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
Engineering improved technology for nanoparticle-based adjuvant manufacture. Over the next decade nanotechnology will redefine vaccines for animal and human health. Nanoparticle adjuvants will boost engineered vaccines that use minimal antigens such as recombinant proteins and synthetic peptides. This project aims to develop a platform technology for making and controlling the properties of inulin nanoparticles by optimising the engineering and manufacturing aspects of inulin nanoparticles to fu ....Engineering improved technology for nanoparticle-based adjuvant manufacture. Over the next decade nanotechnology will redefine vaccines for animal and human health. Nanoparticle adjuvants will boost engineered vaccines that use minimal antigens such as recombinant proteins and synthetic peptides. This project aims to develop a platform technology for making and controlling the properties of inulin nanoparticles by optimising the engineering and manufacturing aspects of inulin nanoparticles to fundamentally understand the relationship between physical-chemical properties and efficacy. Completion of this project aims to produce potent nanoparticle-based adjuvants underpinned by novel manufacturing technology, to ultimately facilitate the development of more effective and protective vaccines for animals and humans.Read moreRead less
Develop Catalyst Materials for Future Fuels by Operando Computation. This project aims to design catalyst materials for the production of future fuels (green ammonia, hydrocarbon and alcohol). Using carbon and nitrogen as energy carriers, these fuels are generated from renewable sources such as wind or solar; they are safe, reliable, and possess high energy density. The outcomes include advance in computational electrochemistry to the Opeando level, electrocatalysts design principles with clearl ....Develop Catalyst Materials for Future Fuels by Operando Computation. This project aims to design catalyst materials for the production of future fuels (green ammonia, hydrocarbon and alcohol). Using carbon and nitrogen as energy carriers, these fuels are generated from renewable sources such as wind or solar; they are safe, reliable, and possess high energy density. The outcomes include advance in computational electrochemistry to the Opeando level, electrocatalysts design principles with clearly articulated reaction mechanisms, and candidate materials for experimental validation. Facilitated by advanced computation techniques and reliable catalyst materials design procedure, this project will address the biggest challenge in future fuel generation, which is the lack of efficient catalyst materials. Read moreRead less
Catalysts for hydrogen-free ammonia production by electrochemical method. This project aims to realise the next generation of ammonia production under ambient conditions without hydrogen feedstock. Through a combination of theoretical molecular-level understanding and experimental materials engineering, a range of catalysts will be developed under a materials discovery scheme for electrochemical nitrogen reduction to ammonia. These new catalysts, featuring high activity, efficiency, selectivity, ....Catalysts for hydrogen-free ammonia production by electrochemical method. This project aims to realise the next generation of ammonia production under ambient conditions without hydrogen feedstock. Through a combination of theoretical molecular-level understanding and experimental materials engineering, a range of catalysts will be developed under a materials discovery scheme for electrochemical nitrogen reduction to ammonia. These new catalysts, featuring high activity, efficiency, selectivity, and stability, will facilitate an alternative artificial nitrogen fixation technology powered by renewable energies. This technology will enable the production of green fertilisers and provide renewable energy storage, which are key environmental and energy challenges that Australia and the world currently face.Read moreRead less
Nanostructured Electrocatalysts for Clean Fuels Production. This project aims to develop single-component and hybrid transition-metal and metal-free electrocatalysts with controllable nanostructures to efficiently and selectively catalyse carbon dioxide reduction and hydrogen evolution reactions for clean fuels production including hydrogen and low-carbon organic molecules. By combining experimental and theoretical modelling, this project plans to reveal the origins, mechanism and pathway of the ....Nanostructured Electrocatalysts for Clean Fuels Production. This project aims to develop single-component and hybrid transition-metal and metal-free electrocatalysts with controllable nanostructures to efficiently and selectively catalyse carbon dioxide reduction and hydrogen evolution reactions for clean fuels production including hydrogen and low-carbon organic molecules. By combining experimental and theoretical modelling, this project plans to reveal the origins, mechanism and pathway of these reactions, and the effect of catalyst composition and morphology on their performance. The resulting nanostructured catalysts are of great importance for feasible clean fuel generation and carbon dioxide reduction.Read moreRead less
Early Career Industry Fellowships - Grant ID: IE230100048
Funder
Australian Research Council
Funding Amount
$466,097.00
Summary
Ammonium-selective membranes to shift water industry into circular economy. The project aims to develop ammonium-selective membranes which are urgently needed in Australian key industries for sustainable ammonia recovery. The project expects to construct the membranes to achieve desirable pore size and surface functionality for fast and selective ammonia transport. The developed membranes should make ammonia recovery from wastewater more effective and sustainable, leading to the healthy waterway ....Ammonium-selective membranes to shift water industry into circular economy. The project aims to develop ammonium-selective membranes which are urgently needed in Australian key industries for sustainable ammonia recovery. The project expects to construct the membranes to achieve desirable pore size and surface functionality for fast and selective ammonia transport. The developed membranes should make ammonia recovery from wastewater more effective and sustainable, leading to the healthy waterway and reduced energy for both ammonia production and removal. Recovered ammonia expects to produce valuable products, supporting agriculture industry and hydrogen economy. The developed membranes should enable water industry's shift into circular economy, providing significant economic and environmental benefits to Australia.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE150100187
Funder
Australian Research Council
Funding Amount
$290,000.00
Summary
SA Facility for High Resolution Imaging and Material Characterization. Facility for high resolution imaging and material characterisation: The aim of this project is to establish a facility that will allow researchers to visualise and analyse structure at nanoscale resolutions. The development of the next generation of opto-electronics, electrochemical and biomedical devices requires tools that can quickly visualise and characterise complex materials at multiscale. The new collaborative nano in ....SA Facility for High Resolution Imaging and Material Characterization. Facility for high resolution imaging and material characterisation: The aim of this project is to establish a facility that will allow researchers to visualise and analyse structure at nanoscale resolutions. The development of the next generation of opto-electronics, electrochemical and biomedical devices requires tools that can quickly visualise and characterise complex materials at multiscale. The new collaborative nano infrared thermal analysis facility is essential to meet the demands of a large number of innovative projects conducted by multidisciplinary consortia of researchers. Located in state-of-the art laboratories and managed as open access resources, the facility will enable and advance research in the areas of energy harvesting, environmental monitoring, biomedical devices, food and pharmaceuticals.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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Linkage Infrastructure, Equipment And Facilities - Grant ID: LE210100153
Funder
Australian Research Council
Funding Amount
$497,264.00
Summary
Integrated In situ Characterisation Facilities for Energy Studies. This project aims to establish a new capability to reveal catalytic behaviour of materials under practical working conditions at multi-scale levels. Through in situ monitoring of surface, interface and structural properties of catalysts, this unique integrated facility will overcome current limitations due to a lack of understanding of reaction mechanism, by ex situ and/or individual in situ characterisations. This world-class fa ....Integrated In situ Characterisation Facilities for Energy Studies. This project aims to establish a new capability to reveal catalytic behaviour of materials under practical working conditions at multi-scale levels. Through in situ monitoring of surface, interface and structural properties of catalysts, this unique integrated facility will overcome current limitations due to a lack of understanding of reaction mechanism, by ex situ and/or individual in situ characterisations. This world-class facility will significantly advance a range of electrocatalysis, photocatalysis and battery applications for renewable energy-storage and clean-fuel generation. This will be Australia’s only platform; it will benefit a number of innovative research projects in energy, catalysis and environmental and materials science.Read moreRead less