Acetylene and Ethylene Adsorption on a β-Mo2C(100) Surface: A Periodic DFT Study on the Role of C- and Mo-Terminations for Bonding and Hydrogenation Reactions

Mo2C catalysts are widely used in hydrogenation reactions; however, the role of the C and Mo terminations in these catalysts is not clear. Understanding the binding of adsorbates is key for explaining the activity of Mo2C. The adsorption of acetylene and ethylene, probe molecules representing alkyne...

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Autores:
Tipo de recurso:
Fecha de publicación:
2017
Institución:
Universidad de Medellín
Repositorio:
Repositorio UDEM
Idioma:
eng
OAI Identifier:
oai:repository.udem.edu.co:11407/4284
Acceso en línea:
http://hdl.handle.net/11407/4284
Palabra clave:
Acetylene
Adsorption
Bins
Catalyst activity
Catalysts
Chemical bonds
Density functional theory
Electronic properties
Ethylene
Hydrocarbons
Lighting
Catalytic potential
Chemical equations
Ethylene adsorption
Hydrogenation reactions
Mo-terminated surface
Orthorhombic systems
Periodic density functional theory
Unsaturated hydrocarbons
Hydrogenation
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License
http://purl.org/coar/access_right/c_16ec
Description
Summary:Mo2C catalysts are widely used in hydrogenation reactions; however, the role of the C and Mo terminations in these catalysts is not clear. Understanding the binding of adsorbates is key for explaining the activity of Mo2C. The adsorption of acetylene and ethylene, probe molecules representing alkynes and olefins, respectively, was studied on a β-Mo2C(100) surface with C and Mo terminations using calculations based on periodic density functional theory. Moreover, the role of the C/Mo molar ratio was investigated to compare the catalytic potential of cubic (δ-MoC) and orthorhombic (β-Mo2C) surfaces. The geometry and electronic properties of the clean δ-MoC(001) and β-Mo2C(100) surfaces have a strong influence on the binding of unsaturated hydrocarbons. The adsorption of ethylene is weaker than that of acetylene on the surfaces of the cubic and orthorhombic systems; adsorption of the hydrocarbons was stronger on β-Mo2C(100) than on δ-MoC(001). The C termination in β-Mo2C(100) actively participates in both acetylene and ethylene adsorption and is not merely a spectator. The results of this work suggest that the β-Mo2C(100)-C surface could be the one responsible for the catalytic activity during the hydrogenation of unsaturated C≡C and C=C bonds, while the Mo-terminated surface could be poisoned or transformed by the strong adsorption of C and CHx fragments. (Chemical Equation Presented). © 2017 American Chemical Society.

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