Hydrogen photoelectrochemical generation

Bockris JO M, Uosald K (1977) The rate of the photoelectrochemical generation of hydrogen at p-type semiconductors. J Electrochem Soc 124 1348-1355... 

Satsangi VR, Kumari K, Singh AP et al (2008) Nanostructured hematite for photoelectrochemical generation of hydrogen. Int J Hydrogen Energy 33 312-318... 

Solar Photoelectrochemical Generation of Hydrogen Fuel J55 Visible light flux... 

Dominey RN, Lewis NS, Bruce JA, Bookbinder DC, Wrighton MS (1982) Improvement of photoelectrochemical hydrogen generation by surface modification of p-type silicon semiconductor photo-cathodes. J Am Chem Soc 104 467 82... 

Jahagirdar, A.H. and Dhere, N.G., Photoelectrochemical water splitting using CuInj j.Gaj.S2/ CdS thin film solar cells for hydrogen generation, Solar Energ. Mater. Solar Cells, 91, 1488, 2007. 

Bak, T., Nowotny, J., Rekas, M., Sorrell, C.C. 2002. Photoelectrochemical hydrogen generation from water using solar energy materials-related aspects. Int J Hydrogen Energy 27 991-1022. 

Photoelectrochemical hydrogen generation from water using solar energy. Materials-related aspects. Int J Hydrogen Chem 991-1022... 

ZnS-CdS (bandgap = 2.3-2.4 eV) composite semiconductor photoelectrodes show a broad spectral response and n-type behavior, with saturation of the anodic photocurrent upon increasing anodic potential making the system suitable for use as a photoelectrochemical cell photoanode [72], Nanostructured ZnS-CdS thin film electrodes show that anodic photocurrent saturation can be attained with the application of a small, 0.1 V, bias [73], while hydrogen evolution is observed at the Pt cathode. The performance of the ZnS-CdS photoanodes appear strongly dependent upon the method of film preparation [72,73], with Zn rich films demonstrating superior photocurrent generation, and stability, in comparison to Cd rich films. 

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