Electrodeposited cobalt and its alloys nanocoating: A brief review

2012 IEEE Business, Engineering & Industrial Applications Colloquium (BEIAC) Pub Date : 2012-04-07 DOI:10.1109/BEIAC.2012.6226099

K. M. Hyie, Wan Normimi Roslini Abdullah, Nor Azrina Resali

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引用次数: 2

Abstract

Nanocrystalline materials have gained importance to be developed due to their significantly enhanced properties compared to the polycrystalline materials. Electrodeposition has a special role in synthesizing the nanocrystalline materials. In current review, the superiority of electrodeposition technique in producing various nanocyrstalline materials that exhibit improved characteristics compared to materials produced by conventional techniques are discussed. The nanocrystalline cobalt and its alloys have been recognized as one of the capable materials to replace the hard chrome coating. This coating is known to be carcinogenic on the tissue and toxic to human beings, plants and animals. The approaches taken in designing the efficient nanocrystalline cobalt and its alloys coatings which provide superior resistance to corrosion are outlined. The mechanical properties of various nanostructured coating materials using the nanoindentation testing are also described. The understanding obtained from the review will offer guidelines for future researches, thus providing new structured coatings which can be utilized in various applications such as corrosion and wear resistance applications.

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电沉积钴及其合金纳米涂层研究进展

与多晶材料相比，纳米晶材料的性能得到了显著的提高，因此得到了越来越多的重视。电沉积在纳米晶材料的合成中具有特殊的作用。本文讨论了电沉积技术在制备各种纳米晶体材料方面的优越性，这些材料与传统方法制备的材料相比具有更好的性能。纳米晶钴及其合金已被公认为是替代硬铬涂层的有力材料之一。众所周知，这种涂层对组织具有致癌性，对人类、植物和动物都有毒性。概述了设计具有优异耐腐蚀性能的纳米晶钴及其合金涂层所采取的方法。本文还介绍了采用纳米压痕测试方法制备的各种纳米结构涂层材料的力学性能。从综述中获得的理解将为未来的研究提供指导，从而提供新的结构涂层，可用于各种应用，如耐腐蚀和耐磨应用。

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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2012 IEEE Business, Engineering & Industrial Applications Colloquium (BEIAC)

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