Strain-induced switch for hydrogen storage in cobalt-decorated nitrogen-doped graphene

[Display omitted] •Co-decorated N-doped graphene is a promising material for hydrogen gas storage.•The transition point of chemisorption/physisorption of hydrogen gas occurs under 8% strain.•Almost all hydrogen gas can be released by applying 10% strain.•The usable storage capacity is 6.00% at low p...

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Bibliographic Details
Published in:Applied surface science 2019-04, Vol.473, p.174-181
Main Authors: Liang, Xiongyi, Ng, Siu-Pang, Ding, Ning, Wu, Chi-Man Lawrence
Format: Article
Language:English
Subjects:
Density function theory
Graphene
Hydrogen storage
Strain
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Summary:[Display omitted] •Co-decorated N-doped graphene is a promising material for hydrogen gas storage.•The transition point of chemisorption/physisorption of hydrogen gas occurs under 8% strain.•Almost all hydrogen gas can be released by applying 10% strain.•The usable storage capacity is 6.00% at low pressure and room temperature. As a feasibility study for hydrogen storage, the adsorption behavior of H2 on transition metal-decorated N-doped graphene is systematically investigated by density functional theory and the adsorption isotherm is used to predict to practical capacity at realistic condition by grand canonical partition function. The biaxial strain is proposed to be a reversible switch for hydrogen storage. Our computational results suggest that Co-decorated N-doped graphene is a highly promising material for hydrogen gas storage with good thermal stability and excellent gravimetric density. Additionally, the adsorption of H2 is sensitive to the biaxial tensile strain, and the transition point of chemisorption/physisorption occurs under 8% strain. By applying 10% strain for desorption, the storage capacity can be effectively improved to 6.00 wt% (i.e. 19% enhancement) at low pressure and room temperature. Our findings not only reveal the feasibility of a tunable material for hydrogen storage, but also provide a new strategy to control the performance for hydrogen storage by biaxial tensile strain.
ISSN:0169-4332
1873-5584
DOI:10.1016/j.apsusc.2018.12.132