高等学校化学学报 ›› 2021, Vol. 42 ›› Issue (2): 321.doi: 10.7503/cjcu20200477
收稿日期:
2020-07-21
出版日期:
2021-02-10
发布日期:
2020-12-14
通讯作者:
左自成
E-mail:zuozic@iccas.ac.cn
基金资助:
GAO Xiaoya, ZUO Zicheng(), LI Yuliang
Received:
2020-07-21
Online:
2021-02-10
Published:
2020-12-14
Contact:
ZUO Zicheng
E-mail:zuozic@iccas.ac.cn
Supported by:
摘要:
石墨炔是新兴的碳同素异形体, 其独特的结构和性质引起了不同领域科学家的广泛关注. 研究表明, 石墨炔在能源、 催化、 光学、 磁学、 信息科学和生命科学等领域发展潜力巨大. 近年来, 石墨炔在电化学能源领域的基础和应用研究展现了石墨炔作为电化学能源材料所具有的独特优势, 为解决电化学能源器件所面临的科学瓶颈提供了新理念、 新方法和新概念. 本文综合评述了近3年来石墨炔在电化学电池界面应用方面的研究进展, 主要涉及二维石墨炔的制备和结构优势, 及其为多种电化学电池电极界面构筑、 界面选择性传输及电极界面稳定性等带来的新启发.
中图分类号:
TrendMD:
高小雅, 左自成, 李玉良. 石墨炔电化学电池界面构筑. 高等学校化学学报, 2021, 42(2): 321.
GAO Xiaoya, ZUO Zicheng, LI Yuliang. Construction of Graphdiyne Interface in Electrochemical Batteries. Chem. J. Chinese Universities, 2021, 42(2): 321.
Fig.2 Characterization of silicon anode coated by graphdiyne and the performance[44](A) TEM images of the silicon nanoparticles protected by the graphdiyne in large scale; (B) TEM image of the graphdiyne nanosheet; (C) TEM images of the graphdiyne on the silicon nanoparticles; (D, E) rate performance(D) and long-term stability(E) of the silicon electrode before and after coating graphdiyne;(F) the scheme showing the mechanism of performance enhancement of silicon anode. Copyright 2018, Wiley-VCH.
Fig.3 Top view(A—C) and side view(D—F) SEM images of graphdiyne?coated metal oxide electrodes with different morphologies and their electrochemical performance(G—H)[49](A, D, G) Nanorods; (B, E, H) nanowalls; (C, F) nanospheres. Copyright 2019, Wiley-VCH.
Fig.4 Top view(A) and side view(B) of the optimized structural model for the calculation and the plot of the binding energy between the graphdiyne and the LiCoO2 cathode(C)[53]Copyright 2018, Royal Society of Chemistry.
Fig.5 Problems of organic cathodes(A, B) and the potential of graphdiyne for protecting the organic cathodes(C) and SEM images of the sodium rhodizonate dibasic before(D) and after(E) graphdiyne coating[66]Copyright 2020, Wiley-VCH.
Fig.6 Characterization of the sulfur cathode[69](A) Scheme of the H-graphdiyne(HSGY@S) for the sulfur cathode; (B, C) SEM(B) and (C) TEM image of HSGY@S; (D—F) elemental distribution images of samples. Copyright 2019, Wiley-VCH.
Fig.7 Preparation and characterization of the S@Nafion@graphdiyne cathode[75](A) Illustrations to showing the preparation of the electrode; (B, C) SEM(B) and TEM(C) images of the electrode;(D,E) the electrochemical performance of the electrode with S loading of 1.5 mg/cm2(D) and 3 mg/cm2(E). Copyright 2020, Elsevier.
Fig.8 Graphdiyne film for suppressing lithium dendrites[87](A) SEM of graphdiyne film;(B) polarization curves of lithium deposition process; (C, D) possible behaviors of lithium deposition without(C)and with(D) graphdiyne film. Copyright 2018, Elsevier.
Fig.9 Interaction between N?doped graphdiyne and Li atoms[89](A, B) N configurations(A) and its corresponding N1s XPS(B) in graphdiyne;(C) the binding energy between different N configurations and Li atom; (D—F) the optimized structure of Li atom on the Cu(D), graphdiyne (E) and N-doped graphdiyne(F). Copyright 2019, Royal Society of Chemistry.
Fig.10 Graphdiyne film for suppressing the Zn dendrites[90](A, B) Top view(A) and side view(B) morphologies of the H-graphdiyne(HsGDY) on the Zn electrode; (C) transport of Zn ions in the HsGDY film; (D) electrochemical stability of HsGDY-modified Zn electrode; (E) morphologies of the Zn electrodes after cycling. Copyright 2020, Wiley-VCH.
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