Highly functional green materials platform: Starch-ionic liquid-carbon nanotube polymer melt nanocomposites. This project will deliver state of the art scientific advances in green polymers, green plasticisers and tailored nanomaterials for melt processible renewable starch plastics for high-performance applications as electroactive polymers in areas such as biosensors and biodiagnostics.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100033
Funder
Australian Research Council
Funding Amount
$150,000.00
Summary
Green biopolymer nanocomposites facility: supercritical carbon dioxide characterisation and processing for nanomaterials and biopolymers. This facility will house characterisation and processing equipment for developing the next generation biopolymer materials. Novel biopolymers will be developed from natural and renewable resources using improved performance and lower energy supercritical carbon dioxide processing methods.
Advanced Materials from Automated Synthesis of Sequence-Defined Polymers. The project aims to develop industrially scalable and environmentally friendly methods for synthesis of sequence-defined multiblock copolymers (polymer chains containing segments of different polymer types) using automated synthesis methods. The materials to be explored will be largely based on renewable biomass-derived monomeric building blocks. Such polymers are able to undergo microphase separation into spatially period ....Advanced Materials from Automated Synthesis of Sequence-Defined Polymers. The project aims to develop industrially scalable and environmentally friendly methods for synthesis of sequence-defined multiblock copolymers (polymer chains containing segments of different polymer types) using automated synthesis methods. The materials to be explored will be largely based on renewable biomass-derived monomeric building blocks. Such polymers are able to undergo microphase separation into spatially periodic compositional patterns, thereby providing access to a vast range of nano-engineered materials. This would enable design and synthesis of new advanced materials, making use of renewable resources and supporting the circular economy, with diverse potential applications ranging from nanomedicine to materials science.Read moreRead less
Development of High Performance Mechanical Sorting of Plastics for Recycling. This research program aims to develop and test a range of high performance, mechanical in-process plastics sorting technologies in conjunction with Australia's lead recycling company. Currently, recycling techniques result in an insufficient purity and quality level, thus limiting the extent of recycling and opportunity for end product applications. Increasing the purity of recycled plastics and economics of recyclin ....Development of High Performance Mechanical Sorting of Plastics for Recycling. This research program aims to develop and test a range of high performance, mechanical in-process plastics sorting technologies in conjunction with Australia's lead recycling company. Currently, recycling techniques result in an insufficient purity and quality level, thus limiting the extent of recycling and opportunity for end product applications. Increasing the purity of recycled plastics and economics of recycling, without compromising throughput levels, will result in an increase in recycling rates and the range of applications of recycled plastics.Read moreRead less
Development of Advanced Polymers from Recycled Industrial Plastics for Replacement of Virgin Resins. The main objective of this research program is to develop strategies and techniques to develop advanced polymeric materials obtained from recycled industrial plastics for replacement of virgin resins in industrial packaging. Studies show that only a very small amount of such plastic is reclaimed after industrial use. The research will include a comprehensive study of the life cycle of the indus ....Development of Advanced Polymers from Recycled Industrial Plastics for Replacement of Virgin Resins. The main objective of this research program is to develop strategies and techniques to develop advanced polymeric materials obtained from recycled industrial plastics for replacement of virgin resins in industrial packaging. Studies show that only a very small amount of such plastic is reclaimed after industrial use. The research will include a comprehensive study of the life cycle of the industrial packaging products, development of new blends of the recycled resins, and the application of these blends to manufacture good quality injection moulded and blow moulded products including new plastic pails and containers for industrial use.Read moreRead less
Self-reinforced biopolymer composites. This project will pioneer high performance and biodegradable composites using self-reinforced biopolymer composites. Composites can have poor properties due to interfacial issues, and this reduces their performance. By producing a fully self-reinforced (where the fibre and the polymer are the same type of polymer) polymer composites, the project will develop a way to improve properties, increase the use of biobased materials, and improve recyclability and b ....Self-reinforced biopolymer composites. This project will pioneer high performance and biodegradable composites using self-reinforced biopolymer composites. Composites can have poor properties due to interfacial issues, and this reduces their performance. By producing a fully self-reinforced (where the fibre and the polymer are the same type of polymer) polymer composites, the project will develop a way to improve properties, increase the use of biobased materials, and improve recyclability and biodegradability. Outcomes include greater understanding of design of self-reinforced biopolymer composites structure, processing and properties. This will produce opportunities for high performance biobased composite manufacturing and a growing circular plastics economy for Australia.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0237936
Funder
Australian Research Council
Funding Amount
$100,000.00
Summary
Research facility for plastics and composites : Dynamic Mechanical Analyser and Rheometer System. The Dynamic Mechanical Analyser (DMA) and Control Stress Rheometer System is a unique set of equipment where both instruments can be run simultaneously using the same controller module. The DMA can provide quantitative and qualitative information on high spectrum of mechanical and rheological properties of materials in solid state. The Rheometer complements the DMA by providing information about pro ....Research facility for plastics and composites : Dynamic Mechanical Analyser and Rheometer System. The Dynamic Mechanical Analyser (DMA) and Control Stress Rheometer System is a unique set of equipment where both instruments can be run simultaneously using the same controller module. The DMA can provide quantitative and qualitative information on high spectrum of mechanical and rheological properties of materials in solid state. The Rheometer complements the DMA by providing information about properties of materials in liquid state. The equipment will be used both for academic research of plastic, ceramic and composite materials and for industrial projects in the areas of material processing, recycling of plastics and for building a database of material's properties. Read moreRead less
Faster, greener, stronger: a new approach to synthesis of polymer materials. The project will investigate new approaches towards polymer material synthesis in the complete absence of hazardous solvents, with the aim of creating materials that have superior physical or chemical properties compared to those prepared using existing methods. This project is significant for driving advances in material design and characterization using simple starting materials and environmentally sustainable conditi ....Faster, greener, stronger: a new approach to synthesis of polymer materials. The project will investigate new approaches towards polymer material synthesis in the complete absence of hazardous solvents, with the aim of creating materials that have superior physical or chemical properties compared to those prepared using existing methods. This project is significant for driving advances in material design and characterization using simple starting materials and environmentally sustainable conditions. Expected outcomes include the production of unique nanomaterials, hydrogels and polymer monoliths with targeted applications, in addition to advances in 3D printing. This project will significantly benefit the sustainable material manufacturing industry into the future.Read moreRead less
Nanostructure Design and Toughening Mechanisms of Novel Thermosets. The research will enable a new technology to manufacture a class of novel nanostructured thermosets that will impact many application areas in Australia, such as protective surface coatings, structural adhesives and composite matrix materials for aerospace and automotive, and microelectronic devices, etc. The intellectual properties and patents generated will contribute to the overall competitiveness and productivity of Australi ....Nanostructure Design and Toughening Mechanisms of Novel Thermosets. The research will enable a new technology to manufacture a class of novel nanostructured thermosets that will impact many application areas in Australia, such as protective surface coatings, structural adhesives and composite matrix materials for aerospace and automotive, and microelectronic devices, etc. The intellectual properties and patents generated will contribute to the overall competitiveness and productivity of Australia~{!/~}s R&D. They will also provide business opportunities to develop niche markets for these new and high-value added materials on a large scale in Australia so as to maximise return and create jobs. Read moreRead less
Novel injection moulded polymer substrates for solid phase applications. Solid phase organic reactions form the basis of many applications in drug design and development and medical applications. This project proposes the development of novel solid phase materials via control of novel insitu crosslinking and foaming processes and novel process molding control. This will enable more controlled large scale rapid production and detection of materials for biological and medical uses.