This thesis presents a study of hydrogen evolution electrocatalyst for alkaline water electrolysis. Hydrogen production through the electrolysis of water requires the development of new electrocatalysts in order to reduce the hydrogen evolution over-potential of the cathode in order to make water electrolysis more competitive and efficient. An alternative approach in the optimisation of water splitting electrocatalyst may Be the modification of the metal electrocatalytic behaviour by supporting nano-particles on oxide support. Development of the electrocatalyst material for hydrogen evolution reaction in alkaline electrolyte may obtain more stable hydrogen evolution reaction.

Pt on TiO₂ electrocatalyst has been synthesized by applying high throughput Physical Vapor Deposition (HT PVD) method. Electrochemistry measurements of Pt on TiO₂ have been used to study the characteristic and stability of the electrocatalyst for hydrogen evolution reaction in alkaline electrolyte for water electrolysis. XRD confirmed that the phase of TiO₂ were amorphous and anatase after annealing for 6 hours at the temperature of 450^oC. The thicknesses of TiO₂ both for amorphous and anatase were 200 nm.

Similar electrocatalytic behavior are presented both for Pt on amorpous TiO₂ and Pt on anatase TiO₂ from electrochemistry measurements using cyclic voltammetry and potential step on the 10 x 10 E-chem arrays in alkaline electrolyte (0.5 M NaOH). Higher currents are seen in the larger particle size of platinum in TiO₂ both for amorphous and anatase phase. The hydrogen evolution reaction starts at the potential below -0.8 V vs RHE. The potential for hydrogen evolution reaction is shifted to the low potential. Larger particle size of platinum shows lower potential of hydrogen evolution reaction.

Al-Odail, F. A., Anastasopoulos, A., Hayden, B. E., 2010, Phys. Chem. Chem. Phys., 12, 11398.

Bamwenda, G. R., Tsubota,S., Nakamura, T. and Haruta, M., 1997, Catal. Lett., 44, 83.

Galinska, A. and Walendziewski, J., 2005, Energ. Fuel, 19, 1143.

Guerin, S., Hayden, B. E., 2006, J. Comb. Chem., 8, 66.

Guerin, S., Hayden, B. E., Lee, C. E., Mormiche, C., Owen, J. R.,

Russell, A. E., 2004, J. Comb. Chem., 6, 149.

Guerin, S., Hayden, B. E., Lee, C. E., Mormiche, C., Russell, A. E., 2006, J. Phys. Chem. B., 110, 14355.

Guerin, S., Hayden, B. E., Pletcher, D., Rendall, M. E., Suchsland, J., 2006, J. Comb. Chem., 8, 679.

Guerin, S., Hayden, B. E., Pletcher, D., Rendal, M. E., Suchsland, J., Williams, L., 2006, J. Comb. Chem., 8, 791.

Kaninski, M. P. M., Saponjic, D. P., Perovic, I. M., Maksic, A. D., Nikolic, V.M., 2011, Appl. Catal. A: Gen., 405, 29.

Kruger, P., 2000, J. Hydrogen Energ., 25, 395.

Lee, K., Nam, W. S., Han, G. Y., 2004, Int. J. Hydrogen Energ., 29, 1343.

Macsic, A. D., Miulovic, S. M., Nikolic, V. M., Perovic, I. M., Kaninski, M. P. M., 2011, Appl. Catal. A: Gen., 405, 25.

Ni, M., Leung, M. K. H, Leung, D. Y. C., Sumathy, K., 2007, Renew. Sust. Energ. Rev., 11, 401.

Nikolic, V. M., Tasic, G. S., Maksic, A. D., Saponjic, D. P., Miulovic, S. M., Kaninski, M. P. M., 2010, Int. J. Hyd. Energ., 35, 12369.

Noel, M., Vasu, K. I., Cyclic 1990, Voltammetry and the Frontiers of Electrochemistry, Aspect Publications, London.

Park, J. H., Kim, S., Bard, A. J., 2006, Nano. Lett., 6, 24.

Reddington, E., Sapienza, A., Gurau, B., Viswanathan, R., Sarangapani, S., Smotkin, E. S., Mallouk, T. E., 1998, Science, 280, 1735.

Yazici, B., 1999, Turk. J. Chem., 23, 301.