Discovery Early Career Researcher Award - Grant ID: DE230100324
Funder
Australian Research Council
Funding Amount
$394,318.00
Summary
Cooperative Single Atom Catalysts for Zn-CO2 Batteries. This project aims to develop cooperative single-atom catalysts for efficient and selective electrocatalytic CO2 conversion and Zn-CO2 batteries. Cooperative catalysts at the single atom limit can potentially achieve enhanced electrochemical properties beyond state-of-the-art and will trigger significant theoretical and technological interests in energy conversion and storage fields. It is expected to generate new knowledge in materials scie ....Cooperative Single Atom Catalysts for Zn-CO2 Batteries. This project aims to develop cooperative single-atom catalysts for efficient and selective electrocatalytic CO2 conversion and Zn-CO2 batteries. Cooperative catalysts at the single atom limit can potentially achieve enhanced electrochemical properties beyond state-of-the-art and will trigger significant theoretical and technological interests in energy conversion and storage fields. It is expected to generate new knowledge in materials science and electrochemistry, using interdisciplinary approaches of atom-precise material engineering, in situ characterisation and full-cell optimisation. Significant economic and environmental benefits are expected from developing carbon-neutral CO2 electrolysers with low cost and high energy efficiency.Read moreRead less
Precision-engineered hybrid core-shell materials . This project aims to develop new platform technologies for making nanostructured hybrid core-shell materials with exceptionally high drug loading and programmed release. Building on this research team's recent breakthrough in the precision engineering of core-shell materials, this research will revolutionise current approaches for making drug-loaded polymer and inorganic particles. Significant outcomes will include a novel sequential nanoprecipi ....Precision-engineered hybrid core-shell materials . This project aims to develop new platform technologies for making nanostructured hybrid core-shell materials with exceptionally high drug loading and programmed release. Building on this research team's recent breakthrough in the precision engineering of core-shell materials, this research will revolutionise current approaches for making drug-loaded polymer and inorganic particles. Significant outcomes will include a novel sequential nanoprecipitation platform technology for making drug-core polymer-shell nanoparticles, and a new bio-inspired approach for making hybrid drug-core silica-shell nanocomposites, and new materials for applications in programmed release and delivery systems.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL210100050
Funder
Australian Research Council
Funding Amount
$3,263,000.00
Summary
Interfacial design and engineering for high-performance batteries. This Fellowship aims to design the next generation of batteries - for use in portable devices, electric vehicles and smart grids - that will overcome the energy density, cycle life, and safety issues, and will contribute to a more sustainable future. This comprehensive and ground-breaking research program combines experiment and theory of electrode/electrolyte interfacial behaviour with materials engineering, to develop a toolkit ....Interfacial design and engineering for high-performance batteries. This Fellowship aims to design the next generation of batteries - for use in portable devices, electric vehicles and smart grids - that will overcome the energy density, cycle life, and safety issues, and will contribute to a more sustainable future. This comprehensive and ground-breaking research program combines experiment and theory of electrode/electrolyte interfacial behaviour with materials engineering, to develop a toolkit of new battery design principles. The program expects to deliver high energy-density batteries with outstanding safety profiles and extended cycle lives. These outcomes would revolutionise battery technologies and position Australia as a global leader in the critical transition to a decarbonised economy.
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Catalytic Degardation of Emerging Microplastic Pollutants. This project aims to develop robust and low-cost nanocarbon hybrids and advanced remediation technology to address globally emerging microplastic contaminations. The project expects to boost innovations in development of novel magnetic nanomaterials, process of microplastic purification, and green catalysis. Expected outcomes of this project will include efficient strategies in materials fabrication and a cutting-edge nanotechnology. The ....Catalytic Degardation of Emerging Microplastic Pollutants. This project aims to develop robust and low-cost nanocarbon hybrids and advanced remediation technology to address globally emerging microplastic contaminations. The project expects to boost innovations in development of novel magnetic nanomaterials, process of microplastic purification, and green catalysis. Expected outcomes of this project will include efficient strategies in materials fabrication and a cutting-edge nanotechnology. The success of the project will underpin the scientific bases of carbocatalysis, provide significant benefits to the Australian industry and society for a sustainable future with clean water, and increase the leading capacity of Australia in fundamental research and frontier technology.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
Molecular movies using time-resolved momentum spectroscopies. This project aims to use time-resolved momentum spectroscopies to take snapshots of chemical and physical processes as they evolve in time. This project expects to use these molecular movies to track the changes to electron motion after they have absorbed light. Expected outcomes of this project include understanding how the motion of electrons can drive physical processes and induce chemical changes. This will provide significant ben ....Molecular movies using time-resolved momentum spectroscopies. This project aims to use time-resolved momentum spectroscopies to take snapshots of chemical and physical processes as they evolve in time. This project expects to use these molecular movies to track the changes to electron motion after they have absorbed light. Expected outcomes of this project include understanding how the motion of electrons can drive physical processes and induce chemical changes. This will provide significant benefits through expanding knowledge that will assist in controlling chemical reactions and developing technologies with improved performance, such as sensors and solar cells. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200100629
Funder
Australian Research Council
Funding Amount
$409,516.00
Summary
Single-atom anchored photocatalysts for solar ammonia production. This project aims to develop single-atom anchored two-dimensional photocatalysts with outstanding activity, selectivity and stability for sunlight-driven photocatalytic nitrogen reduction to produce ammonia via combining advanced characterizations and theoretical calculations. This project will contribute to the fundamental knowledge on the nature and origin of the activity, selectivity and stability in photocatalytic ammonia prod ....Single-atom anchored photocatalysts for solar ammonia production. This project aims to develop single-atom anchored two-dimensional photocatalysts with outstanding activity, selectivity and stability for sunlight-driven photocatalytic nitrogen reduction to produce ammonia via combining advanced characterizations and theoretical calculations. This project will contribute to the fundamental knowledge on the nature and origin of the activity, selectivity and stability in photocatalytic ammonia production. High-performance and cost-effective solar ammonia production is expected to achieve in this project. This project will not only reduce the Australia’s demand for non-renewable fossil fuels, but also alleviate the environmental contamination, greenhouse effect and climate change in Australia.
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Electrocatalytic Refinery for Fuels and Chemicals . The aim is to produce the fundamental science for sustainable production of fuels and chemicals through an advanced electrocatalytic approach using abundant small-molecule sources like water, carbon dioxide, and nitrogen oxides as feedstocks. A range of highly active and selective electrode catalysts will be developed for electrolysis processes at ambient temperatures and pressures, by an interdisciplinary approach combining atomic-level materi ....Electrocatalytic Refinery for Fuels and Chemicals . The aim is to produce the fundamental science for sustainable production of fuels and chemicals through an advanced electrocatalytic approach using abundant small-molecule sources like water, carbon dioxide, and nitrogen oxides as feedstocks. A range of highly active and selective electrode catalysts will be developed for electrolysis processes at ambient temperatures and pressures, by an interdisciplinary approach combining atomic-level material design principles, in situ/ex situ instrumental techniques, and modern computation methods. The expected outcomes will be of great significance for renewable energy use and clean fuel generation – the major energy and environmental challenges facing Australia and the world.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230101637
Funder
Australian Research Council
Funding Amount
$431,318.00
Summary
Heterogeneous Molecular Catalysts for Carbon Dioxide Conversion. This project aims to develop a series of structure-tailored, activity-enhanced and selectivity-oriented heterogeneous molecular catalysts for efficiently converting carbon dioxide (CO2) into value-added fuels and chemicals. Innovations are expected in the rational design and engineering of materials, new mechanistic findings from computation and in-situ characterisation, and breakthroughs in CO2 conversion. Expected outcomes includ ....Heterogeneous Molecular Catalysts for Carbon Dioxide Conversion. This project aims to develop a series of structure-tailored, activity-enhanced and selectivity-oriented heterogeneous molecular catalysts for efficiently converting carbon dioxide (CO2) into value-added fuels and chemicals. Innovations are expected in the rational design and engineering of materials, new mechanistic findings from computation and in-situ characterisation, and breakthroughs in CO2 conversion. Expected outcomes include new synthesis methods, innovative multi-structural engineering strategies, thorough reaction mechanism understanding, and high-performance commercially-relevant CO2 reduction electrolysis. Benefits include a sustainable future for Australia with decreased CO2 emissions and increased green-fuel production.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100159
Funder
Australian Research Council
Funding Amount
$473,847.00
Summary
Developing Room-Temperature Liquid Metal Batteries for Safe Energy Storage. To overcome safety issues intrinsic to the prevalent solid metal anodes in battery technology, this project aims to develop room-temperature liquid metal batteries by employing liquid Sodium-Potassium alloy. Innovations will span the development of the electrode concept, interface-oriented electrolyte design guided by theory and experiment, and prototype battery cell examples to illustrate how high round-trip efficiencie ....Developing Room-Temperature Liquid Metal Batteries for Safe Energy Storage. To overcome safety issues intrinsic to the prevalent solid metal anodes in battery technology, this project aims to develop room-temperature liquid metal batteries by employing liquid Sodium-Potassium alloy. Innovations will span the development of the electrode concept, interface-oriented electrolyte design guided by theory and experiment, and prototype battery cell examples to illustrate how high round-trip efficiencies at fast charging can be achieved over a prolonged time. The anticipated outcomes would transform battery technology concepts while providing a critical scientific basis for commercialisation. Further, the success of this project would help Australia realise its shift from traditional to emerging sustainable energy systems.Read moreRead less