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The overall project objective is the development and application of combinatorial methods to discover an efficient, practical, and economically sensible material for photoelectrochemical production of hydrogen from water and sunlight. We are exploring a shift in the research paradigm from conventional serial chemical research to a combinatorial approach featuring a systematic and deliberate high-speed exploration of the composition-structure-property
relationships of new metal-oxide based solid-state aterials. By intelligent and rapid design, synthesis, and analysis of large diverse collections of potential photoelectrochemical materials in libraries we are attempting to discover new and useful energy producing materials as well as better understand fundamental mechanism and composition-structure function relationships of these materials. Since funding began in September 2001 we have remained on or ahead of
schedule for milestone completion as outlined in the monthly reports. We have designed and built several prototype systems for automated electrosynthetic deposition of metal oxides including both parallel and serial systems. We now have developed direct cathodic routes to oxides of several metals including W, Ni, Nb, Ti, Fe, Cu, Co, Mo, Zn by stabilization with several ligand types and made preliminary studies with libraries which have shown general trends.
Specific improvements in W doped with Ni, Pt, and Ru have been observed. Preliminary work on electrosynthesis of mesoporous WO3 and TiO2 films from a peroxo-stabilized electrolyte using ionic surfactants has not yet shown highly ordered materials, however, increases in photocurrent have been observed which we are attempting to explain. Finally, an important derivative of our work has been from libraries of pulsed electrodeposited Pt doped WO3 whereby a new means of creating nanoparticles has been developed which show high activity for methanol oxidation without the poisoning problems of pure Pt electrodes. |
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