Adsorption properties of fission gases Xe and Kr on pristine and doped graphene: A first principle DFT study

Adsorption properties of fission gases Xe and Kr on pristine and doped graphene: A first principle DFT study

Graphene has excellent adsorption properties due to large surface area and has been used in applications related to gas sorption and separation. The separation of radioactive noble gases using graphene is an interesting area of research relevant to nuclear waste management. Radioactive noble gases X...

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Bibliographic Details
Published in:Journal of nuclear materials Vol. 490; pp. 174 - 180
Main Authors: Vazhappilly, Tijo, Ghanty, Tapan K., Jagatap, B.N.
Format: Journal Article
Language:English
Published: Elsevier B.V 01-07-2017
Subjects:
Binding energy
Density functional theory
Doped graphene
Noble gas adsorption
Nuclear waste management
Doped graphene
Nuclear waste management
Density functional theory
Noble gas adsorption
Binding energy
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Summary:Graphene has excellent adsorption properties due to large surface area and has been used in applications related to gas sorption and separation. The separation of radioactive noble gases using graphene is an interesting area of research relevant to nuclear waste management. Radioactive noble gases Xe and Kr are present in the off-gas streams from nuclear fission reactors and spent nuclear fuel reprocessing plants. The entrapment of these volatile fission gases is important in the context of nuclear safety. The separation of Xe from Kr is extremely difficult, and energy intensive cryogenic distillation is generally employed. Physisorption based separation techniques using porous materials is a cost effective alternative to expensive cryogenic distillation. Thus, adsorption of noble gases on graphene is relevant for fundamental understanding of physisorption process. The properties of graphene can be tuned by doping and incorporation of defects. In this regard, we study the binding affinity of Xe and Kr in pristine and doped graphene sheets. We employ first principle calculations using density functional theory, corrected for dispersion interactions. The structural parameters obtained from the current study show excellent agreement with the available theoretical and experimental observations on similar systems. Noble gas adsorption energies on pristine graphene match very well with the available literature. Our results show that the binding energy of fission gases Xe and Kr on graphene can be considerably improved through doping the lattice with a heteroatom. The adsorption of radioactive fission gases Xe and Kr on pristine/doped graphene is an interesting topic in the context of nuclear waste management. Previous experimental and computational studies about Xe/Kr adsorption on graphene were limited to only on pristine graphene. The doping by hetero atom changes the electronic properties of graphene and creates active sites in the lattice. Based on first principle calculations, we suggest specific doped graphenes for efficient sorption of noble gases. [Display omitted]
ISSN:0022-3115
1873-4820
DOI:10.1016/j.jnucmat.2017.04.017