Unravelling mechanisms in plasma growth of polymers. Surface engineering broadens the breadth of applications for many materials, and enhances the performance and value of current and emerging technologies. Surface engineering is particularly important to maintaining the competitiveness of manufacturing in developed economies such as Australia, that can not compete on a cost basis with emerging economies. Plasma coating replaces (alternative) environmentally-questionable surface treatments. This ....Unravelling mechanisms in plasma growth of polymers. Surface engineering broadens the breadth of applications for many materials, and enhances the performance and value of current and emerging technologies. Surface engineering is particularly important to maintaining the competitiveness of manufacturing in developed economies such as Australia, that can not compete on a cost basis with emerging economies. Plasma coating replaces (alternative) environmentally-questionable surface treatments. This project enhances Australian competitiveness; it cuts across industrial sectors and will deliver the new knowledge required to enhance material/technology functionality/performance. A PhD student will receive a multi-disciplinary training in a frontier technology and advanced analytical tools.Read moreRead less
Novel Biomimetic Nanosprings:Protein-based Elastomer for Engineering Applications. The ability to produce biomimetic elastomeric components with approximately infinite fatigue life offers significant impact on energy consumption and materials usage. In this project, we seek this goal by bio-macromolecular modification and understanding of the unique proteins from a number of different insects that provide the structural basis of novel bioelastomers with outstanding in-vitro fatigue properties. T ....Novel Biomimetic Nanosprings:Protein-based Elastomer for Engineering Applications. The ability to produce biomimetic elastomeric components with approximately infinite fatigue life offers significant impact on energy consumption and materials usage. In this project, we seek this goal by bio-macromolecular modification and understanding of the unique proteins from a number of different insects that provide the structural basis of novel bioelastomers with outstanding in-vitro fatigue properties. The project will translate the superior in-vivo properties of these proteins to real-world novel bioelastomers for engineering applications. Such functional materials will find potential use in areas such as microelectromechanical devices (MEMS), actuators, artificial muscles, drug delivery vehicles, etc.Read moreRead less
Preventing biological growth – a new generation anti-biofouling coatings. The project aims to improve anti-biofouling technology by developing a ‘smart and green’ coating that requires no toxic biocides and makes use of copper already present in the water. Biofouling is the unwanted attachment and growth on surfaces in water; it causes significant problems on ships and in drinking water systems, and damages infrastructure and capital investment. Biofouling also carries a significant risk of spre ....Preventing biological growth – a new generation anti-biofouling coatings. The project aims to improve anti-biofouling technology by developing a ‘smart and green’ coating that requires no toxic biocides and makes use of copper already present in the water. Biofouling is the unwanted attachment and growth on surfaces in water; it causes significant problems on ships and in drinking water systems, and damages infrastructure and capital investment. Biofouling also carries a significant risk of spreading diseases and environmental damage through the introduction of invasive marine species. Existing coatings release highly toxic substances into the water, causing untold environmental damage. This project offers a single, comprehensive solution for all of the above problems.Read moreRead less
The development of super-toughened epoxies using a novel nanomaterial. Epoxy resins are widely used as structural adhesives and coatings in engineering structures. This project will address the problem of the intrinsic brittleness of epoxy by making it significantly tougher with superior performance and cost-effectiveness. Our technology for producing super-toughened epoxy will lead to a wide range of applications for new and existing products in the construction, automotive, aerospace, adhesive ....The development of super-toughened epoxies using a novel nanomaterial. Epoxy resins are widely used as structural adhesives and coatings in engineering structures. This project will address the problem of the intrinsic brittleness of epoxy by making it significantly tougher with superior performance and cost-effectiveness. Our technology for producing super-toughened epoxy will lead to a wide range of applications for new and existing products in the construction, automotive, aerospace, adhesive and microelectronics industries.Read moreRead less
Environmentally benign polymer solar cells. The project aims to prepare polymer solar cells, by developing water-compatible conjugated materials for the active layer. This technology would be cost-efficient and not use environmentally harmful solvents. The project would achieve aqueous compatibility of these hydrophobic molecules through substitution and careful positioning of functional groups. Fabrication processes will be optimised to incorporate these materials into solar cells, with a focus ....Environmentally benign polymer solar cells. The project aims to prepare polymer solar cells, by developing water-compatible conjugated materials for the active layer. This technology would be cost-efficient and not use environmentally harmful solvents. The project would achieve aqueous compatibility of these hydrophobic molecules through substitution and careful positioning of functional groups. Fabrication processes will be optimised to incorporate these materials into solar cells, with a focus on controlling the morphology of the active material. Determining the relationships between conjugated molecular design and cell performance should provide a new direction in solar-cell technology.Read moreRead less
Develop materials for stable and efficient printed polymer solar cells. The project aims to develop strategies to overcome current limitations of polymer solar cells by enhancing the thermal stability of these devices. This project expects to generate new knowledge in the area of stable and high-performance polymer solar cells, that can be manufactured by the printing industry in Australia. The expected outcome of this project includes new high performing materials, processing and additive strat ....Develop materials for stable and efficient printed polymer solar cells. The project aims to develop strategies to overcome current limitations of polymer solar cells by enhancing the thermal stability of these devices. This project expects to generate new knowledge in the area of stable and high-performance polymer solar cells, that can be manufactured by the printing industry in Australia. The expected outcome of this project includes new high performing materials, processing and additive strategies to overcome the key challenge to commercialising polymer solar cells. A significant benefit is their printability, providing the opportunity to establish a sovereign capability to manufacture low cost energy production systems in Australia.
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A Novel Approach to Polymer/Nanosheet Composites and Their Fundamentals. Multifunctional Polymer/nanosheet composites have not yet been widely scaled up in polymer processing and composite industries mainly due to cost and inhaling hazard. This project proposes a novel methodology which embeds nanosheet preparation within polymer melt to both remove the inhaling hazard and lower the cost; the key is to develop two groups of nanosheet intercalation compounds which can expand at the polymer proces ....A Novel Approach to Polymer/Nanosheet Composites and Their Fundamentals. Multifunctional Polymer/nanosheet composites have not yet been widely scaled up in polymer processing and composite industries mainly due to cost and inhaling hazard. This project proposes a novel methodology which embeds nanosheet preparation within polymer melt to both remove the inhaling hazard and lower the cost; the key is to develop two groups of nanosheet intercalation compounds which can expand at the polymer processing temperature, to exfoliate and disperse nanosheets in polymers. It is expected to generate new knowledge of the structure-property relationships and fracture mechanisms of these composites, for industry to scale up this technology and to develop new product.Read moreRead less
Folding polymers for high-performance energy storage. This project aims to address the current bottleneck of energy storage capability in polymers by developing new compact structures through programmed polymer folding. This project expects to understand how structures determine electrochemistry properties by creating densely packed redox-active polymers to break the limits of charge transfer rates and storage ability. Expected outcomes include deep insights into fundamental electrochemical reac ....Folding polymers for high-performance energy storage. This project aims to address the current bottleneck of energy storage capability in polymers by developing new compact structures through programmed polymer folding. This project expects to understand how structures determine electrochemistry properties by creating densely packed redox-active polymers to break the limits of charge transfer rates and storage ability. Expected outcomes include deep insights into fundamental electrochemical reaction mechanisms, laying a strong foundation for the applications of polymers from flexible electronic devices to micro-grid energy storage. This project should provide significant benefit in new knowledge and support advanced manufacturing using our high value-added materials.Read moreRead less
New bar-encoded polymer microbeads for multiplexed bioanalysis-a quick and high-throughput approach for complex disease diagnosis. Distinguishable new bar-encoded (element-encoded) polymer microbeads associated with a mass spectroscopy-flow cytometer detector provide a novel platform for highly multiplexed biological analysis. Such an approach can simultaneously identify many non-self-agents at low concentrations, which facilitates early-stage complex disease diagnosis.
Electrowetting as a tool for measuring the surface energy of solids. Ionic liquids can be forced to spread over hydrophobic surfaces by applying an electric field, thus overwriting their natural tendency to bead. This phenomenon, called electrowetting, can be used to manipulate liquids but also to determine the surface energy of the solid surface which is a key design parameter in many applications.