Australian Laureate Fellowships - Grant ID: FL190100139
Funder
Australian Research Council
Funding Amount
$3,185,850.00
Summary
New Artificial Leaf for Efficient Solar Fuel Production . The Fellowship aims to develop next-generation materials that harness solar energy to produce valuable fuels and chemicals from water and carbon dioxide, replacing fossil fuels. The program will design new semiconductor materials to revolutionise solar-to-fuel technologies that currently have very low efficiency. The expected outcomes include innovative systems such as wireless artificial leaves that mimic natural photosynthesis for effic ....New Artificial Leaf for Efficient Solar Fuel Production . The Fellowship aims to develop next-generation materials that harness solar energy to produce valuable fuels and chemicals from water and carbon dioxide, replacing fossil fuels. The program will design new semiconductor materials to revolutionise solar-to-fuel technologies that currently have very low efficiency. The expected outcomes include innovative systems such as wireless artificial leaves that mimic natural photosynthesis for efficient hydrocarbon production, carbon dioxide reduction, and water purification. The expected benefits include next-generation solar fuel and chemical generation technologies, and research capabilities to position Australia as a global leader in the transition to a decarbonised economy.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
Room Temperature Rechargeable Sulphur Batteries. The project will lead to the development of low cost sulphur rechargeable batteries for electric vehicles and hybrid electric vehicles and will contribute to the national priority goal of reducing and capturing emissions in transport to improve our environment. The project will take the incentive in establishing a leading national position in the development of low cost energy storage technology. The Partner Organisation, Nipress, has a close con ....Room Temperature Rechargeable Sulphur Batteries. The project will lead to the development of low cost sulphur rechargeable batteries for electric vehicles and hybrid electric vehicles and will contribute to the national priority goal of reducing and capturing emissions in transport to improve our environment. The project will take the incentive in establishing a leading national position in the development of low cost energy storage technology. The Partner Organisation, Nipress, has a close connection to Australia. The company has imported raw materials (metal lead, 8000 tons) from Australia every year. The success of sulphur batteries technology will increase the opportunity of Nipress using more Australian raw materials.
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Cold catalysis for water splitting. This project aims to develop photocatalysts via AC magnetic field through nanoscale heating for efficient H2 generation. This project is to introduce cold catalysis concept, which heats catalysts only but not solution, thus called cold catalysis, in the area of production of renewable energy. Expected outcome is the creation of clean and low cost catalysts to effectively harvest the chemical energy from the sun via splitting of water into H2 and O2 without cau ....Cold catalysis for water splitting. This project aims to develop photocatalysts via AC magnetic field through nanoscale heating for efficient H2 generation. This project is to introduce cold catalysis concept, which heats catalysts only but not solution, thus called cold catalysis, in the area of production of renewable energy. Expected outcome is the creation of clean and low cost catalysts to effectively harvest the chemical energy from the sun via splitting of water into H2 and O2 without causing any environmental damage. This unique technology will also help to address clean energy generation, which is in line with H2 economy plan by Australia government, and provide opportunities for new industries that will benefit Australian economy.Read moreRead less
Integrated composite electrodes for electrochemical synthesis of ammonia. This project aims to develop multifunctional composite electrodes for electrochemical synthesis of ammonia from water, nitrogen gas and renewable energy under ambient conditions. Hydrophobic subnanometre water channels will be integrated with an electrocatalyst to control supply of water as vapour, thereby effectively minimising hydrogen evolution reaction and enabling high-efficiency ammonia synthesis. Expected outcomes i ....Integrated composite electrodes for electrochemical synthesis of ammonia. This project aims to develop multifunctional composite electrodes for electrochemical synthesis of ammonia from water, nitrogen gas and renewable energy under ambient conditions. Hydrophobic subnanometre water channels will be integrated with an electrocatalyst to control supply of water as vapour, thereby effectively minimising hydrogen evolution reaction and enabling high-efficiency ammonia synthesis. Expected outcomes include enhanced capacity in developing electrochemical reaction systems, and new fundamental knowledge of electrocatalyst design and reaction engineering. This should provide significant economic and environmental benefits by developing a sustainable manufacturing technology to transform the century-old ammonia industry.Read moreRead less
Flow process and visible-light driven reactions for polymer manufacturing. This project aims to develop rapid, scalable light-driven continuous flow processing techniques that allow the production of value-added synthetic polymers that cannot be achieved by existing technologies. The project will take advantage of the spatio-temporal control of the light mediated polymerisation with flow process to achieve control over the primary structure, the sequential arrangement of monomer units in a polym ....Flow process and visible-light driven reactions for polymer manufacturing. This project aims to develop rapid, scalable light-driven continuous flow processing techniques that allow the production of value-added synthetic polymers that cannot be achieved by existing technologies. The project will take advantage of the spatio-temporal control of the light mediated polymerisation with flow process to achieve control over the primary structure, the sequential arrangement of monomer units in a polymer chain and the molecular weight distribution. The project will result in the preparation of functional polymers containing a specific arrangement of monomers in the polymer chain and a precise distribution of polymer chains. The development of such process will result in the development of advanced materials.Read moreRead less
Nanoscale heating towards high efficient nitrogen reduction reduction. This project aims to develop nanoscale heating technique using AC magnetic field for efficient synthesis of ammonia, widely used for fertiliser and having potential for hydrogen storage. This project is to introduce nanoscale heating concept by heating catalyst only but not solution in electrochemical catalysis to achieve high catalytic activity. Expected outcome is the creation of low cost catalysts having high selectivity a ....Nanoscale heating towards high efficient nitrogen reduction reduction. This project aims to develop nanoscale heating technique using AC magnetic field for efficient synthesis of ammonia, widely used for fertiliser and having potential for hydrogen storage. This project is to introduce nanoscale heating concept by heating catalyst only but not solution in electrochemical catalysis to achieve high catalytic activity. Expected outcome is the creation of low cost catalysts having high selectivity and formation rate for ammonia production. This unique technology has the potential to replace current ammonia production based on Haber-Bosch process, which consumes 2% of world energy and contributes 3% of overall CO2 emission. The project provides opportunities for new industries that will benefit Australian economy.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL200100049
Funder
Australian Research Council
Funding Amount
$2,906,992.00
Summary
Nanofluidic Membranes for Sustainable Energy Future. This project aims to create a novel class of advanced membranes by making fundamental breakthroughs in nanofluidics, and harnessing this for developing new renewable energy and low-energy separation technologies. This project addresses the key challenges in understanding selective mass transport at the angstrom scale, thereby allowing the development of innovative materials design strategies to realise the ultrafast molecular and ionic permeat ....Nanofluidic Membranes for Sustainable Energy Future. This project aims to create a novel class of advanced membranes by making fundamental breakthroughs in nanofluidics, and harnessing this for developing new renewable energy and low-energy separation technologies. This project addresses the key challenges in understanding selective mass transport at the angstrom scale, thereby allowing the development of innovative materials design strategies to realise the ultrafast molecular and ionic permeation, and the ultrahigh selectivities observed in biological cell membranes. This new cross-disciplinary research will benefit Australia by the development of new materials for accelerating renewable hydrogen and biofuel futures, and enabling sustainable production of energy materials.Read moreRead less
Mechanical modulation of particle-cell interactions. Mechanical forces play critical roles in many biological processes, but how particle mechanical properties modulate particle-cell interactions remains elusive. This project aims to develop new design principles for engineering nano/micromaterials with tunable mechanical properties for improved cell activation and expansion, and to advance knowledge of the role of particle stiffness in modulating receptor-mediated particle-cell interactions. Ex ....Mechanical modulation of particle-cell interactions. Mechanical forces play critical roles in many biological processes, but how particle mechanical properties modulate particle-cell interactions remains elusive. This project aims to develop new design principles for engineering nano/micromaterials with tunable mechanical properties for improved cell activation and expansion, and to advance knowledge of the role of particle stiffness in modulating receptor-mediated particle-cell interactions. Expected outcomes and benefits include new fundamental understanding of the effect of particle mechanical properties on cell function, new insights into T cell activation and expansion, and new classes of stiffness-tunable fit-for-purpose materials for various applications in cell manufacturing.Read moreRead less
Engineering the trafficking of nanoparticles within cells. This project aims to engineer responsive nanoparticles capable of trafficking efficiently within cells. The site of release of therapeutic cargo has importance for improving the efficacy of many treatments, for example vaccine delivery. Therefore fundamental understanding of how nanoparticle structure can be engineered to control cellular behaviour is necessary. The project will engineer new polymeric nanomaterials and investigate the im ....Engineering the trafficking of nanoparticles within cells. This project aims to engineer responsive nanoparticles capable of trafficking efficiently within cells. The site of release of therapeutic cargo has importance for improving the efficacy of many treatments, for example vaccine delivery. Therefore fundamental understanding of how nanoparticle structure can be engineered to control cellular behaviour is necessary. The project will engineer new polymeric nanomaterials and investigate the impact of their structure on biological properties. The benefits of this project will include new fundamental insights into improving nanoparticle design for vaccine delivery, as well as the expansion of Australia’s knowledge base in the area of biodegradable polymers.Read moreRead less