A defect mechanism for oxygen reduction reaction. This project aims to use defective carbon to replace expensive platinum as a catalyst for oxygen reduction reaction (ORR) in fuel cells. Defective carbons incorporating non-precious metals are better than platinum in terms of over-potential, current density and number of electron transfer. They reduce the overall fuel cell cost but their better stability and higher open voltage and power density promise huge commercial benefit. This project is ex ....A defect mechanism for oxygen reduction reaction. This project aims to use defective carbon to replace expensive platinum as a catalyst for oxygen reduction reaction (ORR) in fuel cells. Defective carbons incorporating non-precious metals are better than platinum in terms of over-potential, current density and number of electron transfer. They reduce the overall fuel cell cost but their better stability and higher open voltage and power density promise huge commercial benefit. This project is expected to be important for large-scale implementation of fuel cells.Read moreRead less
Engineering the Building Blocks of Novel Interfacial Metastable Oxide Materials. This project aims to engineer the building blocks of a new family of materials recently discovered and patented as interfacial metastable oxide (i-MOx). A key discovery is the interfacial columnar atom alignment adjacent to crystal structures, conferring the materials exceptional ionic conduction well beyond the state-of-the-art, with a broad appeal to ionic transport membranes, electrodes in fuel cells and thermal ....Engineering the Building Blocks of Novel Interfacial Metastable Oxide Materials. This project aims to engineer the building blocks of a new family of materials recently discovered and patented as interfacial metastable oxide (i-MOx). A key discovery is the interfacial columnar atom alignment adjacent to crystal structures, conferring the materials exceptional ionic conduction well beyond the state-of-the-art, with a broad appeal to ionic transport membranes, electrodes in fuel cells and thermal cycling oxygen production. Advanced characterisation techniques will be employed to fundamentally elucidate the role that the interfacial structure plays to deliver remarkable performance. The outcomes will lead to possible breakthroughs in advanced materials for emerging green energy applications.Read moreRead less
Scale up of direct carbon fuel cells. As a modern society, Australia is highly reliant on energy which is derived predominantly from coal using pulverised fuel technology with low efficiency (35-40 per cent) and high greenhouse gas emissions. This project will develop a new method for the more efficient utilisation of Australia's coals. Consequently, the power generation industry in Australia will be able to export energy in the 80 per cent efficiency range, while pure carbon dioxide can be easi ....Scale up of direct carbon fuel cells. As a modern society, Australia is highly reliant on energy which is derived predominantly from coal using pulverised fuel technology with low efficiency (35-40 per cent) and high greenhouse gas emissions. This project will develop a new method for the more efficient utilisation of Australia's coals. Consequently, the power generation industry in Australia will be able to export energy in the 80 per cent efficiency range, while pure carbon dioxide can be easily sequestrated.Read moreRead less