Theoretical insights into hydrogenation of CO2 to formic acid over a single Co atom incorporated nitrogen-doped graphene: A DFT study

[Display omitted] •A single Co atom can be stably anchored over a monovavancy nitrogen-doped graphene.•CO2 hydrogenation proceeds via the formate (HCOO) intermediate.•The activation energy for the rate-determining-step of this reaction is 0.51 eV.•The formation of side products (CO and H2O) is almos...

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Bibliographic Details
Published in:Applied surface science 2019-05, Vol.475, p.363-371
Main Authors: Esrafili, Mehdi D., Nejadebrahimi, Bahram
Format: Article
Language:English
Subjects:
Catalysis
CO2 reduction
DFT
Doping
Graphene
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Summary:[Display omitted] •A single Co atom can be stably anchored over a monovavancy nitrogen-doped graphene.•CO2 hydrogenation proceeds via the formate (HCOO) intermediate.•The activation energy for the rate-determining-step of this reaction is 0.51 eV.•The formation of side products (CO and H2O) is almost impossible or proceeds with great difficulty. The catalytic hydrogenation of CO2 molecule over a single Co atom incorporated nitrogen-doped graphene is investigated using dispersion-corrected density functional theory calculations. It is found that a Co adatom can be effectively stabilized over a mono- or di-vacancy defective nitrogen-doped graphene due to strong hybridization between the Co-3d and N-2p states near the Fermi level. The high energy barrier for the diffusion of Co atom suggests that the resulting structures are stable enough to be used in the hydrogenation of CO2. Our results indicate the Co atom incorporated over a mono-vacancy defective nitrogen-doped graphene (CoN3-Gr) has a large tendency to activate H2 and CO2 molecules due to localization of a relative large positive charge on the Co atom. The hydrogenation of CO2 over CoN3-Gr starts with the coadsorption of H2 and CO2, followed by the formation of a formate (HCOO) intermediate. This needs an activation energy of 0.31 eV, which indicates it can easily proceed at ambient temperature. In the next step, the HCOO moiety is converted to HCOOH by overcoming an energy barrier of 0.51 eV. Our results indicate that the formation of side products, i.e. CO and H2O, is almost impossible or proceeds with great difficulty due to the corresponding large activation energy. The results of this study suggest that CoN3-Gr can be regarded as a highly active and promising catalyst for hydrogenation of CO2 at room temperature.
ISSN:0169-4332
1873-5584
DOI:10.1016/j.apsusc.2018.12.302