posted on 2015-05-13, 00:00authored byJacob
T. Hyde, Kenneth Hanson, Aaron K. Vannucci, Alexander M. Lapides, Leila Alibabaei, Michael R. Norris, Thomas J. Meyer, Daniel P. Harrison
The oxidative stability of the molecular
components of dye-sensitized photoelectrosynthesis cells for solar
water splitting remains to be explored systematically. We report here
the results of an electrochemical study on the oxidative stability
of ruthenium(II) polypyridyl complexes surface-bound to fluorine-doped
tin oxide electrodes in acidic solutions and, to a lesser extent,
as a function of pH and solvent with electrochemical monitoring. Desorption
occurs for the Ru(II) forms of the surface-bound complexes with oxidation
to Ru(III) enhancing both desorption and decomposition. Based on the
results of long-term potential hold experiments with cyclic voltammetry
monitoring, electrochemical oxidation to Ru(III) results in slow decomposition
of the complex by 2,2′-bipyridine ligand loss and aquation
and/or anation. A similar pattern of ligand loss was also observed
for a known chromophore–catalyst assembly for both electrochemical
water oxidation and photoelectrochemical water splitting. Our results
are significant in identifying the importance of enhancing chromophore
stability, or at least transient stability, in oxidized forms in order
to achieve stable performance in aqueous environments in photoelectrochemical
devices.