Discovery Early Career Researcher Award - Grant ID: DE230101044
Funder
Australian Research Council
Funding Amount
$444,318.00
Summary
Bio-inspired nanomaterials with tunable drug loading and controlled release. This project aims to develop new platform technologies for making bio-inspired nanomaterials with tunable drug loading and controlled release. This project will revolutionise current approaches to make lipid nanoparticles camouflaged with natural cell membranes for delivery of both insoluble and soluble drugs. Significant outcomes will include a novel commercially relevant salt-induced nanoprecipitation platform technol ....Bio-inspired nanomaterials with tunable drug loading and controlled release. This project aims to develop new platform technologies for making bio-inspired nanomaterials with tunable drug loading and controlled release. This project will revolutionise current approaches to make lipid nanoparticles camouflaged with natural cell membranes for delivery of both insoluble and soluble drugs. Significant outcomes will include a novel commercially relevant salt-induced nanoprecipitation platform technology for making precisely engineered nanomaterials with tailored functions for applications in controlled release and targeted delivery. Benefits include securing a sustainable future for Australia, with new nanotechnology strategies for advanced manufacturing.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
Early Career Industry Fellowships - Grant ID: IE230100437
Funder
Australian Research Council
Funding Amount
$417,237.00
Summary
Nanobubbles for effective and energy efficient water treatment. This project aims to produce new knowledge for developing ozone nanobubbles as a technological option for the water industry where commercially suitable technologies are unavailable. Australian water utilities have identified two key challenges: destruction of micropollutants and natural organic matter in recycled and reservoir water, respectively. New knowledge from the project will allow these water utilities to utilise the extrao ....Nanobubbles for effective and energy efficient water treatment. This project aims to produce new knowledge for developing ozone nanobubbles as a technological option for the water industry where commercially suitable technologies are unavailable. Australian water utilities have identified two key challenges: destruction of micropollutants and natural organic matter in recycled and reservoir water, respectively. New knowledge from the project will allow these water utilities to utilise the extraordinary properties of nanobubbles and the strong oxidation capability of ozone for effective and energy efficient water treatment. Tech-transfer to the industry is guaranteed through a scientifically designed pilot plant for benchmarking against the current state of the art ozonation process and reverse osmosis.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230100471
Funder
Australian Research Council
Funding Amount
$456,318.00
Summary
Designing advanced Zn-ion batteries towards practical applications. Aqueous Zn-ion batteries (ZIBs) are much safer and cheaper than current Li-ion batteries due to the water-based electrolyte and abundant Zn reserves. However, the state-of-the-art ZIB technique faces huge challenges for practical applications due to the low cathode capacity and poor Zn anode reversibility. This project aims to design novel cathodes with a new-type mechanism and highly reversible Zn anodes. Accordingly, on-demand ....Designing advanced Zn-ion batteries towards practical applications. Aqueous Zn-ion batteries (ZIBs) are much safer and cheaper than current Li-ion batteries due to the water-based electrolyte and abundant Zn reserves. However, the state-of-the-art ZIB technique faces huge challenges for practical applications due to the low cathode capacity and poor Zn anode reversibility. This project aims to design novel cathodes with a new-type mechanism and highly reversible Zn anodes. Accordingly, on-demand large-size ZIBs and flexible devices under industrial parameters will also be developed. The success of this project will place Australia at the forefront of implementing safe and low-cost batteries in largescale smart grid systems, household markets, and wearable medical devices.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
Discovery Early Career Researcher Award - Grant ID: DE230101011
Funder
Australian Research Council
Funding Amount
$420,818.00
Summary
Developing advanced potassium-sulfur batteries for scalable energy storage. Potassium-sulfur (K-S) batteries are recognised as a promising energy storage technology for large-scale applications, due to their high theoretical capacity, low toxicity and the low cost of both potassium and sulfur. However, their grid-scale development is plagued by safety hazards and fast capacity fade. This project aims to address these challenges by developing atomic-level engineering of host materials for sulfur, ....Developing advanced potassium-sulfur batteries for scalable energy storage. Potassium-sulfur (K-S) batteries are recognised as a promising energy storage technology for large-scale applications, due to their high theoretical capacity, low toxicity and the low cost of both potassium and sulfur. However, their grid-scale development is plagued by safety hazards and fast capacity fade. This project aims to address these challenges by developing atomic-level engineering of host materials for sulfur, K metal anode and solid electrolyte. The outcomes of this project will provide increased understanding of the mechanism for K-S batteries and novel strategies for their development, placing Australia at the forefront of K-S batteries for scalable battery research and supporting our cutting-edge energy storage technology.
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Solar-thermal desalination system for parallel water-electricity generation. This project aims to develop a multi-functional solar-thermal desalination device to simultaneously produce clean water and electricity. Interfacial solar evaporation-based desalination technology has the unique advantage of using solar light as the sole energy source for affordable clean water production. However, its absolute evaporation rate is still too low for practical application and all of the latent heat releas ....Solar-thermal desalination system for parallel water-electricity generation. This project aims to develop a multi-functional solar-thermal desalination device to simultaneously produce clean water and electricity. Interfacial solar evaporation-based desalination technology has the unique advantage of using solar light as the sole energy source for affordable clean water production. However, its absolute evaporation rate is still too low for practical application and all of the latent heat released from vapor condensation during desalination is wasted. Solving these two critical issues by the study of energy nexus, design and fabrication of advanced photothermal materials and desalination devices could accelerate practical adoption of this technology and benefit millions of people who desperately need clean water. 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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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
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