Electrochemical synthesis of Sb2Se3 modified with cobalt and co-catalyst for solar water splitting

Abstract

The search for a safe, clean and abundant energy source is one of the greatest scientific challenges of the 21st century. Therefore, the use of solar energy is a promising alternative to make sustainable use of carbon-free energy. This allows us to investigate ways that use solar energy in photoelectrocatalysis processes in the production of hydrogen gas through solar water splitting. The use of thin films of Sb2Se3 in photovoltaic and photoelectrochemical applications has been a new alternative for semiconductor materials as it presents adequate optical bandgap energy between 1.10 - 1.17 eV and high absorption coefficient in ultraviolet and visible (± = > 105 cm-1) compared to other commonly used absorbers. Furthermore, its obtaining by electrochemical methods is a good alternative for manufacturing a highly promising semiconductor using versatile techniques, with low energy consumption and easy handling. To improve the photoelectrocatalytic properties of thin films, doping is a technique often used to influence material properties. Since cobalt is a corrosion resistant transition metal and good thermal and electrical conductor, it becomes a good alternative to modify Sb2Se3 films with cobalt ions to improve its catalytic properties for solar water splitting in hydrogen production. To complete the device, it is necessary the presence of co-catalysts for hydrogen evolution reaction, such as Pt or a-MoSx, to improve kinetic factors and reduce photocorrosion effects. Therefore, this project aims to manufacture a device of the FTO/Co:Sb2Se3/co-catalyst type by simplified electrodeposition methods so that an efficient and durable system can be obtained through the hydrogen release reaction. (AU)