Sustainable polymer construction materials from agricultural waste. Agricultural waste is the world's most abundant petroleum alternative for transformation into environmentally friendly bio-based materials for the construction sectors. Bringing together complimentary research expertise between academia and industry, this project aims to address this opportunity and develop technologies that economically convert agricultural wastes to crude-oils to produce bio-based resins, adhesives and polyure ....Sustainable polymer construction materials from agricultural waste. Agricultural waste is the world's most abundant petroleum alternative for transformation into environmentally friendly bio-based materials for the construction sectors. Bringing together complimentary research expertise between academia and industry, this project aims to address this opportunity and develop technologies that economically convert agricultural wastes to crude-oils to produce bio-based resins, adhesives and polyurethane. This project expects to produce ready-to-use, total replacements for petroleum-based construction materials. This should provide significant benefits including supporting Australian manufacturing by delivering technologies for sustainable and rapid adoption in the construction, resin and coating industries. Read moreRead less
Understanding production and application of alpha emitting radionuclides. This project aims to develop new materials to improve the efficiency of production of radionuclides, as well as tools to improve our understanding of isotope decay products to to improve efficiency of delivery. High performance polymers will be evaluated to establish optimal design properties for enhanced radionuclide collection from novel generators of isotopic lead (Pb-212), and new methods will be developed to improve u ....Understanding production and application of alpha emitting radionuclides. This project aims to develop new materials to improve the efficiency of production of radionuclides, as well as tools to improve our understanding of isotope decay products to to improve efficiency of delivery. High performance polymers will be evaluated to establish optimal design properties for enhanced radionuclide collection from novel generators of isotopic lead (Pb-212), and new methods will be developed to improve understanding of isotope product stability. Anticipated outcomes will provide greater production and utility of radioisotopes in radiopharmaceuticals, while building strong ties with partner AdvanCell Isotopes. This could improve manufacture of radionuclides, expanding capability and applications in radiopharmaceuticals.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100917
Funder
Australian Research Council
Funding Amount
$457,647.00
Summary
Manufacturing Nanostructured Metallic Materials via 3D Printed Polymers. This project aims to develop additive manufacturing processes capable of rapidly producing nanostructured polymer and metallic materials with tuneable physical and chemical properties. This project expects to develop new knowledge and chemical processes, allowing the rational design of functional materials with applications in catalysis, energy storage, and chemical separations. Expected outcomes include more energy efficie ....Manufacturing Nanostructured Metallic Materials via 3D Printed Polymers. This project aims to develop additive manufacturing processes capable of rapidly producing nanostructured polymer and metallic materials with tuneable physical and chemical properties. This project expects to develop new knowledge and chemical processes, allowing the rational design of functional materials with applications in catalysis, energy storage, and chemical separations. Expected outcomes include more energy efficient and environmentally benign methods for functional materials synthesis, and increased understanding of structure-property-performance relationships in nanostructured materials. This should provide benefits to Australia by providing cost-effective routes for materials used in energy, health, and water.Read moreRead less
Mid-Career Industry Fellowships - Grant ID: IM230100090
Funder
Australian Research Council
Funding Amount
$1,053,046.00
Summary
Multi material 3D Printing. This project aims to further develop a new 3D printing technique commercialised by an Australian start-up company. Current electronics manufacturing is extremely capital intensive, slow and restrictive in 3D design. The 3D printing method proposed in this application will disrupt the current advanced manufacturing eco system; creating unique methods to unlock advances in diverse markets for example, photovoltaics, printed circuit boards and sensors. The expected outco ....Multi material 3D Printing. This project aims to further develop a new 3D printing technique commercialised by an Australian start-up company. Current electronics manufacturing is extremely capital intensive, slow and restrictive in 3D design. The 3D printing method proposed in this application will disrupt the current advanced manufacturing eco system; creating unique methods to unlock advances in diverse markets for example, photovoltaics, printed circuit boards and sensors. The expected outcomes of this project are to create new commercial opportunities for the next generation of 3D printed electronics. This will provide significant benefits, creating unique capability to manufacture devices in 3D - faster, cheaper and with reduced reliance on global supply chains.Read moreRead less
An in-built depolymerisation solution for polyethylene waste. This project aims to design enzymes that can be embedded into polyethylene, and later activated by the elevated temperatures of a compost heap, to depolymerise the plastic to small molecules. There are no good options available for the controlled decomposition of polyethylene waste at present, and instead researchers have focussed on solutions that rely on modifications to the underlying chemistry of the backbone and or collection to ....An in-built depolymerisation solution for polyethylene waste. This project aims to design enzymes that can be embedded into polyethylene, and later activated by the elevated temperatures of a compost heap, to depolymerise the plastic to small molecules. There are no good options available for the controlled decomposition of polyethylene waste at present, and instead researchers have focussed on solutions that rely on modifications to the underlying chemistry of the backbone and or collection to a central facility. Our approach would result in an in-built decomposition that does not require collection and recycling in a central facility. Since it is based on a depolymerisation mechanism it does not result in the production of harmful, partially disintegrated microplastics.Read moreRead less
Resonant tender X-ray scattering of organic semiconductors. This project aims to establish resonant tender X-ray scattering as a mature technique for unravelling the complex microstructure of organic semiconductor layers. By understanding and exploiting the resonant interaction between organic semiconductors and X-rays tuned to appropriate absorption edges, new information about the molecular packing of these materials will be obtained. The expected outcomes are new experimental methodologies an ....Resonant tender X-ray scattering of organic semiconductors. This project aims to establish resonant tender X-ray scattering as a mature technique for unravelling the complex microstructure of organic semiconductor layers. By understanding and exploiting the resonant interaction between organic semiconductors and X-rays tuned to appropriate absorption edges, new information about the molecular packing of these materials will be obtained. The expected outcomes are new experimental methodologies and analysis tools for determining the complex structure of technologically relevant materials. Benefits include understanding of the properties of solution-processed semiconductors enabling the design of high performance materials with applications in energy, electronics, lighting and health.Read moreRead less
Smart materials for atmospheric water management and water harvesting. Fresh water is a scarce resource in many parts of the globe but uncomfortably over-supplied in other regions. Dehumidifying machines, such as air conditioners, are extensively used in humid climates to enhance human comfort, but with great energy costs. Likewise, the production of potable water in remote dry regions is energy intensive. We propose novel hyper-absorbent desiccating polymers combined into sorption-powered engin ....Smart materials for atmospheric water management and water harvesting. Fresh water is a scarce resource in many parts of the globe but uncomfortably over-supplied in other regions. Dehumidifying machines, such as air conditioners, are extensively used in humid climates to enhance human comfort, but with great energy costs. Likewise, the production of potable water in remote dry regions is energy intensive. We propose novel hyper-absorbent desiccating polymers combined into sorption-powered engines inspired by nastic movements in plants to develop extremely efficient dehumidifiers and water harvesting machines. These polymer actuators can help address the auto-acceleration of climate change caused by the increasing use of air conditioners and provide cheap, clean water for remote communities.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL220100016
Funder
Australian Research Council
Funding Amount
$2,738,854.00
Summary
Light-Driven Manufacturing for (Re)Programmable Materials. This Laureate Fellowship aims to develop a suite of chemical reactions independently activated by specific colours of light for the precise synthesis of functional macromolecules and the fabrication of (re)programmable polymeric materials. The outcome of this Laureate will be the direct production of advanced 3D printed objects with tuneable properties and functions by exploiting different wavelengths of light. This research unlocks the ....Light-Driven Manufacturing for (Re)Programmable Materials. This Laureate Fellowship aims to develop a suite of chemical reactions independently activated by specific colours of light for the precise synthesis of functional macromolecules and the fabrication of (re)programmable polymeric materials. The outcome of this Laureate will be the direct production of advanced 3D printed objects with tuneable properties and functions by exploiting different wavelengths of light. This research unlocks the structural precision of Nature and the next-generation capabilities of reshapability. These innovative tools will revolutionise 3D printing methods, which will create a new era of advanced manufacturing.Read moreRead less