在电磁场中形成具有磁性的复合涂层

M. Sakhnenko, I. Yermolenko, A. Korohodska, H. Karakurkchi, N. Gorohivska
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摘要

本文介绍并分析了恒定磁场对铁族金属及其合金电沉积过程影响的研究结果。研究结果表明,该方法可以加速镀层的沉积,改善镀层的表面形貌和硬度。恒定磁场作用下的复合涂层比没有磁场作用下的复合涂层具有更高的耐腐蚀性、光催化性能和磁性能。已经确定,恒定磁场的存在改变了所研究材料的化学成分。铁磁性成分增加,抗磁性成分减少。为了评估其磁性能,我们选择了在不同电解时间下由单极脉冲电流沉积的Fe-Co-W和Fe-Co-Mo涂层样品,这是由于其成分的厚度和分布不同。结果表明,在三组分合金电沉积的非平衡过程中,形成了一些金属间非磁性化合物的簇状结构,这些簇状结构具有短范围有序特征,导致合金的饱和磁化强度降低。Fe-Co-W涂层的矫顽力值高于非晶合金,其中元素P, B, Si作为非磁性成分。对于Fe-Co-W合金来说,与顺磁性金属间相中钨的原子排列顺序相似的大团簇,以及表面粗糙度和自由体积,可能在磁化反转中起重要作用。结果表明,Fe-Co-W电偶合金可分为磁硬材料和磁软材料,并结合较高的显微硬度,为该系统在信息记录、再现和微机电系统磁性元件生产中的应用开辟了前景。通过适当设计磁场结构,可以创建新的磁性纳米结构和对工业催化和电镀过程的新水平的控制。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
FORMATION OF COMPOSITE COATINGS WITH MAGNETIC PROPERTIES IN AN ELECTROMAGNETIC FIELD
The article presents and analyzes the results of the study of the influence of a constant magnetic field on the electrodeposition processes of the ferrum family metals and their alloys. The studies performed indicate the effect of accelerating deposition, improving the surface morphology and hardness of the obtained coatings. Composite coatings applied under the influence of a constant magnetic field can have higher corrosion resistance, improved photocatalytic and magnetic properties than those obtained without it. It has been established that the presence of a constant magnetic field changes the chemical composition of the studied material. There is an increase in the ferromagnetic and a decrease in the diamagnetic component. To assess the magnetic properties, samples of Fe-Co-W and Fe-Co-Mo coatings deposited by unipolar pulsed current at different electrolysis durations were selected, which is due to the difference in the thickness and distribution of the components. The results obtained suggest that in the nonequilibrium process of electrodeposition in three-component alloys, clusters with a short-range order characteristic of a number of intermetallic nonmagnetic compounds are formed, which leads to a decrease in the saturation magnetization of the alloy. The Fe-Co-W coatings are characterized by higher values of the coercive force compared to amorphous alloys, in which the elements P, B, Si act as a non-magnetic component. Probably, for the Fe-Co-W alloy, large clusters with a compositional order similar to the arrangement of atoms in the paramagnetic intermetallic phase with tungsten, along with surface roughness and free volume, play a significant role in magnetization reversal. The results obtained make it possible to classify the obtained Fe-Co-W galvanic alloys as magnetically hard, and Fe-Co-Mo as magnetically soft materials, which, in combination with high microhardness, opens up prospects for the use of such systems in the production of magnetic elements for recording and reproducing information and microelectromechanical systems respectively. With properly designed field structures, new magnetic nanostructures and a new level of control over industrial catalytic and electroplating processes can be created.
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