The fabrication of thin-film Fe(2)O(3) photoanodes from the spray pyrolysis of Fe(III)-containing solutions is reported along with their structural characterization and application to the photoelectrolysis of water. These films combine good performance, measured in terms of photocurrent density, with excellent mechanical stability. A full investigation into the effects that modifications of the spray-pyrolysis method, such as the addition of dopants or structure-directing agents and changes in precursor species or carrier solvent, have on the performance of the photoanodes has been realized. The largest photocurrents were obtained from photoanodes prepared from ferric chloride precursor solutions, simultaneously doped with Ti(4+) (5%) and Al(3+) (1%). Doping with Zn(2+) also shows promise, cathodically shifting the onset potential by approximately 0.22 V.
Nanostructuring of semiconductor films offers the potential means for producing photoelectrodes with improved minority charge carrier collection. Crucial to the effective operation of the photoelectrode is also the choice of a suitable electrolyte. The behaviour of the nanostructured WO(3) photoanodes in methane sulfonic acid solutions, which allow one to obtain large, perfectly stable visible-light driven water splitting photocurrents, is discussed. The important effect of the electrolyte concentration upon the current distribution and the related photocurrent losses within the nanoporous photoelectrodes is pointed out.
Solar-to-hydrogen photoelectrochemical
cells (PECs) have been proposed
as a means of converting sunlight into H2 fuel. However,
in traditional PECs, the oxygen evolution reaction and the hydrogen
evolution reaction are coupled, and so the rate of both of these is
limited by the photocurrents that can be generated from the solar
flux. This in turn leads to slow rates of gas evolution that favor
crossover of H2 into the O2 stream and vice
versa, even through ostensibly impermeable membranes such as Nafion.
Herein, we show that the use of the electron-coupled-proton buffer
(ECPB) H3PMo12O40 allows solar-driven
O2 evolution from water to proceed at rates of over 1 mA
cm–2 on WO3 photoanodes without the need
for any additional electrochemical bias. No H2 is produced
in the PEC, and instead H3PMo12O40 is reduced to H5PMo12O40. If the
reduced ECPB is subjected to a separate electrochemical reoxidation,
then H2 is produced with full overall Faradaic efficiency.
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