DFT-D study of adsorption of diaminoethane and propylamine molecules on anatase (101) TiO2 surface

•The adsorption of diaminoethane and propylamine on anatase (101)was studied with DFT-D.•The mechanism of formation of the monolayer was characterized.•Born Opernheimer Molecular Dynamics simulations was performed at 298K for a full layer of DAE. The adsorption on anatase (101) TiO2 surface of two m...

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Bibliographic Details
Published inApplied surface science Vol. 426; pp. 107 - 115
Main Authors Hemeryck, A., Motta, A., Lacaze-Dufaure, C., Costa, D., Marcus, P.
Format Journal Article
LanguageEnglish
Published Elsevier B.V 31.12.2017
Subjects
Adhesion
Amine
Cohesive film
DFT-D
Diaminoethane
Propylamine
TiO2
Diaminoethane
Amine
DFT-D
Adhesion
Propylamine
Cohesive film
TiO2
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Summary:•The adsorption of diaminoethane and propylamine on anatase (101)was studied with DFT-D.•The mechanism of formation of the monolayer was characterized.•Born Opernheimer Molecular Dynamics simulations was performed at 298K for a full layer of DAE. The adsorption on anatase (101) TiO2 surface of two model amines, diaminoethane (DAE) and propylamine (PPA), was investigated using Density Functional Theory-Dispersion included (DFT-D) calculations. The investigated coverage is ranging from 0.25 monolayer to full coverage (one amine molecule per surface Ti ion). Both interactions of the adsorbed layer with the anatase (101) TiO2 surface and intermolecular interactions are described. A structural transition from a bridge to a perpendicular structure is found for DAE when evolving from 0.25 monolayer to full coverage. At full coverage, a dense, ordered adhesive layer is formed. For DAE, at intermediate coverage, different isoenergetic configurations are found and structural transition from a bridge to a perpendicular structure is found. In contrast, the adsorption mode of PPA is more regular with only perpendicularly adsorbed molecules at all investigated coverages. Dispersion forces already account for 40% of the adsorption energy at low coverage (0.25 ML) and are the driving force for monolayer formation with a contribution of 60% up to 100% at high coverage. As revealed by molecular dynamics, the molecules can change their orientation towards the surface in a concerted way.
ISSN:0169-4332
1873-5584
DOI:10.1016/j.apsusc.2017.07.161