First principle study on cobalt-decorated graphyne for hydrogen storage

Juan Ren; Ning C. Zhang; Qi J. Liu; Bin Tang

doi:10.1080/1536383X.2018.1458024

First principle study on cobalt-decorated graphyne for hydrogen storage

Juan Ren, Ning C. Zhang, Qi J. Liu, Bin Tang

Research output: Contribution to journal › Article › peer-review

14 Scopus citations

Abstract

The adsorptions of hydrogen on cobalt-decorated graphyne are investigated by first principles study. The results show that isolate Co atom is preferred to locate hollow site above the center of the acetylenic ring (H ₁ ) with binding energies of 3.98 eV. A maximum of five hydrogen molecules can bind to cobalt-decorated graphyne on the one side. The average binding energy per H ₂ molecule for Co-decorated graphyne is around 0.26 eV, which is higher than that of pure graphyne. In addition, more H ₂ molecules would bind with cobalt-decorated graphyne when more metal atoms are dispersed at graphyne. Our calculations offer explanation for the nature of bonding between the metal and the hydrogen molecules, which the coordination bonding between the empty d states in the metal atom and the occupied s states in hydrogen molecules.

Original language	English
Pages (from-to)	643-648
Number of pages	6
Journal	Fullerenes Nanotubes and Carbon Nanostructures
Volume	26
Issue number	10
DOIs	https://doi.org/10.1080/1536383X.2018.1458024
State	Published - 3 Oct 2018
Externally published	Yes

Keywords

61.48.Gh
68.43.-h
71.15.Mb
Graphyne
adsorption
density functional theory
hydrogen

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10.1080/1536383X.2018.1458024

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title = "First principle study on cobalt-decorated graphyne for hydrogen storage",

abstract = " The adsorptions of hydrogen on cobalt-decorated graphyne are investigated by first principles study. The results show that isolate Co atom is preferred to locate hollow site above the center of the acetylenic ring (H 1 ) with binding energies of 3.98 eV. A maximum of five hydrogen molecules can bind to cobalt-decorated graphyne on the one side. The average binding energy per H 2 molecule for Co-decorated graphyne is around 0.26 eV, which is higher than that of pure graphyne. In addition, more H 2 molecules would bind with cobalt-decorated graphyne when more metal atoms are dispersed at graphyne. Our calculations offer explanation for the nature of bonding between the metal and the hydrogen molecules, which the coordination bonding between the empty d states in the metal atom and the occupied s states in hydrogen molecules.",

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T1 - First principle study on cobalt-decorated graphyne for hydrogen storage

AU - Ren, Juan

AU - Zhang, Ning C.

AU - Liu, Qi J.

AU - Tang, Bin

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N2 - The adsorptions of hydrogen on cobalt-decorated graphyne are investigated by first principles study. The results show that isolate Co atom is preferred to locate hollow site above the center of the acetylenic ring (H 1 ) with binding energies of 3.98 eV. A maximum of five hydrogen molecules can bind to cobalt-decorated graphyne on the one side. The average binding energy per H 2 molecule for Co-decorated graphyne is around 0.26 eV, which is higher than that of pure graphyne. In addition, more H 2 molecules would bind with cobalt-decorated graphyne when more metal atoms are dispersed at graphyne. Our calculations offer explanation for the nature of bonding between the metal and the hydrogen molecules, which the coordination bonding between the empty d states in the metal atom and the occupied s states in hydrogen molecules.

AB - The adsorptions of hydrogen on cobalt-decorated graphyne are investigated by first principles study. The results show that isolate Co atom is preferred to locate hollow site above the center of the acetylenic ring (H 1 ) with binding energies of 3.98 eV. A maximum of five hydrogen molecules can bind to cobalt-decorated graphyne on the one side. The average binding energy per H 2 molecule for Co-decorated graphyne is around 0.26 eV, which is higher than that of pure graphyne. In addition, more H 2 molecules would bind with cobalt-decorated graphyne when more metal atoms are dispersed at graphyne. Our calculations offer explanation for the nature of bonding between the metal and the hydrogen molecules, which the coordination bonding between the empty d states in the metal atom and the occupied s states in hydrogen molecules.

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KW - 71.15.Mb

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KW - density functional theory

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First principle study on cobalt-decorated graphyne for hydrogen storage

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Keywords

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