Interaction of organic pollutants with TiO2: a density functional theory study of carboxylic acids on the anatase (101) surface

Understanding the interaction of the carboxylic group with TiO2 is crucial for photocatalytic degradation of pollutants, because aromatic molecules containing carboxylic acid groups are among the most common micropollutants. This study investigated the interactions of the anatase TiO2 (101) surface with several aromatic carboxylic acids: benzoic, nicotinic, salicylic and anthranilic acid, using dispersion-corrected density functional theory (DFT) calculations. For all the molecules studied, we found higher stabilities of monodentate adsorbed configurations over bidentate. Dispersion was found to have a significant effect on adsorption energies. In particular, dispersion gave rise to a tilted monodentate adsorption configuration, where adsorption through interfacial covalent and hydrogen bonds was additionally stabilised by dispersion interactions of the aromatic ring with the surface. Comparative calculations using DFT with empirical dispersion correction and van der Waals-corrected functionals found the relative stabilities of adsorbed structures to be independent of the method of describing dispersion. Thermodynamic probabilities of different adsorption configurations were evaluated using the Boltzmann distribution, and the tilted dispersion-stabilised structures were predicted to be by far the most abundant. Finally, the optical absorption of TiO2-acid systems was modelled, and TiO2-aromatic acid complexes were found to have their optical absorption extended into the visible range.

Automated summary

Understanding the interaction between carboxylic groups and TiO2 is crucial for photocatalytic degradation of pollutants. This study used density functional theory (DFT) calculations to investigate the interaction of several aromatic carboxylic acids with the TiO2 (101) surface. Monodentate adsorbed configurations were found to be more stable than bidentate for all the molecules studied. Dispersion interactions were found to have a significant effect on adsorption energies, stabilizing the tilted monodentate adsorption configuration. Thermodynamic probabilities indicated that the dispersion-stabilized structures were the most abundant. Additionally, the optical absorption of TiO2-acid complexes was found to extend into the visible range.