NANO-SCALE CATALYST SYSTEMS FOR HYDROGEN GENERATION FOR FUEL CELLS. The project aims to develop nano-scale catalyst materials for micro-channel fuel processing systems. Micro-channel reactors have the benefits over conventional technology of being more compact and potential for much lower costs. This will assist in the development of hydrogen generation systems for fuel cells, as well as other chemical processing applications such as gas-to-liquids technology. The technology has the potential t ....NANO-SCALE CATALYST SYSTEMS FOR HYDROGEN GENERATION FOR FUEL CELLS. The project aims to develop nano-scale catalyst materials for micro-channel fuel processing systems. Micro-channel reactors have the benefits over conventional technology of being more compact and potential for much lower costs. This will assist in the development of hydrogen generation systems for fuel cells, as well as other chemical processing applications such as gas-to-liquids technology. The technology has the potential to generate significant IP in an evolving multi-billion dollar fuel cell industry. Support from Ceramic Fuel Cells Ltd. and the Gas Technology Institute will ensure that the work has an international as well as national perspective, and a route to exploitation.Read moreRead less
Nanostructured Carbon Electrodes. The development of higher capacity energy storage devices is critical to the efficient use of energy. The fundamental knowledge gained in this project will enable the production of the next generation advanced electrode materials for this purpose and hence provide many new commercial opportunities for Australian industry. The project brings together world leaders in their own fields to address a highly multidisciplinary area of research and will provide an excel ....Nanostructured Carbon Electrodes. The development of higher capacity energy storage devices is critical to the efficient use of energy. The fundamental knowledge gained in this project will enable the production of the next generation advanced electrode materials for this purpose and hence provide many new commercial opportunities for Australian industry. The project brings together world leaders in their own fields to address a highly multidisciplinary area of research and will provide an excellent training for PhD students and post doctoral Research Fellows, enabling them to work in and contribute to the development of new nanotechnology industries in Australia.Read moreRead less
Nano- and micro-scale engineering of MoS2-based catalyst for conversion of syngas to ethanol. Domestic production of ethanol to provide a 10% blend in petrol (E10) can be achieved from waste methane gas that Australia currently vents or flares to atmosphere. This project aims to develop a conversion process for making ethanol from syngas (the product of coal or methane gasification). Small scale, modularised plants would make ethanol locally to the methane emission source. The benefits of local ....Nano- and micro-scale engineering of MoS2-based catalyst for conversion of syngas to ethanol. Domestic production of ethanol to provide a 10% blend in petrol (E10) can be achieved from waste methane gas that Australia currently vents or flares to atmosphere. This project aims to develop a conversion process for making ethanol from syngas (the product of coal or methane gasification). Small scale, modularised plants would make ethanol locally to the methane emission source. The benefits of local E10 production would be a reduction in the oil trade deficit of $1 billion per year, $500 million per year in lower carbon imposts to industry and government, 25 million tonnes per year of reduced CO2e release to atmosphere and significantly improved urban air through reduced emissions from car transport, with attendant human health benefits.Read moreRead less