SnO2, IrO2, Ta^sub 2^O^sub 5^, Bi^sub 2^O3, and TiO2 nanoparticle anodes: electrochemical oxidation coupled with the cathodic reduction of water to yield molecular H2

In recent years, the search for environmentally friendly alternative energy sources with reduced carbon footprints has increased. The coupling of photovoltaic power sources with advanced electrolysis systems for hydrogen production via water splitting using organic contaminants as sacrificial electr...

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Bibliographic Details
Published in:Journal of nanoparticle research : an interdisciplinary forum for nanoscale science and technology 2012-08, Vol.14 (8), p.1
Main Authors: Choi, Jina, Qu, Yan, Hoffmann, Michael R
Format: Article
Language:English
Subjects:
Alternative energy sources
Anodes
Carbon footprint
Chemical pollution
Electrochemistry
Electrolysis
Hydrogen production
Manufacturing industry
Nanoparticles
Organic contaminants
Oxidation
Phenols
Photovoltaics
Seawater
Sodium chloride
Titanium dioxide
Wastewater oxidation
Water pollution
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Summary:In recent years, the search for environmentally friendly alternative energy sources with reduced carbon footprints has increased. The coupling of photovoltaic power sources with advanced electrolysis systems for hydrogen production via water splitting using organic contaminants as sacrificial electron donors has been considered to a be viable alternative. In this report, we demonstrated the feasibility of a scaled-up rooftop prototype of the proposed hybrid photovoltaic-electrolysis system, which utilizes semiconductor nanoparticles coated on to metal substrates as electrodes for the generation of hydrogen coupled with the oxidation of wastewater. Application of an anodic bias of >2.0 V to bismuth-doped TiO2 (BiO^sub x^-TiO2) on Ti metal anodes with a sequential under-coatings of nanoparticulate SnO2, IrO2, Ta^sub 2^O^sub 5^, and Bi^sub 2^O3 results in the electrochemical degradation of a variety of organic chemical contaminants in water (i.e., rhodamine B (Rh.B), methylene blue (MB), salicylic acid, triclosan, and phenol) and actual wastewater from a chemical manufacturing plant, while at the same time, molecular hydrogen is produced at stainless steel (SS) cathodes. The kinetics of the anodic substrates oxidation is investigated as a function of the cell current (I ^sub cell^), substrate concentration, and background electrolyte composition (e.g., NaCl, Na^sub 2^SO^sub 4^, or seawater). Average current efficiencies were found to be in the range of 4-22 %, while the cathodic current and energy efficiencies for hydrogen production were found to be in the range of 50-70 % and 20-40 %, respectively.[PUBLICATION ABSTRACT]
ISSN:1388-0764
1572-896X
DOI:10.1007/s11051-012-0983-5