Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0211003
Funder
Australian Research Council
Funding Amount
$125,000.00
Summary
A Facility for Probing Nanostructure in Polymers. The properties of a polymer are only partly determined by its molecular structure. It is now clear that the organization of molecular structure and phase morphology on a nano-scale has an equally important role in determining material behaviour. Increasingly this can be manipulated by judicious choice of formulation and processing variables. The polymer Nano-Structure Facility will bring together Australia's principal polymer experts in this a ....A Facility for Probing Nanostructure in Polymers. The properties of a polymer are only partly determined by its molecular structure. It is now clear that the organization of molecular structure and phase morphology on a nano-scale has an equally important role in determining material behaviour. Increasingly this can be manipulated by judicious choice of formulation and processing variables. The polymer Nano-Structure Facility will bring together Australia's principal polymer experts in this area of structure-property relations and provide them with shared access to the appropriate, modern analytical tools required to probe the nano-structure of such new materials with enhanced properties.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0668517
Funder
Australian Research Council
Funding Amount
$220,000.00
Summary
Hyphenated techniques in polymer science and engineering. The collaborator's research capabilities will be greatly enhanced because the equipment will allow simultaneous measurements of various properties which can provide much more information than sequential experiments. Students will be able to undertake research with state-of-the-art equipment which will enhance their research careers and employment prospects. The resulting information will be invaluable to the development of polymer blends ....Hyphenated techniques in polymer science and engineering. The collaborator's research capabilities will be greatly enhanced because the equipment will allow simultaneous measurements of various properties which can provide much more information than sequential experiments. Students will be able to undertake research with state-of-the-art equipment which will enhance their research careers and employment prospects. The resulting information will be invaluable to the development of polymer blends with optimized morphology and mechanical properties; improved polymer processing techniques linked to how the structure and orientation develops; the development of new materials, including novel human tissue implants, from studies of the rheology and phase structure of a polymer during photopolymerization.Read moreRead less
Nanostructured materials by controlled photopolymerization. Photo-polymerization is an important and flexible means of converting a crosslinkable monomer into a solid and has application ranging from lens production to photo-lithography. This project aims at developing the technology of producing multi-phase structures of controllable morphology by selective and independent dual photo-polymerization of blends of crosslinkable monomers at controlled rates. These morphologies may have applicatio ....Nanostructured materials by controlled photopolymerization. Photo-polymerization is an important and flexible means of converting a crosslinkable monomer into a solid and has application ranging from lens production to photo-lithography. This project aims at developing the technology of producing multi-phase structures of controllable morphology by selective and independent dual photo-polymerization of blends of crosslinkable monomers at controlled rates. These morphologies may have applications in toughening polymers with minimum loss in strength and optical transparency, abrasion resistant coatings, tissue engineering (where the phases have differing biodegradability), in microfluidics, and microelectro-mechanical systems (where sub-micron channels/domains are required) or in membrane separation.Read moreRead less
Novel network polymers with photoinduced plasticity. The production of crosslinked polymers (thermosets and rubbers) is a multi-billion dollar industry and these polymers are irreplaceable in their use in numerous applications in the household goods, medical, electronics, automotive and construction industries. However, they shrink during solidification causing internal stresses which weaken them and they can not be reshaped, repaired or recycled. This study will develop a novel range of cros ....Novel network polymers with photoinduced plasticity. The production of crosslinked polymers (thermosets and rubbers) is a multi-billion dollar industry and these polymers are irreplaceable in their use in numerous applications in the household goods, medical, electronics, automotive and construction industries. However, they shrink during solidification causing internal stresses which weaken them and they can not be reshaped, repaired or recycled. This study will develop a novel range of crosslinkable polymers which can change shape on irradiation by light (or by heating) for use in applications ranging from repairable composites, stress-free lens, non-shrinking dental filling materials and light-sensitive actuators which will have significant benefit to industry.Read moreRead less
High efficiency photoinitiators for novel photopolymerization processes. The radiation curing industry is worth several billion dollars world-wide with an Australian market of ca. $100 million and an even greater market in the Asian region. One of the main factors controlling the expansion of this industry is the development of new photoinitiator systems with improved performance. This project aims to combine the skills of three leading scientists in the photocuring field to develop more efficie ....High efficiency photoinitiators for novel photopolymerization processes. The radiation curing industry is worth several billion dollars world-wide with an Australian market of ca. $100 million and an even greater market in the Asian region. One of the main factors controlling the expansion of this industry is the development of new photoinitiator systems with improved performance. This project aims to combine the skills of three leading scientists in the photocuring field to develop more efficient, environmentally-friendly systems by controlling the initiation and polymerization mechanisms in (meth)acrylate, cyclic ether, cyanate and vinyl ethers. This should benefit local manufacturers exporting into the printing, adhesive, dental, lithography, composite industries and to the photopolymer industry generally.Read moreRead less
Advanced polymer fibres with multiple functionalities. This project will add value to the local polymer and fibre industries. Australia is a significant producer of synthetic polymers such as polypropylene and the largest producer of wool. There is also local production of nanoparticles such as zinc oxide. This project will add value to all these producers through innovative uses and applications of different types of material. Combining organic and inorganic particles in a polymer matrix has no ....Advanced polymer fibres with multiple functionalities. This project will add value to the local polymer and fibre industries. Australia is a significant producer of synthetic polymers such as polypropylene and the largest producer of wool. There is also local production of nanoparticles such as zinc oxide. This project will add value to all these producers through innovative uses and applications of different types of material. Combining organic and inorganic particles in a polymer matrix has not been reported. This innovation will strengthen our position in research into advanced materials, which is a national research priority.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0883017
Funder
Australian Research Council
Funding Amount
$300,000.00
Summary
Advanced processing and characterisation facility for functional polymers and polymer nanofibres. The pilot-scale processing and advanced characterisation facility will significantly strengthen R&D capacity for innovative research and development of functional polymers and polymer nanofibres, hence adding value to the $10-billion plus market for plastics, rubber and biopolymers manufactured and used in Australia. It will further strengthen Australia's position in polymer and nanofibre research a ....Advanced processing and characterisation facility for functional polymers and polymer nanofibres. The pilot-scale processing and advanced characterisation facility will significantly strengthen R&D capacity for innovative research and development of functional polymers and polymer nanofibres, hence adding value to the $10-billion plus market for plastics, rubber and biopolymers manufactured and used in Australia. It will further strengthen Australia's position in polymer and nanofibre research and innovation.Read moreRead less
A Mechanistic Approach to the Compression Properties of Z-Pinned Composites. The proposed research is a fundamental investigation of the compressive mechanical properties and failure mechanisms of fibre reinforced polymer (FRP) composites reinforced with z-pins. These composites are a new material with strong potential applications in aerospace structures subject to high compressive loads, however their compressive properties are poorly understood. Using theoretical modelling, finite element an ....A Mechanistic Approach to the Compression Properties of Z-Pinned Composites. The proposed research is a fundamental investigation of the compressive mechanical properties and failure mechanisms of fibre reinforced polymer (FRP) composites reinforced with z-pins. These composites are a new material with strong potential applications in aerospace structures subject to high compressive loads, however their compressive properties are poorly understood. Using theoretical modelling, finite element analysis and experimentation, the research program will greatly enhance the fundamental understanding of the strengthening and failure mechanisms of z-pinned composites. A key outcome of the research will be design guidelines for optimising the pinning of composites for maximum structural performance in aerospace applications.Read moreRead less
Crystalline Mesoporous Metal Oxides for Solid Oxide Fuel Cell Electrodes. Our crystalline mesoporous electrodes will help realise the full potentials of solid oxide fuel cells. Such advanced fuel cell technology will drastically increase the power generation efficiency, and reduce CO2 emissions from present power plants, thereby transforming Australian energy industry and improving our environment. The design and development of novel crystalline mesoporous materials that find widespread industri ....Crystalline Mesoporous Metal Oxides for Solid Oxide Fuel Cell Electrodes. Our crystalline mesoporous electrodes will help realise the full potentials of solid oxide fuel cells. Such advanced fuel cell technology will drastically increase the power generation efficiency, and reduce CO2 emissions from present power plants, thereby transforming Australian energy industry and improving our environment. The design and development of novel crystalline mesoporous materials that find widespread industrial applications will advance Australia's knowledge and skill base, and help Australia's high-tech industries to stay competitive, including the development of new high-tech industries in Australia.Read moreRead less
Polymerization of amyloid fibrils and electroactive hybrid nanowires using ionic liquids. The electronics world is constantly shrinking with devices being miniaturised and increasing levels of complexity built in. To maintain this trend, new technologies and new device fabrication approaches are required. APD Byrne, will develop new materials based on amyloid fibrils by their facile conversion to a range of novel high strength electroactive nanoscopic wires with application in many electronic d ....Polymerization of amyloid fibrils and electroactive hybrid nanowires using ionic liquids. The electronics world is constantly shrinking with devices being miniaturised and increasing levels of complexity built in. To maintain this trend, new technologies and new device fabrication approaches are required. APD Byrne, will develop new materials based on amyloid fibrils by their facile conversion to a range of novel high strength electroactive nanoscopic wires with application in many electronic devices. One such device that will benefit from these nanowires is organic solar cells. Solar is a clean renewable energy source that can reduce Australia's dependence on fossil fuels. The development of new approaches and materials aimed at increasing solar cell efficiencies is an important outcome for Australia.Read moreRead less