Energy-efficient liquid-flow system for electroreduction of carbon dioxide. Concerns about fossil fuel depletion and rising carbon emissions have brought about an urgent demand for carbon dioxide (CO2) capture and utilisation technologies. Facilitated by the mechanism-driven catalyst development and engineering innovation, this project aims to deliver a durable and cost-effective approach to electrochemical transformation of CO2 into the valuable products. The proposed automatic liquid-flow reac ....Energy-efficient liquid-flow system for electroreduction of carbon dioxide. Concerns about fossil fuel depletion and rising carbon emissions have brought about an urgent demand for carbon dioxide (CO2) capture and utilisation technologies. Facilitated by the mechanism-driven catalyst development and engineering innovation, this project aims to deliver a durable and cost-effective approach to electrochemical transformation of CO2 into the valuable products. The proposed automatic liquid-flow reactor system is expected to enable an energy efficient and practical viable CO2 reduction in benign aqueous electrolytes. The resulting innovations will not only reduce the environmental impact of atmospheric CO2 but also generate highly concentrated industrial feedstocks for the sustainable production of commodity chemicals.Read moreRead less
Efficient and selective water electrolysis for clean energy and environment. This project aims to develop an anion exchange membrane electrolysis cell for efficient co-generation of hydrogen and hydrogen peroxide from the splitting of water by coupling the hydrogen evolution reaction with a selective, two-electron water oxidation reaction catalysed by cost-effective, perovskite materials. This project expects to generate new knowledge in understanding the selective water electrolysis and in deve ....Efficient and selective water electrolysis for clean energy and environment. This project aims to develop an anion exchange membrane electrolysis cell for efficient co-generation of hydrogen and hydrogen peroxide from the splitting of water by coupling the hydrogen evolution reaction with a selective, two-electron water oxidation reaction catalysed by cost-effective, perovskite materials. This project expects to generate new knowledge in understanding the selective water electrolysis and in developing efficient energy conversion technologies. This project is expected to improve the utilisation of renewable energy and promote development of manufacturing and chemical industries in Australia. This should provide significant benefits to achieve energy safety and environmental sustainability for Australia.Read moreRead less