Computational evaluation of superalkali-decorated graphene nanoribbon as advanced hydrogen storage materials

Computational evaluation of superalkali-decorated graphene nanoribbon as advanced hydrogen storage materials

In this study, we proposed that homo superalkali NM4 clusters with high tetrahedral geometry, can be applied to develop high-performance hydrogen storage materials. Moreover, their special bonding structures and chemical stability make them ideal units for decoration of different kinds of pristine m...

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Bibliographic Details
Published in:International journal of hydrogen energy Vol. 46; no. 48; pp. 24510 - 24516
Main Authors: Gao, Peng, Li, Ji-wen, Wang, Guangzhao
Format: Journal Article
Language:English
Published: Elsevier Ltd 13-07-2021
Subjects:
Ab initio
DFT
Graphene nanoribbon
Hydrogen storage
Superalkali cluster
Superalkali cluster
Ab initio
Hydrogen storage
DFT
Graphene nanoribbon
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Summary:In this study, we proposed that homo superalkali NM4 clusters with high tetrahedral geometry, can be applied to develop high-performance hydrogen storage materials. Moreover, their special bonding structures and chemical stability make them ideal units for decoration of different kinds of pristine monolayers. We made a trial to decorate the NLi4 clusters onto the 1D graphene nanoribbon, and employed density functional theory (DFT) computational studies to solve its electronic structure, and further evaluate its applicability in hydrogen storage. We found that the electronic charges on Li atoms were successfully transferred to the pristine monolayer, thus a partial electronic field around each Li atom was formed. This subsequently leads to the polarization of the adsorbed hydrogen molecules, and further enhances the electrostatic interactions between the Li atoms and hydrogen. Each NLi4 cluster can adsorb at most 16 hydrogen molecules. For this novel material, its total capacity of hydrogen storage can reach to 11.2 wt %, surpassing the target value of 5.5 wt %, set by the U.S department of energy (DOE) [1], making itself an ideal unit for advanced energy materials design. [Display omitted] •Superalkali NLi4 was applied to decorate graphene nanoribbon.•The NLi4-decorated graphene nanoribbon performs well in H2 adsorption.•Binding structure of this material was solved via DFT calculations.
ISSN:0360-3199
1879-3487
DOI:10.1016/j.ijhydene.2021.05.023