Enhancing the Magnetic Core Properties of Ultra-Thin Flaky FeSiAl Alloy Powders Through High-Temperature Reduction Treatment

IF 1.6 4区物理与天体物理 Q3 PHYSICS, APPLIED Journal of Superconductivity and Novel Magnetism Pub Date : 2024-06-04 DOI:10.1007/s10948-024-06772-z

Lunjia Du, Jianwen Chen, Qingqing Zhang, Zhimei Long, Chaoqun Li, Jiaqi Lai, Lan Liu, Te Hu, Yilong Ma, Bin Shao

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Abstract

The surface properties of ultra-thin flaky FeSiAl alloy powders with a thickness of 0.65 μm were modified through a high-temperature reduction process. The original FeSiAl alloy powders exhibited an inherent outer layer primarily composed of FeO_x, SiAl_xO_y, and Al₂O₃. The reduction process involved the reduction of Fe³⁺ to metallic Fe through the use of H₂. During the pressing process of the magnetic core, the flaky FeSiAl alloy powders naturally formed a stack structure with the (100) orientation. Following the reduction treatment, the FeSiAl magnetic core demonstrated an effective permeability as high as 624 at 100 kHz, with a total loss of 108.8 mW/cm³ under maximal applied fields of 50 mT at 100 kHz. These results reveal that high-temperature reduction treatment and reduction in the thickness of flaky FeSiAl alloy powders play the significant role in further enhancing their magnetic core properties.

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通过高温还原处理增强超薄片状铁硅铝合金粉末的磁芯特性

通过高温还原工艺改变了厚度为 0.65 μm 的超薄片状 FeSiAl 合金粉末的表面特性。原始的 FeSiAl 合金粉末具有一个主要由 FeOx、SiAlxOy 和 Al2O3 组成的固有外层。还原过程包括使用 H2 将 Fe3+ 还原成金属 Fe。在磁芯的压制过程中，片状的 FeSiAl 合金粉末自然形成了 (100) 取向的堆叠结构。经过还原处理后，FeSiAl 磁芯在 100 kHz 频率下的有效磁导率高达 624，在 100 kHz 频率下的最大外加磁场为 50 mT 时，总损耗为 108.8 mW/cm3。这些结果表明，高温还原处理和减少片状 FeSiAl 合金粉末的厚度对进一步提高其磁芯性能具有重要作用。

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来源期刊

Journal of Superconductivity and Novel Magnetism 物理-物理：凝聚态物理

CiteScore

3.70

自引率

11.10%

发文量

342

审稿时长

3.5 months

期刊介绍： The Journal of Superconductivity and Novel Magnetism serves as the international forum for the most current research and ideas in these fields. This highly acclaimed journal publishes peer-reviewed original papers, conference proceedings and invited review articles that examine all aspects of the science and technology of superconductivity, including new materials, new mechanisms, basic and technological properties, new phenomena, and small- and large-scale applications. Novel magnetism, which is expanding rapidly, is also featured in the journal. The journal focuses on such areas as spintronics, magnetic semiconductors, properties of magnetic multilayers, magnetoresistive materials and structures, magnetic oxides, etc. Novel superconducting and magnetic materials are complex compounds, and the journal publishes articles related to all aspects their study, such as sample preparation, spectroscopy and transport properties as well as various applications.