Nanomagnetic Molecular Materials. This research project involves the preparation of new molecular magnets using metals such as manganese and vanadium and a study of their physical properties. Metal compounds of the cluster type are significant since they are nanoscale in size and offer new quantum features, with an improved understanding of the magnetic properties as a primary outcome and long term possible use in future quantum computers. This fundamental study provides excellent training to p ....Nanomagnetic Molecular Materials. This research project involves the preparation of new molecular magnets using metals such as manganese and vanadium and a study of their physical properties. Metal compounds of the cluster type are significant since they are nanoscale in size and offer new quantum features, with an improved understanding of the magnetic properties as a primary outcome and long term possible use in future quantum computers. This fundamental study provides excellent training to post-graduate students and makes them ideally suited to take jobs in advanced materials, an area being emphasised in Australia's nanotechnological future.Read moreRead less
Nanomagnetic Materials from Molecular Clusters and Coordination Polymers. Magnetic materials are important through their use in recording tapes and other electronic devices. Traditional magnetic materials are metals, alloys or metal oxides made by high temperature methods. Our aims are to synthesize new chemical and molecule based solid materials which possess the properties of traditional magnets but which are made by careful chemical design at ambient temperatures. We will make materials which ....Nanomagnetic Materials from Molecular Clusters and Coordination Polymers. Magnetic materials are important through their use in recording tapes and other electronic devices. Traditional magnetic materials are metals, alloys or metal oxides made by high temperature methods. Our aims are to synthesize new chemical and molecule based solid materials which possess the properties of traditional magnets but which are made by careful chemical design at ambient temperatures. We will make materials which have three-dimensional network structures or large clusters of ions such as manganese bridged by organic molecules. Their magnetic properties will be studied in detail. The cluster compounds are significant since they are nanoscale in size and offer new features, with long term possible use in future quantum computers.Read moreRead less
Synthesis and Fundamental Understanding of Low-Dimensional Metal Oxide Nanoparticles for Gas Sensing Application. This project is primarily devoted to material science and nanotechnology, one of the cutting-edge areas in Australia's National Research Priority. Successful completion of this project will result in controlled synthesis, functional assembly and fundamental understanding of low-dimensional metal oxide nanostructures. The research findings will be useful for developing new and complex ....Synthesis and Fundamental Understanding of Low-Dimensional Metal Oxide Nanoparticles for Gas Sensing Application. This project is primarily devoted to material science and nanotechnology, one of the cutting-edge areas in Australia's National Research Priority. Successful completion of this project will result in controlled synthesis, functional assembly and fundamental understanding of low-dimensional metal oxide nanostructures. The research findings will be useful for developing new and complex nanostructures for functional applications in lithium ionic batteries, catalysts and gas sensors. The conduct of this project will significantly expand the knowledge creativity of Australia in advanced materials.
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Reactions of Coordinated Dinitrogen. The program will develop novel metal-based catalysts and reagents that will transform nitrogen gas into ammonia and other nitrogen-containing compounds (nitrogen fixation). This fundamental chemical transformation underpins major chemical industries and this new approach using organometallic catalysts will significantly improve the efficiency of ammonia production and reduce the energy and harsh reaction conditions currently required. This program will desi ....Reactions of Coordinated Dinitrogen. The program will develop novel metal-based catalysts and reagents that will transform nitrogen gas into ammonia and other nitrogen-containing compounds (nitrogen fixation). This fundamental chemical transformation underpins major chemical industries and this new approach using organometallic catalysts will significantly improve the efficiency of ammonia production and reduce the energy and harsh reaction conditions currently required. This program will design catalysts with multiple complementary metal centres tailored to bind and activate nitrogen gas to facilitate its reaction with hydrogen or other reagents.Read moreRead less
Synthetic and theoretical studies of metal complexes containing carbon-rich ligands. Previous studies in my group, in conjunction with synthetic and theoretical chemistry groups at the Université de Rennes 1, France, have delineated the properties of a series of complexes containing carbon chains linking two metal centres. Having achieved a partial understanding of the features which result in good electronic communication between the metal centres via the carbon chain, the present proposal see ....Synthetic and theoretical studies of metal complexes containing carbon-rich ligands. Previous studies in my group, in conjunction with synthetic and theoretical chemistry groups at the Université de Rennes 1, France, have delineated the properties of a series of complexes containing carbon chains linking two metal centres. Having achieved a partial understanding of the features which result in good electronic communication between the metal centres via the carbon chain, the present proposal seeks to extend this collaboration to further studies which will generate related compounds in which actual eletron exchange can occur, i.e. leading to oxidation/reduction, by using compounds in which two or more different metal centres are present. This may lead to development of nano devices, e.g. molecular-scale switches. If one of the centres is activated by light, a photo-active sensor may result.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989127
Funder
Australian Research Council
Funding Amount
$400,000.00
Summary
A High-Throughput Neutron Spectrometer for The Study of Atomic and Molecular Motion at ANSTO. Neutron scattering enables new science across a broad range of disciplines, and for this reason it is undergoing major expansion in the USA, Europe, Japan and Australia. Various diffactometers and spectrometers have recently been built at ANSTO, but an instrumental option for a high-throughput cross-discipline spectroscopy is urgently needed. Fortunately, it is fairly straightforward to add this type of ....A High-Throughput Neutron Spectrometer for The Study of Atomic and Molecular Motion at ANSTO. Neutron scattering enables new science across a broad range of disciplines, and for this reason it is undergoing major expansion in the USA, Europe, Japan and Australia. Various diffactometers and spectrometers have recently been built at ANSTO, but an instrumental option for a high-throughput cross-discipline spectroscopy is urgently needed. Fortunately, it is fairly straightforward to add this type of option to an existing spectrometer that will broaden its user-base from specialised applications in physics to more general applications in physics, chemistry, materials-science and biology. This additional option provides a totally new way for Australian scientists to study atomic and molecular motions. Read moreRead less
Poly-crystalline Thin Films for LASER Applications. This project is based on a recent discovery which reports LASER emission in disordered media such as polycrystalline ZnO. This behaviour appears to be related to the crystallographic properties of ZnO (wurztite) material. Using a novel deposition process the defect density, size of crystallites and macroscopic orientation within such thin films will be controlled independently. This will provide an opportunity to study the fundamental basis of ....Poly-crystalline Thin Films for LASER Applications. This project is based on a recent discovery which reports LASER emission in disordered media such as polycrystalline ZnO. This behaviour appears to be related to the crystallographic properties of ZnO (wurztite) material. Using a novel deposition process the defect density, size of crystallites and macroscopic orientation within such thin films will be controlled independently. This will provide an opportunity to study the fundamental basis of such behaviour. In conjunction with this the development of structure in similarly produced GaN (wurztite) films will be examined. This work should also provide practical information concerning the potential performance of LASER devices based on disordered materials.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
Understanding, prediction and control of polymorphism in pharmaceuticals. The proposed research will lead, through a better understanding of polymorphism, to more efficient production of pharmaceuticals and will enhance the establishment and protection of patents. The work will have flow-on in other areas such as the manufacture of pigments, dyes and explosives. The project uses methodology for the elucidation of local structure and function at the atomic to nanoscale level in which Australia is ....Understanding, prediction and control of polymorphism in pharmaceuticals. The proposed research will lead, through a better understanding of polymorphism, to more efficient production of pharmaceuticals and will enhance the establishment and protection of patents. The work will have flow-on in other areas such as the manufacture of pigments, dyes and explosives. The project uses methodology for the elucidation of local structure and function at the atomic to nanoscale level in which Australia is a world leader. The project will further enhance our standing in this field and will provide excellent research training opportunities in areas particularly pertinent to future exploitation of the Australian Synchrotron and the new Research Reactor OPAL, which open in 2007. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0668017
Funder
Australian Research Council
Funding Amount
$1,047,000.00
Summary
Membrane Protein Structure and Interaction Facility. While it is estimated that a third of the human genome encodes for membrane proteins, the structures of only relatively few membrane proteins are currently known. It will be some time before membrane protein structure determination becomes routine, yet over 50% of the drugs on the market today rely on the activity of membrane proteins for their efficacy. This application seeks to establish a Membrane Protein Structure and Interaction Facility ....Membrane Protein Structure and Interaction Facility. While it is estimated that a third of the human genome encodes for membrane proteins, the structures of only relatively few membrane proteins are currently known. It will be some time before membrane protein structure determination becomes routine, yet over 50% of the drugs on the market today rely on the activity of membrane proteins for their efficacy. This application seeks to establish a Membrane Protein Structure and Interaction Facility for the development and application of novel techniques and approaches to study the structure and interactions of membrane proteins. Research progress will be greatly enhanced by the establishment of this dedicated facility with cutting-edge technologies for the study of membrane proteins.Read moreRead less