First-principles calculation of quantum capacitance of metals doped graphenes and nitrogen/metals co-doped graphenes: designing strategies for supercapacitor electrodes

In this paper, we investigated the quantum capacitance and the integrated charge of graphene-based materials based on first-principles density functional theory calculations. Transition metals doped in a graphene plane will not move out of the graphene plane and will finally form an accurate symmetr...

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Bibliographic Details
Published in:Journal of materials science 2019, Vol.54 (1), p.483-492
Main Authors: Wang, Min, Chen, Liangliang, Zhou, Jiangqi, Xu, Lingrui, Li, Xiangyang, Li, Lijie, Li, Xin
Format: Article
Language:English
Subjects:
Analysis
Atomic properties
Capacitance
Capacitors
Characterization and Evaluation of Materials
Charge materials
Chemistry and Materials Science
Classical Mechanics
Computation
Crystallography and Scattering Methods
Density
Density functional theory
Divacancies
Electrode materials
Electrodes
First principles
Graphene
Graphite
Materials Science
Mathematical analysis
Nitrogen
Polymer Sciences
Scandium
Solid Mechanics
Supercapacitors
Transition metals
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Summary:In this paper, we investigated the quantum capacitance and the integrated charge of graphene-based materials based on first-principles density functional theory calculations. Transition metals doped in a graphene plane will not move out of the graphene plane and will finally form an accurate symmetrical structure. Meanwhile, for transition metals doped out of plane, regardless of the positions that the metals were placed, they will conform to the same stable M–MV complexes eventually. Meanwhile, the introduction of N atoms makes the Al atom hybridization state tend to be consistent. Al 3 –NNN (the Al-embedded, nitrogen doped monovacancy graphene-based complexes, and the number of N atoms represents the number of N atoms surrounding the Al) and Al 4 –NNNN (Al-embedded, nitrogen doped divacancy graphene-based complexes) have the same Al atom hybridization, but it is different in the Al doped monovacancy graphene complexes (Al–MV) and the Al doped divacancy graphene complexes (Al–DV). In addition, we also found that both the Sc doped monovacancy graphene and the Al 4 –N (Al-embedded, nitrogen doped divacancy graphene-based complexes) can be used as candidates for the negative electrode materials of asymmetric supercapacitors. The results can provide valuable insights into the design and preparation of electrodes for high-performance supercapacitors.
ISSN:0022-2461
1573-4803
DOI:10.1007/s10853-018-2840-0