Development of solar
fuels photoanodes through combinatorial integration of Ni — La — Co — Ce oxide catalysts on BiVO4.
Solar
Fuels Photoanodes Prepared by Inkjet Printing of Copper Vanadates P. Newhouse, D. Boyd, A. Shinde, D. Guevarra, L. Zhou, E. Soedarmadji, G. Li, J. B. Neaton, and J. M. Gregoire
Development of solar
fuels photoanodes through combinatorial integration of Ni - La - Co-Ce oxide and Ni - Fe - Co-Ce oxide catalysts on BiVO4.
Joel A. Haber, «Development of Solar
Fuels Photoanodes through Combinatorial Integration of Ni - La - Co-Ce Oxide and Ni - Fe - Co-Ce Oxide Catalysts on BiVO4»
Development of Solar
Fuels Photoanodes through Combinatorial Integration of Ni - La - Co-Ce and Ni - Fe - Co-Ce Oxide Catalysts on BiVO4.
Discovery of Solar
Fuels Photoanode Materials by Integrating High - Throughput Theory and Experiment.
The poor stability of most semiconductors in the highly oxidizing environment of a solar
fuels photoanode has been a key factor limiting the use of many candidates light absorbers.
Combining high throughput experimentation with theory enabled discovery of a unique solar
fuels photoanode with remarkable stability.
Not exact matches
«The job of the
photoanode is to absorb sunlight and then use that energy to oxidize water — essentially splitting apart the H2O molecule and rearranging the atoms to form a
fuel.
The final product, Gregoire said, would look something like a solar panel and involve three components: the
photoanode, a photocathode, which forms the
fuel, and a membrane that separates the two.
Dr. Ager's research interests include the fundamental electronic and transport characteristics of photovoltaic materials, development of new
photoanodes and photocathodes based on abundant elements for solar
fuels production, and the development of new oxide - and sulfide - based transparent conductors.