Hydrogen electrochemical production

K. Noda, N. A. Zorin, C. Nakamura, M. Miyake, I. N. Gogotov, Y. Asada, H. Akutsu, J. Miyake (1998) Langmuir-Blodgett film of hydrogenase for electrochemical hydrogen production. Thin Solid Films, 327-329 639-642... 

The US photolytic program focuses on both photo-biological and photo-electrochemical hydrogen production processes and is funded at US 2.8 million. 

J.D. Benck, Z. Chen, L.Y. Kuritzky, A.J. Forman, T.F. JaramiUo, Amorphous molybdenum sulfide catalysts for electrochemical hydrogen production insights into the origin of then-catalytic activity (ACS Catalysis, 2012), pp. 1916-1923... 

Souza, R. F., PadiUia, J. C., Goncalves, R. S., Souza, M. O., Berthelot, J. R. (2007). Electrochemical hydrogen production from water electrolysis using ionic liquid as electrolytes towards the best device. Journal of Power Sources, 164, 792—798. 

Tien HT, Chen JW (1990) Hydrogen production from water by semiconductor septum electrochemical photovoltaic cell using visible light. Int J Hydrogen Energy 15 563-568... 

Cathodic hydrogen evolution is one of the most common electrochemical reactions. It is the principal reaction in electrolytic hydrogen production, the auxiliary reaction in the production of many substances forming at the anode, such as chlorine, and a side reaction in many cathodic processes, particularly in electrohydrometallurgy. It is of considerable importance in the corrosion of metals. Its special characteristic is the fact that it can proceed in any aqueous solution particular reactants need not be added. The reverse reaction, which is the anodic ionization of molecular hydrogen, is utilized in batteries and fuel cells. 

Doenitz, W. et al., Electrochemical high temperature technology for hydrogen production or direct electricity generation, Int. ]. Hydrogen Energ., 13,283,1988. 

Fujishima, A., Kobayakawa, K., and Honda, K., Hydrogen production under sunlight with an electrochemical photocell, /. Electrochem. Soc., 122, 1487, 1975. 

Divisek J (1990) Water electrolysis in a low and medium temperature regime. In Wendt H (ed) Electrochemical hydrogen technologies - Electrochemical production and combustion of hydrogen. Elsevier, New York, pp 137-212... 

Jaramillo TE, Baeck SH, Shwarsctein AK, Choi KS, Stucky GD, McFarland EW (2005) Automatated electrochemical synthesis and photoelectrochemical characterization of Zni-xCOxO thin film for solar hydrogen production. J Comb Chem 7 264-271... 

Mathew X, Bansal A, Turner JA, Dhere R, Mathews NR, Sebastian PJ (2002) Photoelectrochemical characterization of surface modified CdTe for hydrogen production. J New Mater Electrochem Systems 5 149-157... 

Several important energy-related applications, including hydrogen production, fuel cells, and CO2 reduction, have thrust electrocatalysis into the forefront of catalysis research recently. Electrocatalysis involves several physiochemical environmental dfects, which poses substantial challenges for the theoreticians. First, there is the electric potential which can aifect the thermodynamics of the system and the kinetics of the electron transfer reactions. The electrolyte, which is usually aqueous, contains water and ions that can interact directly with a surface and charged/polar adsorbates, and indirectly with the charge in the electrode to form the electrochemical double layer, which sets up an electric field at the interface that further affects interfacial reactivity. 

Cross-cutting Hydrogen from Biomass Hydrogen production from nuclear energy Photo-electrochemical Biological and photolytic systems Hydrogen production from Boron... 

---