ENERGETICS OF SEMICONDUCTOR ELECTRODE SOLUTION INTERFACES - EQCM EVIDENCE FOR CHARGE-COMPENSATING CATION ADSORPTION AND INTERCALATION DURING ACCUMULATION LAYER FORMATION IN THE TITANIUM-DIOXIDE ACETONITRILE SYSTEM

Combined reflectance, electrochemical quartz crystal microbalance, and conventional voltammetric measurements on high-area titanium dioxide electrodes in dry, electrolyte-containing solutions of acetonitrile sh ow that electron accumulation layer formation is coupled directly to i ntercalation (e.g., Li+ or Na+) or to reversible adsorption (tetrabuty lammonium ion) of charge compensating cations. Difficulty in achieving intercalation with these ions appears to account for the extreme nega tive shift of the flatband potential in acetonitrile, in comparison to aqueous solutions. More generally, the charge compensation based adso rption/intercalation phenomenon appears to play a key role in defining the conduction band edge energetics of titanium dioxide (and presumab ly other metal oxides) in solution environments.