Three-dimensional solar-energy-driven hydrogen generation from ammonia. This project aims to address the challenges of hydrogen generation, transportation and storage by conceptualising a novel three-dimensional, solar-driven system for ammonia splitting on ultralight catalyst materials. The project expects to generate new knowledge in the area of advanced materials enabled hydrogen technologies through interdisciplinary approaches involving materials science, novel catalysis, and nanotechnology ....Three-dimensional solar-energy-driven hydrogen generation from ammonia. This project aims to address the challenges of hydrogen generation, transportation and storage by conceptualising a novel three-dimensional, solar-driven system for ammonia splitting on ultralight catalyst materials. The project expects to generate new knowledge in the area of advanced materials enabled hydrogen technologies through interdisciplinary approaches involving materials science, novel catalysis, and nanotechnology. Expected outcomes include new catalyst materials, design strategies, and advanced ammonia splitting technologies. This should provide significant benefits, such as newly created knowledge, technological innovation, research training, contributing to hydrogen economy and net zero for a greener environment.Read moreRead less
Integrated nonmetal-metal single-atom catalysis for selective synthesis. Single atom catalysts can achieve the maximum efficiency of active sites for a reaction. This project will develop integrated nonmetal and metal single atom-based catalysts for selective oxidation towards clean production and organic waste conversion to value-added polymers for carbon recycle. The project will result in new functional materials and green catalytic processes for chemical synthesis and waste reduction, and ad ....Integrated nonmetal-metal single-atom catalysis for selective synthesis. Single atom catalysts can achieve the maximum efficiency of active sites for a reaction. This project will develop integrated nonmetal and metal single atom-based catalysts for selective oxidation towards clean production and organic waste conversion to value-added polymers for carbon recycle. The project will result in new functional materials and green catalytic processes for chemical synthesis and waste reduction, and advance fundamental understanding of molecular structure of materials for catalyst design and process engineering for industrial applications. The outcomes will promote the development of chemical industry, waste recycle and green environment in Australia, making significant benefits to economics and society.Read moreRead less
CO2-coupled photothermal catalysis on superlattice structures. This project aims to develop a structure-tailored platform of superlattice materials for photothermal catalytic conversion of natural gases to valuable fuels and chemicals. Innovations lie in engineered atomic and bulk scale nanocrystals for high-efficiency sunlight harvesting to drive CO2-coupled catalysis of C-H bond activation. Advanced characterisations and multiscale computations will enable mechanistic insights into the synergy ....CO2-coupled photothermal catalysis on superlattice structures. This project aims to develop a structure-tailored platform of superlattice materials for photothermal catalytic conversion of natural gases to valuable fuels and chemicals. Innovations lie in engineered atomic and bulk scale nanocrystals for high-efficiency sunlight harvesting to drive CO2-coupled catalysis of C-H bond activation. Advanced characterisations and multiscale computations will enable mechanistic insights into the synergy of photo and thermal catalysis in hydrocarbon conversions. The projects will result in next-generation intelligent materials and clean technologies for solar fuels production and CO2 recycling. Outcomes will benefit Australia’s long-term energy security and sustainability toward a carbon-neutral society. Read moreRead less
Engineered redox polymers for catalytic water purification. This project aims to develop a novel family of chemically and structurally controlled redox polymer as metal-free catalysts for wastewater micropollutant treatment. Innovations lie in the synthesis of high-performance and nanostructured carbon-based materials, multiscale modeling, and in situ characterizations for understanding structure-property relationship in carbon catalysis. Expected outcomes will deliver innovations in functional ....Engineered redox polymers for catalytic water purification. This project aims to develop a novel family of chemically and structurally controlled redox polymer as metal-free catalysts for wastewater micropollutant treatment. Innovations lie in the synthesis of high-performance and nanostructured carbon-based materials, multiscale modeling, and in situ characterizations for understanding structure-property relationship in carbon catalysis. Expected outcomes will deliver innovations in functional materials, mechanism, catalytic engineering, and sustainable separation processes. This project will provide significant benefits in renovating smart nanomaterials in advanced manufacturing and clean environmental technologies, promoting Australia’s economic development and environment protection.Read moreRead less
ARC Centre of Excellence for Green Electrochemical Transformation of Carbon Dioxide. ARC Centre of Excellence for Green Electrochemical Transformation of Carbon Dioxide. This Centre aims to advance carbon dioxide electrochemistry innovations to enable the conversion of carbon dioxide into valuable products and transition Australia to a carbon-neutral economy. This Centre expects to generate new knowledge using experimental and computational approaches to develop systems-level understanding to fu ....ARC Centre of Excellence for Green Electrochemical Transformation of Carbon Dioxide. ARC Centre of Excellence for Green Electrochemical Transformation of Carbon Dioxide. This Centre aims to advance carbon dioxide electrochemistry innovations to enable the conversion of carbon dioxide into valuable products and transition Australia to a carbon-neutral economy. This Centre expects to generate new knowledge using experimental and computational approaches to develop systems-level understanding to furnish industry-ready carbon dioxide utilisation technologies. Expected outcomes include enhanced capacity through collaborations establishing the Centre as an international hub for research, training, technology translation and strategic advice for stakeholders and policymakers. This should accelerate Australia’s progress towards net zero emissions targets and grow a sustainable economy and create future jobs.Read moreRead less