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Function-driven Synthesis and Assembly of Two-dimensional Metal Nanostructures. The project is fundamentally concerned with material science and nanotechnology, one of the cutting-edge areas in Australia's National Research Priority. Successful completion of the project will result in controlled synthesis, functional assembly and their fundamental understanding of metal nanostructures. The research findings will be useful for developments of new nanomaterials and applications to optoelectronics, ....Function-driven Synthesis and Assembly of Two-dimensional Metal Nanostructures. The project is fundamentally concerned with material science and nanotechnology, one of the cutting-edge areas in Australia's National Research Priority. Successful completion of the project will result in controlled synthesis, functional assembly and their fundamental understanding of metal nanostructures. The research findings will be useful for developments of new nanomaterials and applications to optoelectronics, molecular electronics and biochemical sensor systems. They can also greatly increase the scientific understanding of particle behaviour in relation to process control, and expand the knowledge creativity of Australia in research in these materials.Read moreRead less
Development of Novel Nanostructured Electro-optical Systems. The development of flexible and conformal electro-optical systems will strengthen Australia's position in the automotive industry establishing a value adding technology. The auto-dimming mirror industry is worth in excess of US$500 million per annum, with predictions of industry sales of US$2 billion. This project will tap existing Australian manufacturing capabilities and utilise the intellectual capacity of internationally recognise ....Development of Novel Nanostructured Electro-optical Systems. The development of flexible and conformal electro-optical systems will strengthen Australia's position in the automotive industry establishing a value adding technology. The auto-dimming mirror industry is worth in excess of US$500 million per annum, with predictions of industry sales of US$2 billion. This project will tap existing Australian manufacturing capabilities and utilise the intellectual capacity of internationally recognised scientists from UoW and UniSA. The science behind this proposed development will have significance well beyond its initial scope with applications in areas such as ophthalmic lenses, architectural glazing and electronic textiles providing further Australian opportunities in these rapidly developing areas.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0239943
Funder
Australian Research Council
Funding Amount
$245,000.00
Summary
Access for Australian Researchers to Advanced Neutron-Beam Technique. Neutron scattering is one of the most powerful and important investigative tools in the study of materials. Australia has only a low-flux neutron source, HIFAR, which provides no cold or hot neutrons. This excludes large, important areas of science, such as functional films, polymers, self-assembly systems, biological materials, colloids and emulsions, and real-time in-situ studies.
This application aims to continue Aus ....Access for Australian Researchers to Advanced Neutron-Beam Technique. Neutron scattering is one of the most powerful and important investigative tools in the study of materials. Australia has only a low-flux neutron source, HIFAR, which provides no cold or hot neutrons. This excludes large, important areas of science, such as functional films, polymers, self-assembly systems, biological materials, colloids and emulsions, and real-time in-situ studies.
This application aims to continue Australia's parnership with the world's most intense neutron source, ISIS in the UK, in order to sustain the considerable Australian scientific momentum which now relies on ISIS.
The outcome will be new science that cannot be generated solely within Australia.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0453524
Funder
Australian Research Council
Funding Amount
$321,456.00
Summary
The Centre for Advanced Light Microscopy: Equipment for in-vivo multiphoton microscopy and high-throughput confocal microscopy. The Centre for Advanced Light Microscopy was established with ARC RIEF funding and is currently experiencing overwhelming demand as the sole confocal provider for 260 researchers at multiple institutions in south-east Queensland. The present joint application of the Universities of Queensland and Southern Queensland seeks to build on the resounding success of the origi ....The Centre for Advanced Light Microscopy: Equipment for in-vivo multiphoton microscopy and high-throughput confocal microscopy. The Centre for Advanced Light Microscopy was established with ARC RIEF funding and is currently experiencing overwhelming demand as the sole confocal provider for 260 researchers at multiple institutions in south-east Queensland. The present joint application of the Universities of Queensland and Southern Queensland seeks to build on the resounding success of the original initiative by introducing state-of-the-art confocal and multiphoton applications. This powerful platform technology will allow structural and functional information to be obtained from sensitive live samples with unprecedented spatial and temporal resolution, augmenting and accelerating vital research in the biosciences.
Read moreRead less
Controlled Crystallisation of Bioactives. The new technologies developed in this project for bioactive recovery and particle design will allow the development of new value added products for Australia's growing biotechnology industry, especially in pharmaceuticals, neutraceuticals and functional foods. Two PhD students will receive excellent research training to then move into research and development in these industries.
Particle Design for Recovery and Delivery of Bioactives. This project will develop new strategies for economically viable recovery of bioactives from complex solutions, slurries and sludges of biomaterials eg. waste streams from milk and soy bean processing, and fermentation broths. These bioactives, often proteins, have growing applications as high value drugs, nutriceuticals and food additives but are difficult to separate and to maintain in an active form. Crystallisation will be used as a ....Particle Design for Recovery and Delivery of Bioactives. This project will develop new strategies for economically viable recovery of bioactives from complex solutions, slurries and sludges of biomaterials eg. waste streams from milk and soy bean processing, and fermentation broths. These bioactives, often proteins, have growing applications as high value drugs, nutriceuticals and food additives but are difficult to separate and to maintain in an active form. Crystallisation will be used as a primary separation technique. Molecular studies of protein interactions will be used to predict good crystallisation conditions and linked to process crystallisation studies. Both standard and novel particle design strategies will be used to control crystal size and morphology, as well as package the boactive in a deliverable form without loss of activity.Read moreRead less
Particle design and recovery of bioactives by crystallisation and precipitation. This project will develop new strategies for economically viable recovery of bioactives from complex solutions of biomaterials eg. separation of biopharmaceuticals from genetically engineered cell culture, food ingredient processing, functional food and nutraceutical extraction from natural sources. Crystallisation and precipitation will be used as primary separation techniques. We propose a new paradigm in which ....Particle design and recovery of bioactives by crystallisation and precipitation. This project will develop new strategies for economically viable recovery of bioactives from complex solutions of biomaterials eg. separation of biopharmaceuticals from genetically engineered cell culture, food ingredient processing, functional food and nutraceutical extraction from natural sources. Crystallisation and precipitation will be used as primary separation techniques. We propose a new paradigm in which molecular studies of protein interactions will be used to predict good crystallisation conditions and linked to process crystalliation studies. Studies will use a model system of egg white protein mixtures and a real system of industrial importance - the purification of valuable protein products from soy beans (valued at $500 million per year world wide). Soy beans studies will include pilot scale tests at Dupont's industrial reseach laboratories.Read moreRead less
New Enantiomeric Separation Technologies for Natural Product, Pharmaceuticals and Environmental Pollutant Characterisation. Enantiomeric characterisation allows evaluation of drug purity for potentially harmful constituents, consumer protection against adulteration of essential oils and natural materials, and study of chemical interactions in biochemical/environmental systems. Chromatograph technologies (GC, HPLC and CE)for enantioseparation are available, however limitations prevent multicompon ....New Enantiomeric Separation Technologies for Natural Product, Pharmaceuticals and Environmental Pollutant Characterisation. Enantiomeric characterisation allows evaluation of drug purity for potentially harmful constituents, consumer protection against adulteration of essential oils and natural materials, and study of chemical interactions in biochemical/environmental systems. Chromatograph technologies (GC, HPLC and CE)for enantioseparation are available, however limitations prevent multicomponent characterisation of complete sample mixtures. Critical choices involve: choosing a chiral selector that interacts differentially upon all enantiomers; incorporation of selector into high-efficiency chromatographic systems; application to all target compounds in the sample. We will synthesise novel chiral selectors, incorporate these into new separation columns, apply ultra-high resolution 2-dimensional GCxGC to broad-spectrum chiral analysis of volatile chemical samples.Read moreRead less
Novel hybrid agricultural-byproduct/synthetic materials. The French partners have developed a method of converting low-value agricultural by-products into commodity plastics; however, the results are too water-sensitive to be useful. This project is to develop the science for grafting water-resistant moieties to this product, using mechanistically-based techniques developed by the Sydney group. The outcome would be technology for making useful materials from agricultural by-products that are cur ....Novel hybrid agricultural-byproduct/synthetic materials. The French partners have developed a method of converting low-value agricultural by-products into commodity plastics; however, the results are too water-sensitive to be useful. This project is to develop the science for grafting water-resistant moieties to this product, using mechanistically-based techniques developed by the Sydney group. The outcome would be technology for making useful materials from agricultural by-products that are currently of very low value in Australia.Read moreRead less
Establishing the relations between starch nano- and mesostructure and macroscopic physical properties. Starch is the major energy component within human diets, and the most abundant polymer that can be readily extracted from annual crop plants, leading to many actual and potential industrial applications. There are major opportunities to optimise the nutritional value of starches in the human diet, and to enhance the properties of extracted starches as renewable alternatives to petrochemical pol ....Establishing the relations between starch nano- and mesostructure and macroscopic physical properties. Starch is the major energy component within human diets, and the most abundant polymer that can be readily extracted from annual crop plants, leading to many actual and potential industrial applications. There are major opportunities to optimise the nutritional value of starches in the human diet, and to enhance the properties of extracted starches as renewable alternatives to petrochemical polymers. This project will open up our understanding of the structure of starch polymers and show how this relates to important properties such as enzyme digestibility rates, leading to new opportunities for public health and commercial benefits.Read moreRead less