Group 13 Mixed Halide-Hydride and Rare Earth Complexes - New Selective Chiral Hydridic or Low Valent Reducing Agents. This project will make a landmark contribution to two areas of metallohydride chemistry. Both studies will utilise and develop metals that have traditionally been mined and exported from these shores while concurrently imported as value added products at vastly inflated cost. This research will identify knock-on applications in order to stem this financial bias. The new paths to ....Group 13 Mixed Halide-Hydride and Rare Earth Complexes - New Selective Chiral Hydridic or Low Valent Reducing Agents. This project will make a landmark contribution to two areas of metallohydride chemistry. Both studies will utilise and develop metals that have traditionally been mined and exported from these shores while concurrently imported as value added products at vastly inflated cost. This research will identify knock-on applications in order to stem this financial bias. The new paths to rare earth (= Ln) hydrides will have broad industrial appeal, particularly for new materials, where, like similar group 13 materials, they may be used in the deposition of Ln films or even as precursors to superconducting solids. It is anticipated industrial collaboration will ensue. Australia will be promoted as a developer and innovator of frontier technologies.Read moreRead less
Generation of Novel Fermentation Products and their Exploitation in the Synthesis of Biologically Active Organic Compounds with Therapeutic Potential. Collections of new micro-organisms and their metabolites suitable for use in the chemical synthesis programs will emerge from the proposed research. This will provide a potentially highly-valuable national resource that could serve the needs of many laboratories around Australia by allowing them to establish more direct routes to target molecules ....Generation of Novel Fermentation Products and their Exploitation in the Synthesis of Biologically Active Organic Compounds with Therapeutic Potential. Collections of new micro-organisms and their metabolites suitable for use in the chemical synthesis programs will emerge from the proposed research. This will provide a potentially highly-valuable national resource that could serve the needs of many laboratories around Australia by allowing them to establish more direct routes to target molecules being sought in the development of new therapeutic agents and/or materials. The combined application of molecular biological, microbiological and chemical synthesis techniques in a concerted manner in the one location will lead to a raft of new opportunities for the biotech and pharmaceutical industries in Australia.Read moreRead less
Self-Assembly of Nanoscale Molecular Capsules. Nature uses the self-assembly of molecules for the construction of highly complex and functional structures. An understanding of this process will enable the design of new molecular systems, capable of application in areas that include medicine, electronics and communications. Such self-assembly will play a key role in the development of nanotechnology, a rapidly expanding field that is likely to become a major technology in the foreseeable future. ....Self-Assembly of Nanoscale Molecular Capsules. Nature uses the self-assembly of molecules for the construction of highly complex and functional structures. An understanding of this process will enable the design of new molecular systems, capable of application in areas that include medicine, electronics and communications. Such self-assembly will play a key role in the development of nanotechnology, a rapidly expanding field that is likely to become a major technology in the foreseeable future. It is of crucial importance for Australia to maintain cutting-edge research (and research training) in this area if the nation and its industries are to be active contributors to the coming revolution.Read moreRead less
ARC Centre of Excellence - Centre for Free Radical Chemistry and Biotechnology. Free radical chemistry is of increasing importance in the manufacture of improved plastics, paints and related materials, in helping restrict oxidative processes that can lead to adverse human health and also to the degradation of important industrial materials. The research will contribute to promoting & maintaining good health by developing new methods for reducing the impacts of ageing as well as in the treatment ....ARC Centre of Excellence - Centre for Free Radical Chemistry and Biotechnology. Free radical chemistry is of increasing importance in the manufacture of improved plastics, paints and related materials, in helping restrict oxidative processes that can lead to adverse human health and also to the degradation of important industrial materials. The research will contribute to promoting & maintaining good health by developing new methods for reducing the impacts of ageing as well as in the treatment of several life-threatening conditions such as stroke. Industrial applications include better surface coatings for preserving metals, and additives to improve the quality and shelf life of beer and wines.Read moreRead less
Biodegradable Porous HEMA-Based Polymers: Innovative Strategies for the Design and Tuneable Single-Step Production of a Novel Class of Scaffolds for Tissue Engineering. This project will lead to the development of new biocompatible, biodegradable, porous materials ideally suited to many applications in tissue engineering. These new biomaterials will be relatively inexpensive to manufacture, via simple processes using non-toxic reagents. The key properties of the biomaterials will be controllable ....Biodegradable Porous HEMA-Based Polymers: Innovative Strategies for the Design and Tuneable Single-Step Production of a Novel Class of Scaffolds for Tissue Engineering. This project will lead to the development of new biocompatible, biodegradable, porous materials ideally suited to many applications in tissue engineering. These new biomaterials will be relatively inexpensive to manufacture, via simple processes using non-toxic reagents. The key properties of the biomaterials will be controllable by appropriate choice of starting materials. The availability of these new biomaterials will facilitate future developments in tissue engineering, which will ultimately lead to improved medical outcomes in areas as diverse as joint and bone repair and organ regeneration. Local manufacture of these biomaterials would also contribute to the development of the Australian biotechnology industry.Read moreRead less
Integrated self assembly processes and spinning disc reactor technology. Spinning Disc Reactor technology is new to Australia and will have wide ranging applications in nano-technology and in developing benign industrial chemical processes with smaller footprint and significantly reduced capital outlay. The cutting edge research will foster collaboration with industry, and lead to establishing new industries in device technology, smart materials, health care products, catalysis and energy storag ....Integrated self assembly processes and spinning disc reactor technology. Spinning Disc Reactor technology is new to Australia and will have wide ranging applications in nano-technology and in developing benign industrial chemical processes with smaller footprint and significantly reduced capital outlay. The cutting edge research will foster collaboration with industry, and lead to establishing new industries in device technology, smart materials, health care products, catalysis and energy storage, through exploiting commercial opportunities. The project will provide excellent research training in a range of scientific skills and in professional development, and will involve overseas PhD exchange programs. The exciting research incorporating benign metrics will enhance public opinion towards science. Read moreRead less
The chemical, biochemical, genetic and ecological basis of pollinator-driven speciation in Australian sexually deceptive orchids. The Australian biota offers unique opportunities for illuminating ecological and evolutionary processes of worldwide importance. Focussing on Australian sexually deceptive orchids, this study offers a model system for studies of plant speciation that has already captured the interest of the public, educators and scientists around the world. The project will produce mu ....The chemical, biochemical, genetic and ecological basis of pollinator-driven speciation in Australian sexually deceptive orchids. The Australian biota offers unique opportunities for illuminating ecological and evolutionary processes of worldwide importance. Focussing on Australian sexually deceptive orchids, this study offers a model system for studies of plant speciation that has already captured the interest of the public, educators and scientists around the world. The project will produce multiple graduate students with high quality, cross-disciplinary training. Expertise and tools developed will contribute directly to the conservation of endangered Australian orchids. Thus the knowledge obtained from this research will have immediate practical benefits for the sustainable use of Australia's biodiversity.Read moreRead less
Control of the Enantiomeric Self-Resolution Process. The availability of enantiopure molecules is crucial in chemistry and medicine. Enantiomeric self-resolution on crystallisation provides pure left- and right-handed molecules from 1:1 mixtures of the two. It is the simplest and cheapest means of obtaining enantiopure molecules, but its occurrence in any given case cannot normally be
predicted. The understanding and control of the self-resolution process gained through this project will repre ....Control of the Enantiomeric Self-Resolution Process. The availability of enantiopure molecules is crucial in chemistry and medicine. Enantiomeric self-resolution on crystallisation provides pure left- and right-handed molecules from 1:1 mixtures of the two. It is the simplest and cheapest means of obtaining enantiopure molecules, but its occurrence in any given case cannot normally be
predicted. The understanding and control of the self-resolution process gained through this project will represent a major breakthrough in organic and pharmaceutical chemistry. This technological advance will make pure handed molecules available readily and cheaply, thereby allowing chemical, pharmaceutical and biological developments to be made by Australian industry.
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Advanced Ionic Materials for Organic Photovoltaics. Australia will greatly benefit from the development of improved solar energy technology, as a means of addressing the issue of climate change as a result of continued fossil fuel use. Solar power is also advantageous as it also allows electricity to be generated locally where it is needed, which is particularly important for the many remote areas of Australia. The climate in Australia is ideally suited for the electricity production through pho ....Advanced Ionic Materials for Organic Photovoltaics. Australia will greatly benefit from the development of improved solar energy technology, as a means of addressing the issue of climate change as a result of continued fossil fuel use. Solar power is also advantageous as it also allows electricity to be generated locally where it is needed, which is particularly important for the many remote areas of Australia. The climate in Australia is ideally suited for the electricity production through photovoltaics, and this project will focus on improving the performance of these devices to enable their widespread use. Read moreRead less
Microreactors for Organic Synthesis. Since the electronic revolution, miniaturisation has been the trend for devices from consumer electronics to scientific instruments. In this time very little has changed in the manner, or scale, that synthetic organic chemistry has been carried out even though advances in instrumentation mean that less compound is required for identification and analysis. This project aims to bridge the gap by developing recyclable miniaturised reaction vessels for the format ....Microreactors for Organic Synthesis. Since the electronic revolution, miniaturisation has been the trend for devices from consumer electronics to scientific instruments. In this time very little has changed in the manner, or scale, that synthetic organic chemistry has been carried out even though advances in instrumentation mean that less compound is required for identification and analysis. This project aims to bridge the gap by developing recyclable miniaturised reaction vessels for the formation of organic compounds on a scale thousands of times smaller than it is currently done. These devices will have applications in drug discovery programmes due to higher throughput and increased efficiency while minimising waste.Read moreRead less