Fabrication of hollow metallic copper particles using a standard electrode potential difference

IF 1.6 4区化学 Q3 CHEMISTRY, INORGANIC & NUCLEAR Transition Metal Chemistry Pub Date : 2023-09-08 DOI:10.1007/s11243-023-00554-7

Reo Kasori, Noriko Yamauchi, Shohei Tada, Yoshio Kobayashi

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Abstract

Hollow metallic particles have a lower density than their bulk counterparts with an equivalent apparent volume; therefore, they are expected to be applied in fields requiring low density and large surface area materials. This study proposes a method for synthesizing hollow metallic Cu particles in an aqueous solution. An aqueous suspension of hollow metallic Cu particles was prepared by placing metallic Zn particles in an aqueous Cu acetate solution. Based on the displacement plating related to the standard electrode potential difference between Cu and Zn, Cu²⁺ ions were reduced to metallic Cu by receiving electrons from metallic Zn, while metallic Zn dissolved into the aqueous solution. Consequently, metallic Cu with a shell-like shape formed near the surface of the original metallic Zn particles before Zn dissolution, yielding hollow metallic Cu particles. Thus, this study revealed that the Cu acetate concentration should be appropriately controlled to fabricate hollow particles. Moreover, the developed method can easily fabricate hollow metallic particles in one step without adding external reducing agents.

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使用标准电极电位差制备空心金属铜颗粒

中空金属颗粒的密度低于具有等效表观体积的块状金属颗粒；因此，它们有望应用于需要低密度和大表面积材料的领域。本研究提出了一种在水溶液中合成中空金属Cu颗粒的方法。通过将金属Zn颗粒置于醋酸铜水溶液中来制备中空金属Cu颗粒的水悬浮液。基于与Cu和Zn之间的标准电极电势差相关的置换电镀，Cu2+离子通过从金属Zn接收电子而被还原为金属Cu，同时金属Zn溶解在水溶液中。因此，在Zn溶解之前，在原始金属Zn颗粒的表面附近形成具有壳状形状的金属Cu，产生中空的金属Cu颗粒。因此，本研究表明，应适当控制醋酸铜的浓度以制备中空颗粒。此外，所开发的方法可以在不添加外部还原剂的情况下一步容易地制备中空金属颗粒。

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来源期刊

Transition Metal Chemistry 化学-无机化学与核化学

CiteScore

3.60

自引率

0.00%

发文量

审稿时长

1.3 months

期刊介绍： Transition Metal Chemistry is an international journal designed to deal with all aspects of the subject embodied in the title: the preparation of transition metal-based molecular compounds of all kinds (including complexes of the Group 12 elements), their structural, physical, kinetic, catalytic and biological properties, their use in chemical synthesis as well as their application in the widest context, their role in naturally occurring systems etc. Manuscripts submitted to the journal should be of broad appeal to the readership and for this reason, papers which are confined to more specialised studies such as the measurement of solution phase equilibria or thermal decomposition studies, or papers which include extensive material on f-block elements, or papers dealing with non-molecular materials, will not normally be considered for publication. Work describing new ligands or coordination geometries must provide sufficient evidence for the confident assignment of structural formulae; this will usually take the form of one or more X-ray crystal structures.