Water Adsorption and Oxidation
at the Co<sub>3</sub>O<sub>4</sub> (110) Surface
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Abstract
We carried
out density functional theory calculations with on-site Coulomb repulsion
U terms to study the interaction of water with the (110) surface of
the spinel cobalt oxide, Co<sub>3</sub>O<sub>4</sub>, a widely used
oxidation catalyst. This surface has two different terminations, one
positively (A) and the other negatively charged (B). Dissociative
water adsorption is preferred from low up to one monolayer coverage
on the A termination and up to half monolayer on the B termination.
On the latter, a mixed molecular and dissociated monolayer is more
stable at full coverage. The computed structures are used to investigate
the free-energy changes during water oxidation on both surface terminations.
We find that the most difficult step of the oxygen evolution reaction
is the second deprotonation to form an adsorbed O species (O*). Moreover,
the A-terminated surface is more active than the B-terminated surface.
Analysis of the surface electronic structure shows a larger density
of cobalt states near the Fermi energy on the A termination, which
stabilizes the O* species and thus reduces the overpotential