| Literature DB >> 33411539 |
Zhijuan Zhao1, Tianyu Hou2, Nannan Wu2, Shuping Jiao3, Ke Zhou4, Jun Yin5, Ji Won Suk6, Xu Cui7, Mingfei Zhang2, Shaopeng Li2, Yan Qu2,8, Weiguang Xie1, Xi-Bo Li1, Chuanxi Zhao1, Yong Fu1, Rong-Dun Hong9, Shengshi Guo9, Dingqu Lin9, Weiwei Cai9, Wenjie Mai1, Zhengtang Luo10, Yongtao Tian11, Yun Lai2, Yuanyue Liu12, Luigi Colombo13, Yufeng Hao2,14.
Abstract
Corrosion of metals in atmospheric environments is a worldwide problem in industry and daily life. Traditional anticorrosion methods including sacrificial anodes or protective coatings have performance limitations. Here, we report atomically thin, polycrystalline few-layer graphene (FLG) grown by chemical vapor deposition as a long-term protective coating film for copper (Cu). A six-year old, FLG-protected Cu is visually shiny and detailed material characterizations capture no sign of oxidation. The success of the durable anticorrosion film depends on the misalignment of grain boundaries between adjacent graphene layers. Theoretical calculations further found that corrosive molecules always encounter extremely high energy barrier when diffusing through the FLG layers. Therefore, the FLG is able to prevent the corrosive molecules from reaching the underlying Cu surface. This work highlights the interesting structures of polycrystalline FLG and sheds insight into the atomically thin coatings for various applications.Entities:
Keywords: anticorrosion; chemical vapor deposition; few-layer graphene; grain boundaries; polycrystalline
Year: 2021 PMID: 33411539 DOI: 10.1021/acs.nanolett.0c04724
Source DB: PubMed Journal: Nano Lett ISSN: 1530-6984 Impact factor: 11.189