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First-principles study of molecule adsorption on Ni-decorated monolayer MoS2

Barzegar, M ; Sharif University of Technology | 2019

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  1. Type of Document: Article
  2. DOI: 10.1007/s10825-019-01359-7
  3. Publisher: Springer New York LLC , 2019
  4. Abstract:
  5. The interactions between four different gas molecules (methanol, o-xylene, p-xylene and m-xylene) and Ni-decorated monolayer MoS2 were investigated by means of density functional computations to exploit its potential application as a gas sensor. The electronic properties of the Ni-decorated monolayer MoS2 and gas molecule (adsorbent–adsorbate properties) strongly depend on the Ni-decorated monolayer MoS2 structure and the molecular configuration of the adsorbate. The adsorption properties of volatile organic compound (VOC) molecules on Ni-decorated MoS2 has been studied taking into account the parameters such as adsorption energy, energy bandgap, density of states, and Mulliken charge transfer. All three xylene isomers showed considerably stronger adsorption on the Ni-decorated monolayer MoS2 than the methanol. Among them, p-xylene was found to have the highest adsorption energy and charge transfer value in interaction with the Ni-decorated monolayer MoS2. The adsorption energy shows a significant improvement after nickel decoration for xylene adsorption. Therefore, the adsorption of xylene vapor on Ni-decorated monolayer MoS2 was found to be favorable comparing to other VOC molecules. © 2019, Springer Science+Business Media, LLC, part of Springer Nature
  6. Keywords:
  7. Methanol ; MoS2 monolayer ; Ni-decorated MoS2 ; Xylene ; Charge transfer ; Density functional theory ; Electronic properties ; Gas adsorption ; Isomers ; Layered semiconductors ; Molecules ; Molybdenum compounds ; Monolayers ; Volatile organic compounds ; Adsorption energies ; Adsorption properties ; Density function theory ; Density functional computations ; First-principles study ; Molecular configurations ; Molecule adsorptions ; Volatile organic compound (VOC) ; Nickel compounds
  8. Source: Journal of Computational Electronics ; Volume 18, Issue 3 , 2019 , Pages 826-835 ; 15698025 (ISSN)
  9. URL: https://link.springer.com/article/10.1007/s10825-019-01359-7