Hydrogen storage inside a toroidal carbon nanostructure C120: Density functional theory computer simulation

A. Cruz-Torres; F. De; J. Ortíz-López; J. S. Arellano

doi:10.1002/qua.22711

Hydrogen storage inside a toroidal carbon nanostructure C₁₂₀: Density functional theory computer simulation

A. Cruz-Torres, F. De, J. Ortíz-López, J. S. Arellano

Escuela Superior de Física y Matemáticas (ESFM)

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

9 Scopus citations

Abstract

Ab initio density functional calculations were performed for a toroidal carbon C₁₂₀ nanostructure. Hydrogen molecules, n = 1-15, were added inside the nanotorus and for each one of these systems a geometry optimization was obtained. The cohesive energy shows that these structures are energetically stable. For example, the binding energies are -34.95 and -36.19 Hartrees and the interatomic distances H-H are 0.753 and 0.772 Å for 1 and 14 molecules, respectively. Considering only molecular hydrogen, we have always seen so far weak physisorption into the C₁₂₀ nanotorus. There is no chemisorption until the number oh hydrogen molecules are increased to 14. In this case, four hydrogen atoms are chemisorbed. With 15 molecules, there are 10 hydrogen atoms chemisorbed just at the inner nanotorus surface forming 10 H-C bondings with bond length close to that in methane.

Translated title of the contribution	lmacenamiento de hidrógeno dentro de una nanoestructura de carbono toroidal C 120: simulación por computadora de la teoría funcional de la densidad
Original language	English
Pages (from-to)	2495-2508
Number of pages	14
Journal	International Journal of Quantum Chemistry
Volume	110
Issue number	13
DOIs	https://doi.org/10.1002/qua.22711
State	Published - 5 Nov 2010

Keywords

DFT calculations
Hydrogen storage
Toroidal carbon nanostructure

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10.1002/qua.22711

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abstract = "Ab initio density functional calculations were performed for a toroidal carbon C120 nanostructure. Hydrogen molecules, n = 1-15, were added inside the nanotorus and for each one of these systems a geometry optimization was obtained. The cohesive energy shows that these structures are energetically stable. For example, the binding energies are -34.95 and -36.19 Hartrees and the interatomic distances H-H are 0.753 and 0.772 {\AA} for 1 and 14 molecules, respectively. Considering only molecular hydrogen, we have always seen so far weak physisorption into the C120 nanotorus. There is no chemisorption until the number oh hydrogen molecules are increased to 14. In this case, four hydrogen atoms are chemisorbed. With 15 molecules, there are 10 hydrogen atoms chemisorbed just at the inner nanotorus surface forming 10 H-C bondings with bond length close to that in methane.",

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T2 - Density functional theory computer simulation

AU - Cruz-Torres, A.

AU - De, F.

AU - Ortíz-López, J.

AU - Arellano, J. S.

PY - 2010/11/5

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N2 - Ab initio density functional calculations were performed for a toroidal carbon C120 nanostructure. Hydrogen molecules, n = 1-15, were added inside the nanotorus and for each one of these systems a geometry optimization was obtained. The cohesive energy shows that these structures are energetically stable. For example, the binding energies are -34.95 and -36.19 Hartrees and the interatomic distances H-H are 0.753 and 0.772 Å for 1 and 14 molecules, respectively. Considering only molecular hydrogen, we have always seen so far weak physisorption into the C120 nanotorus. There is no chemisorption until the number oh hydrogen molecules are increased to 14. In this case, four hydrogen atoms are chemisorbed. With 15 molecules, there are 10 hydrogen atoms chemisorbed just at the inner nanotorus surface forming 10 H-C bondings with bond length close to that in methane.

AB - Ab initio density functional calculations were performed for a toroidal carbon C120 nanostructure. Hydrogen molecules, n = 1-15, were added inside the nanotorus and for each one of these systems a geometry optimization was obtained. The cohesive energy shows that these structures are energetically stable. For example, the binding energies are -34.95 and -36.19 Hartrees and the interatomic distances H-H are 0.753 and 0.772 Å for 1 and 14 molecules, respectively. Considering only molecular hydrogen, we have always seen so far weak physisorption into the C120 nanotorus. There is no chemisorption until the number oh hydrogen molecules are increased to 14. In this case, four hydrogen atoms are chemisorbed. With 15 molecules, there are 10 hydrogen atoms chemisorbed just at the inner nanotorus surface forming 10 H-C bondings with bond length close to that in methane.

KW - DFT calculations

KW - Hydrogen storage

KW - Toroidal carbon nanostructure

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Hydrogen storage inside a toroidal carbon nanostructure C₁₂₀: Density functional theory computer simulation

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Keywords

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