Nanocrystalline Photodiodes: Novel Devices for Water Splitting
Lead Research Organisation:
University of Strathclyde
Department Name: Pure and Applied Chemistry
Abstract
The fossil fuel reserves of the world are rapidly diminishing and are also the prime cause for global warming. Solar energy represents a major, largely untapped energy source which could easily satisfy current and future global energy demands. Any solar energy conversion device must be inexpensive per m2, efficient and long-lasting. In this programme, novel, inorganic water-splitting systems, called macro-photocatalytic diode cells, MPCDs, utilising a range of new and established visible-light absorbing photocatalyst materials, will be developed for splitting water using sunlight in separate compartments. The latter feature is important as it will minimise, if not eliminate, the various efficiency-lowering recombination reactions associated with mixed product generation. The work programme involves a number of novel aspects including: the preparation of new nanoparticulate, crystalline photocatalyst materials, fabricating them into different novel photodiode formats and the synthesis and utilisation of new redox catalysts. The use of nanoparticulate semiconductor photocatalysts, made via continuous hydrothermal flow synthesis, CHFS, in conjunction with gel casting for robust porous supports, is a particularly important and novel advance, as too is the proposed combinatorial approach to the preparation of photocatalyst films by CVD. The project will develop a significant amount of the underpinning science required for the fabrication of the final, optimised, efficient MPCDs and include a study of the underlying reaction mechanisms, using time-resolved transient absorption spectroscopy. The proposal offers a route to achieving a step change in efficiency for energy capture from the sun and aims to deliver efficient, scalable demonstrators of the MPCD technology, suitable for development into pilot plant systems in the second phase of funding.
Organisations
Publications
Elouali S
(2010)
Photocatalytic evolution of hydrogen and oxygen from ceramic wafers of commercial titanias
in Journal of Photochemistry and Photobiology A: Chemistry
Kafizas A
(2009)
Simple method for the rapid simultaneous screening of photocatalytic activity over multiple positions of self-cleaning films.
in Physical chemistry chemical physics : PCCP
Kafizas A
(2010)
A comprehensive aerosol spray method for the rapid photocatalytic grid area analysis of semiconductor photocatalyst thin films.
in Analytica chimica acta
Mills A
(2010)
A simple, novel method for preparing an effective water oxidation catalyst.
in Chemical communications (Cambridge, England)
Mills A
(2009)
Flagging up sunburn: a printable, multicomponent, UV-indicator that warns of the approach of erythema.
in Chemical communications (Cambridge, England)
Description | We have developed photocatalyst diodes that are able to split water into hydrogen and oxygen using solar energy. we have also developed promising, new water oxidation catalysts to help enhance the solar to chemical energy conversion process. |
Exploitation Route | The results of this work benefits the solar fuels research and industrial communities by identifying a promising new water oxidation catalyst and a new approach to solar conversion of likely interest to a variety of industries. |
Sectors | Energy |
Description | The findings from this work programme were used to create a consortium of partners for a second phase programme that involved developing prototypes with industry |
First Year Of Impact | 2010 |
Sector | Energy |
Impact Types | Economic |