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JOURNAL ARTICLE

Big Bandgap in Highly Reduced Graphene Oxides

Ke-Yan LianYongfei JiXiaofei LiMingxing JinDajun DingYi Luo

Year: 2013 Journal:   The Journal of Physical Chemistry C Vol: 117 (12)Pages: 6049-6054   Publisher: American Chemical Society
DOI: 10.1021/jp3118067
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Abstract

It is generally believed that the bandgap of the graphene oxide is proportional to the concentration of the oxygen atoms and a highly reduced graphene oxide (rGO) without vacancy defects should be gapless. We show here from first principles calculations that the bandgap can be effectively opened even in low oxidation level with the absorption of oxygen atoms either symmetrically or asymmetrically. The properly arranged absorption can induce a bandgap up to 1.19 eV for a C/O ratio of 16/1 in a symmetric system and a bandgap up to 1.58 eV for a C/O ratio of 32/3 in an asymmetric system, at generalized gradient approximation (GGA) level. The hybridization between the in-plane pxy orbitals of oxygen atoms and the out-of-plane pz frontier orbital of graphene is responsible for the opening of the bandgap. This finding sheds new light on the bandgap engineering of graphene.

Keywords:
Graphene Band gap Gapless playback Oxide Materials science Oxygen Absorption (acoustics) Condensed matter physics Atomic orbital Vacancy defect Optoelectronics Molecular physics Nanotechnology Chemistry Physics Electron Composite material Quantum mechanics

Metrics

69
Cited By
3.65
FWCI (Field Weighted Citation Impact)
48
Refs
0.94
Citation Normalized Percentile
Is in top 1%
Is in top 10%

Citation History

Topics

Graphene research and applications
Physical Sciences →  Materials Science →  Materials Chemistry
Graphene and Nanomaterials Applications
Physical Sciences →  Engineering →  Biomedical Engineering
2D Materials and Applications
Physical Sciences →  Materials Science →  Materials Chemistry

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