NCO NPs 的磁性行为主要由阳离子比例、氧化态和位点占有率决定，可以通过合成适当粒度和形态的 NCO NPs 来控制。

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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来源期刊

Nanotechnology 工程技术-材料科学：综合

CiteScore

7.10

自引率

5.70%

发文量

820

审稿时长

2.5 months

期刊介绍： The journal aims to publish papers at the forefront of nanoscale science and technology and especially those of an interdisciplinary nature. Here, nanotechnology is taken to include the ability to individually address, control, and modify structures, materials and devices with nanometre precision, and the synthesis of such structures into systems of micro- and macroscopic dimensions such as MEMS based devices. It encompasses the understanding of the fundamental physics, chemistry, biology and technology of nanometre-scale objects and how such objects can be used in the areas of computation, sensors, nanostructured materials and nano-biotechnology.