posted on 2021-07-15, 16:25authored byGongyao Zeng, Bo Wen, Annabella Selloni
The
interactions of carboxylic acids and water with TiO2 surfaces
are important in applications ranging from solar cells
to biomedical devices. Here we focus on the aqueous interface with
the minority (001) surface of anatase TiO2 (A-001) and
the behavior of adsorbed formic and acetic acid monolayers at this
interface. We investigated the structure and stability of the pristine
reconstructed and formic/acetic acid covered A-001 surfaces in contact
with water using density functional theory (DFT) calculations and
ab initio molecular dynamics (AIMD) simulations. The (1 × 4)
reconstruction of the pristine surface is found to be stable in aqueous
environment, within the time scale of our simulation. Carboxylic acids
adsorb in deprotonated bidentate (BD) form on A-001, with the dissociated
proton transferred to a surface oxygen to form a bridging hydroxyl.
Of the two possible configurations, BD bridging and BD straddling,
of the adsorbed species, the latter is found to rapidly transform
to a monodentate structure during our simulations. Further investigation
of mixed acetate–formate monolayers on A-001 in water indicates
that also BD bridging species can become unstable at the boundaries
between formate and acetate-covered regions, transforming to a monodentate
form that does not prevent water adsorption on the TiO2 surface.