Realizing fast plating/stripping of high-performance Zn metal anode with a low Zn loading

IF 0.7 Q4 MATERIALS SCIENCE, MULTIDISCIPLINARY
Zhuo Li, Tamene Tadesse Beyene, Kai ZHU, D. Cao
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引用次数: 0

Abstract

Zn metal batteries and capacitors (ZMBs/ZMCs) are gaining significant attention due to their low cost, high safety, and high theoretical capacity. However, the low utilization of Zn metal decreases the coulombic efficiency. Here, we present a novel approach to enhance the conductivity of host materials by utilizing a 3D conductive structural network of copper mesh. The 3D copper mesh serves as a high-conductive matrix and additionally coating it with Zn serves as a Zn source. Finally, a flexible reduced graphene oxide (rGO) was deposited on the Zn-coated copper mesh as an anode protective layer. The conductive copper mesh renders a fast plating/stripping of Zn and enables more contact of Zn with the electrolyte. The flexible rGO film deposited on Zn-coated copper mesh alleviates the local charge accumulation and inhibits corrosion. As a result, the Zn-coated copper mesh anode modified with rGO (RCZ) exhibited a longer lifespan of 200 h than the Zn-coated planar copper foil anode which cycled only for 30 h. The RCZ||AC full capacitor obtained high capacity retention of 97.9% after 9000 times cycling. The RCZ anode integrates the merits of 3D structure matrix and rGO realizing a dual-functionalized Zn metal anode. The conductive matrix strategy sheds light on other metal batteries.
实现高性能锌金属阳极的快速电镀/剥离和低锌负载
锌金属电池和电容器(ZMB/ZMC)因其低成本、高安全性和高理论容量而备受关注。然而,金属锌的低利用率降低了库仑效率。在此,我们提出了一种利用铜网三维导电结构网络来增强宿主材料导电性的新方法。三维铜网可作为高导电基体,此外,在铜网上镀锌可作为锌源。最后,柔性还原氧化石墨烯(rGO)作为阳极保护层沉积在锌涂层铜网上。导电铜网可以快速镀锌/剥离锌,并使锌与电解液有更多接触。沉积在镀锌铜网上的柔性 rGO 薄膜可减轻局部电荷积累并抑制腐蚀。因此,用 rGO 修饰的 Zn 涂层铜网阳极(RCZ)比仅循环 30 小时的 Zn 涂层平面铜箔阳极寿命长 200 小时。RCZ 阳极综合了三维结构矩阵和 rGO 的优点,实现了金属锌阳极的双功能化。导电矩阵策略为其他金属电池提供了启示。
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来源期刊
Journal of metals, materials and minerals
Journal of metals, materials and minerals MATERIALS SCIENCE, MULTIDISCIPLINARY-
CiteScore
1.40
自引率
11.10%
发文量
0
期刊介绍: Journal of Metals, Materials and Minerals (JMMM) is a double-blind peer-reviewed international journal published 4 issues per year (starting from 2019), in March, June, September, and December, aims at disseminating advanced knowledge in the fields to academia, professionals and industrialists. JMMM publishes original research articles as well as review articles related to research and development in science, technology and engineering of metals, materials and minerals, including composite & hybrid materials, concrete and cement-based systems, ceramics, glass, refractory, semiconductors, polymeric & polymer-based materials, conventional & technical textiles, nanomaterials, thin films, biomaterials, and functional materials.
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