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
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
New Surfaces for the Control of Endothelial Cell Function: Application in the Design of Biocompatible Stents. Using dewetting of thin polymer films, the present proposal will develop new structured biocompatible surfaces with controlled chemistry and topography, which will allow the growth of a normal (non-activated) monolayer of endothelial cells. Sophisticated molecular parameters will be used to assess that endothelial cells maintain their normal quiescent phenotype. The project sets the grou ....New Surfaces for the Control of Endothelial Cell Function: Application in the Design of Biocompatible Stents. Using dewetting of thin polymer films, the present proposal will develop new structured biocompatible surfaces with controlled chemistry and topography, which will allow the growth of a normal (non-activated) monolayer of endothelial cells. Sophisticated molecular parameters will be used to assess that endothelial cells maintain their normal quiescent phenotype. The project sets the ground work for the design of improved, more biocompatible structured stents to minimise the abnormal growth of cells on and around the stent, thereby reducing the occurrence of vascular complications. Thus this research could improve the success rate of stents implanted into patients with cardiovascular disease and reduce health costs.Read moreRead less
Materials World Network: Nanostructured Polymer Templating of Liquid Crystals. Liquid crystals have a range of technological applications, with the most successful being displays used in computers, watches and calculators. These applications are dependent on controlling the interfaces of liquid crystals. This project will combine the areas of liquid crystals and polymer adsorption for the preparation of a new class of intelligent nanomaterials with well-defined properties. These engineered mater ....Materials World Network: Nanostructured Polymer Templating of Liquid Crystals. Liquid crystals have a range of technological applications, with the most successful being displays used in computers, watches and calculators. These applications are dependent on controlling the interfaces of liquid crystals. This project will combine the areas of liquid crystals and polymer adsorption for the preparation of a new class of intelligent nanomaterials with well-defined properties. These engineered materials are of interest in industrial applications, including the development of chemical and biological sensors and drug delivery vehicles. This program also strengthens the ties between two world-class nanotechnology groups, capturing new opportunities in nanostructured materials.Read moreRead less
Engineered nanostructured materials via continuous polymer assembly for advanced bioapplications. The development of new and flexible processes is critical to the design and construction of advanced materials for future applications in nano- and biotechnology. This project will develop innovative and versatile "bottom-up" nanotechnology techniques to afford nanostructured materials with unprecedented properties. This project has the potential to revolutionise current approaches for forming surfa ....Engineered nanostructured materials via continuous polymer assembly for advanced bioapplications. The development of new and flexible processes is critical to the design and construction of advanced materials for future applications in nano- and biotechnology. This project will develop innovative and versatile "bottom-up" nanotechnology techniques to afford nanostructured materials with unprecedented properties. This project has the potential to revolutionise current approaches for forming surface coatings, films and advanced particles, leading to significant outcomes in diverse areas, including drug delivery, biomaterial implants and biocatalysis. The project will contribute to the development of a robust Australian nanotechnology industry, with the advanced materials developed expected to have health benefits for Australian citizens.Read moreRead less
Building Molecularly Engineered Polymer Nanomaterials. The development of new technologies at the interface between nano- and biotechnology promises to revolutionise healthcare and medicine. This research program will involve the design and synthesis of responsive and programmable polymers and their assembly to form next-generation, engineered materials. The nanomaterials prepared are expected to lead to the development of techniques that enable new types of minimally invasive diagnostics and th ....Building Molecularly Engineered Polymer Nanomaterials. The development of new technologies at the interface between nano- and biotechnology promises to revolutionise healthcare and medicine. This research program will involve the design and synthesis of responsive and programmable polymers and their assembly to form next-generation, engineered materials. The nanomaterials prepared are expected to lead to the development of techniques that enable new types of minimally invasive diagnostics and therapeutics as well as smaller devices. The interdisciplinary research program will cement Australia's position as a leading country in nanobiotechnology research and development.Read moreRead less
Switchable interfaces. The discovery project will challenge some of the most demanding issues regarding adhesion and molecular separation: - Surfaces that can release/prevent bio-film formation can provide novel solutions for corrosion-protection, implants, anti-fouling in medical devices as well as in industrial piping and reactors. - Materials for separation on the molecular level, which can bring new possibilities for fast and selective processes to the pharmaceutical industry. The novel comb ....Switchable interfaces. The discovery project will challenge some of the most demanding issues regarding adhesion and molecular separation: - Surfaces that can release/prevent bio-film formation can provide novel solutions for corrosion-protection, implants, anti-fouling in medical devices as well as in industrial piping and reactors. - Materials for separation on the molecular level, which can bring new possibilities for fast and selective processes to the pharmaceutical industry. The novel combination of the two materials research fields - plasma-polymerisation and electroactive materials- will lead to an international capability at the forefront of separation and adhesion research.Read moreRead less
Novel Fuel-Cell Structures based on Electroactive Polymers. The Discovery Project will tackle some of the challenging issues regarding the conversion of our society into a post-petroleum era through: Development and understanding of a new class of organic catalysts for efficient low temperature fuel-cells; Developing cheap and effective, ultra-thin, ion-conducting membranes for fuel-cells based on new plasma-polymers; and Integrating the components into fuel-cells suitable for stationary, portab ....Novel Fuel-Cell Structures based on Electroactive Polymers. The Discovery Project will tackle some of the challenging issues regarding the conversion of our society into a post-petroleum era through: Development and understanding of a new class of organic catalysts for efficient low temperature fuel-cells; Developing cheap and effective, ultra-thin, ion-conducting membranes for fuel-cells based on new plasma-polymers; and Integrating the components into fuel-cells suitable for stationary, portable and automotive applications. These outcomes will contribute to national research priorities: Frontier Technologies for building and transforming Australian Industries, and An Environmentally Sustainable Australia.
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Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0560758
Funder
Australian Research Council
Funding Amount
$187,000.00
Summary
Dynamics at Interfaces: a facility for the characterisation of the dynamics of structural reorganisation and adsorption at interfaces. Controlling the flow, stability, and general performance of finely dispersed materials is important in a great number of industries from cosmetics to minerals purification. These properties are often controlled by the addition of material that forms a film at the interface between the dispersed material and the solvent. We seek to develop a facility that will ena ....Dynamics at Interfaces: a facility for the characterisation of the dynamics of structural reorganisation and adsorption at interfaces. Controlling the flow, stability, and general performance of finely dispersed materials is important in a great number of industries from cosmetics to minerals purification. These properties are often controlled by the addition of material that forms a film at the interface between the dispersed material and the solvent. We seek to develop a facility that will enable the properties of this film to be characterized, in particular the rate at which the film responds to mechanical and chemical changes. With this knowledge we hope to relate the nanoscopic properties of the adsorbed film to macroscopic properties of the dispersion and be able to tune the structure of the surface film, in order to control the bulk properties of complex fluids.Read moreRead less