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An integrated approach towards the development of new generation RF/microwave dielectric materials. The ultimate aim of this project is to rationally design and optimize new types of environmentally-sustainable, cost-effective and high performance microwave dielectric materials and devices for advanced information and communication technology (ICT) applications. This is a designated National Research Priority area. Our fundamental understanding of dielectric materials and their properties will b ....An integrated approach towards the development of new generation RF/microwave dielectric materials. The ultimate aim of this project is to rationally design and optimize new types of environmentally-sustainable, cost-effective and high performance microwave dielectric materials and devices for advanced information and communication technology (ICT) applications. This is a designated National Research Priority area. Our fundamental understanding of dielectric materials and their properties will be enhanced considerably by working on this project. Further, we will promote the relationship between the fundamental science of polar crystalline materials and practical applications. If successful, the results will enhance Australia's capacity and standing in this highly competitive area. Read moreRead less
The effects of local strain on the crystal chemistry of solid solutions. The concept of the solid solution, the substitution of one kind of atom for another in a crystal structure, is a central idea in both mineral sciences and solid state chemistry. Such atomic substitutions alter local crystal chemistry and hence always introduce strain into crystal lattices. In this project we aim to characterize this substitutional strain. Ultimately this should lead to a better understanding of the geologic ....The effects of local strain on the crystal chemistry of solid solutions. The concept of the solid solution, the substitution of one kind of atom for another in a crystal structure, is a central idea in both mineral sciences and solid state chemistry. Such atomic substitutions alter local crystal chemistry and hence always introduce strain into crystal lattices. In this project we aim to characterize this substitutional strain. Ultimately this should lead to a better understanding of the geological history of rocks, improvements in metal recovery from ores and to the design and synthesis of new materials.Read moreRead less
Design and synthesis of novel lanthanoid complexes for the fabrication of light emitting devices. There is a huge and still growing economy centred around the design and fabrication of low-cost Light Emitting Devices (LEDs), as demonstrated by the excess of US$1.3 billion invested in this field between 2000 and 2007. Nations focused on the production of new and more efficient materials will be at the forefront of these emerging technologies. The major thrust of this proposal, the design and prep ....Design and synthesis of novel lanthanoid complexes for the fabrication of light emitting devices. There is a huge and still growing economy centred around the design and fabrication of low-cost Light Emitting Devices (LEDs), as demonstrated by the excess of US$1.3 billion invested in this field between 2000 and 2007. Nations focused on the production of new and more efficient materials will be at the forefront of these emerging technologies. The major thrust of this proposal, the design and preparation of luminescent rare earths complexes, and their use for the fabrication of LEDS, represent a good opportunity for Australia to access this growing market. Read moreRead less
Cooperativity in Spin Crossover Systems: Memory, Magnetism and Microporosity. Spin-crossover centres are a well known form of inorganic electronic switch for which variation of temperature, pressure and irradiation leads to a change in d-electron configuration and therefore changes to structure, colour and magnetism. Here we aim to synthesise and study a wide variety of new spin-crossover systems where cooperativitiy between centres, induced by careful supramolecular design, will lead to molecul ....Cooperativity in Spin Crossover Systems: Memory, Magnetism and Microporosity. Spin-crossover centres are a well known form of inorganic electronic switch for which variation of temperature, pressure and irradiation leads to a change in d-electron configuration and therefore changes to structure, colour and magnetism. Here we aim to synthesise and study a wide variety of new spin-crossover systems where cooperativitiy between centres, induced by careful supramolecular design, will lead to molecules and materials having memory retention, magnetic ordering and/or microporosity. The significance of these aims covers several fundamental questions in the science of electronic systems. We also identify a number of potential nanochemical switching applications for the unique systems proposed.Read moreRead less
Polynuclear Spin-Crossover Molecular Switches: Host-Guest Chemistry, Magnetism and Memory. The generation of advanced nanomaterials requires both a control of nanoscale structure and the incorporation of specific properties into that structure. This project will lead to significant new developments in this area, with the assembly of complex molecular systems containing electronic switches. The unique combination of nanoscale switching and guest-binding and/or magnetic ordering in these systems ....Polynuclear Spin-Crossover Molecular Switches: Host-Guest Chemistry, Magnetism and Memory. The generation of advanced nanomaterials requires both a control of nanoscale structure and the incorporation of specific properties into that structure. This project will lead to significant new developments in this area, with the assembly of complex molecular systems containing electronic switches. The unique combination of nanoscale switching and guest-binding and/or magnetic ordering in these systems will lead to entirely new materials properties, leading in turn to fundamental advances in the science of molecular electronics and nanomaterials. Benefits of the research are wide-ranging, and include the development of innovative new technologies for molecular sensing, molecular separations, data storage and visual displays.Read moreRead less
Metal Directed Assembly of New Discrete and Framework Supramolecular Systems. An important aspect of this project is the development of strategies for assembling molecules and metals into larger units - leading to novel compounds and materials for which unusual and potentially useful properties can be anticipated. These may include materials that act as catalysts for chemical reactions or absorb and store gases (such as hydrogen for use as a fuel). More generally, the area is one that will under ....Metal Directed Assembly of New Discrete and Framework Supramolecular Systems. An important aspect of this project is the development of strategies for assembling molecules and metals into larger units - leading to novel compounds and materials for which unusual and potentially useful properties can be anticipated. These may include materials that act as catalysts for chemical reactions or absorb and store gases (such as hydrogen for use as a fuel). More generally, the area is one that will underpin the 'bottom-up' approach (building tiny components from individual molecules and ions) in the rapidly expanding field of nanotechnology. Clearly, if Australia is to remain internationally competitive in such new technologies then an understanding of processes of the type outlined in this proposal will be essential.Read moreRead less
Cooperativity in Spin-Crossover Systems: Memory, Magnetism and Microporosity. Spin-crossover centres are a well known form of inorganic electronic switch for which variation of temperature, pressure and irradiation leads to a change in d-electron configuration and therefore changes to structure, colour and magnetism. Here we aim to synthesise and study a wide variety of new spin-crossover systems where cooperativity between centres, induced by careful supramolecular design, will lead to molecule ....Cooperativity in Spin-Crossover Systems: Memory, Magnetism and Microporosity. Spin-crossover centres are a well known form of inorganic electronic switch for which variation of temperature, pressure and irradiation leads to a change in d-electron configuration and therefore changes to structure, colour and magnetism. Here we aim to synthesise and study a wide variety of new spin-crossover systems where cooperativity between centres, induced by careful supramolecular design, will lead to molecules and materials having memory retention, magnetic ordering and/or microporosity. The significance of these aims covers several fundamental questions in the science of electronic systems. We also identify a number of potential nanochemical switching applications for the unique systems proposed.Read moreRead less
Metal Directed Assembly of New Supramolecular Systems. An important aspect of this project is the development of strategies for assembling molecules and metals into larger units - leading to novel compounds and materials for which unusual and potentially useful properties can be anticipated. These may include materials that act as catalysts for chemical reactions or absorb and store gases (such as hydrogen for use as a fuel). More generally, the area is one that will underpin the 'bottom-up' ap ....Metal Directed Assembly of New Supramolecular Systems. An important aspect of this project is the development of strategies for assembling molecules and metals into larger units - leading to novel compounds and materials for which unusual and potentially useful properties can be anticipated. These may include materials that act as catalysts for chemical reactions or absorb and store gases (such as hydrogen for use as a fuel). More generally, the area is one that will underpin the 'bottom-up' approach (building tiny components from individual molecules and ions) in the rapidly expanding field of nanotechnology. Clearly, if Australia is to remain internationally competitive in such new technologies then an understanding of processes of the type outlined in this proposal will be essential.Read moreRead less
Nanoscale Molecular Architectures - New Metallo Cages and Capsules. The design and synthesis of novel cage and capsule-like supermolecular structures will be undertaken, including rare examples of two large cage types - one designed to incorporate two adjacent metal ions in an extended (chiral) cavity while the other utilises macrocyclic metal complexes as the 'walls' of the cage. In the latter case metal variation makes possible the alteration of the electronic environment of a guest occupying ....Nanoscale Molecular Architectures - New Metallo Cages and Capsules. The design and synthesis of novel cage and capsule-like supermolecular structures will be undertaken, including rare examples of two large cage types - one designed to incorporate two adjacent metal ions in an extended (chiral) cavity while the other utilises macrocyclic metal complexes as the 'walls' of the cage. In the latter case metal variation makes possible the alteration of the electronic environment of a guest occupying the central cavity . A third (capsule-like) system is designed to 'open' and 'close' under pH control. The present studies hold promise for underpinning the future development of nano-scale molecular devices.
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Spin Switching in Nanoporous, Nanomolecular and Multifunctional Hybrid Systems. The generation of molecular nanomaterials with advanced chemical and physical properties requires both the control of nanoscale structure and the incorporation of specific function into that structure. This project will lead to significant new advances in this area through the generation of molecules and materials in which nanoscale switching is combined with guest-binding, magnetic ordering, and multiple other prope ....Spin Switching in Nanoporous, Nanomolecular and Multifunctional Hybrid Systems. The generation of molecular nanomaterials with advanced chemical and physical properties requires both the control of nanoscale structure and the incorporation of specific function into that structure. This project will lead to significant new advances in this area through the generation of molecules and materials in which nanoscale switching is combined with guest-binding, magnetic ordering, and multiple other properties. Entirely new materials functionalities will emerge, leading in turn to fundamental advances in the science of molecular electronics and nanomaterials and to the development of innovative new technologies for molecular sensing, molecular separations and data storage.Read moreRead less