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Confinement of space based on association of water soluble container molecules. The proposed research addresses the use of water soluble bowl shaped molecules or ions (cavitands) in conjunction with metal ions and crown ether and related cryptand molecules to form molecular capsules, two or more of the components being pre-programmed to assemble thus. The new materials will be unique in supramolecular chemistry, with the associated architectures bearing on materials science, molecular electronic ....Confinement of space based on association of water soluble container molecules. The proposed research addresses the use of water soluble bowl shaped molecules or ions (cavitands) in conjunction with metal ions and crown ether and related cryptand molecules to form molecular capsules, two or more of the components being pre-programmed to assemble thus. The new materials will be unique in supramolecular chemistry, with the associated architectures bearing on materials science, molecular electronics, separation sciences, and drug delivery. The new range of water soluble container molecules that will become accessible as part of this proposal, promises new applications in these areas.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
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
Optimising synthesis, developing delivery systems and resolving the ecological significance of the chemical in smoke that promotes seed germination. Discovery of the identity of the component in smoke (a butenolide) that promotes seed germination provides the research platform to deliver smoke-like efficacy for germination of native species used in horticulture, land restoration and biodiversity conservation. The study will investigate five key areas to deliver the national benefits of our disco ....Optimising synthesis, developing delivery systems and resolving the ecological significance of the chemical in smoke that promotes seed germination. Discovery of the identity of the component in smoke (a butenolide) that promotes seed germination provides the research platform to deliver smoke-like efficacy for germination of native species used in horticulture, land restoration and biodiversity conservation. The study will investigate five key areas to deliver the national benefits of our discovery: investigate efficacy of butenolide in seed germination; resolve mechanisms of dormancy release via butenolide; optimise synthesis pathways for production of butenolide and germination-effective analogues; investigate the ecologiocal context and natural abundance of butenolide; resolve synthesis and delivery systems for horticulture and restoration.Read moreRead less
A terrestrial hot spring setting for the origin of life. This project aims to test the proposal that a terrestrial hot spring field could have been the setting for the origin of life, in preference over the currently favoured site at deep sea vents. The project will involve an integrated, and multi-disciplinary study of the rocks, fluids, and molecules that together make up ancient to modern hot spring systems, and experiments on prebiotic organic chemistry using early Earth materials. Results w ....A terrestrial hot spring setting for the origin of life. This project aims to test the proposal that a terrestrial hot spring field could have been the setting for the origin of life, in preference over the currently favoured site at deep sea vents. The project will involve an integrated, and multi-disciplinary study of the rocks, fluids, and molecules that together make up ancient to modern hot spring systems, and experiments on prebiotic organic chemistry using early Earth materials. Results will be used to develop a terrestrial origin of life setting and assist in the search for life on Mars.Read moreRead less
Controlling the organisation of matter using vortex fluidics. Vortex fluidic devices will be developed and used to construct functional complex molecules and materials, and probe the structure of self assembled systems. The scalable processing will be assessed for application in advanced materials production, the chemical industry and in developing complex molecules for drug discovery.
Cyclophane Carbene Complexes as Catalysts: An Integrated Synthetic, Structural, and Mechanistic Approach. Metal-carbene complexes are emerging as efficient catalysts for chemical processes of immense importance to the pharmaceutical and fine chemicals industries. This project will build on the recent discovery of a family of complexes that exhibits the highest activity yet reported for metal-carbene catalysts in carbon-carbon bond-forming reactions. Insights into the ways the new catalysts work ....Cyclophane Carbene Complexes as Catalysts: An Integrated Synthetic, Structural, and Mechanistic Approach. Metal-carbene complexes are emerging as efficient catalysts for chemical processes of immense importance to the pharmaceutical and fine chemicals industries. This project will build on the recent discovery of a family of complexes that exhibits the highest activity yet reported for metal-carbene catalysts in carbon-carbon bond-forming reactions. Insights into the ways the new catalysts work will be gained through a combination of synthetic, mechanistic, and structural studies. This detailed investigation of structure/reactivity relationships will provide an understanding of why these catalyst are so efficient and hence give synthetic leads for the development of superior new catalysts suitable for industrial application.Read moreRead less
Vortex fluidic mediated chemical transformations. This project aims to develop a continuous flow vortex fluidic device (VFD) for chemical and biochemical transformations. Vortex fluidic devices should lead to cleaner and faster ways of preparing complex molecules. Depending on the VFD’s operating parameters, including applying field effects such as Faraday waves, plasmas and light sources, reactions could have higher yields and selectivity than traditional batch processing. This will be translat ....Vortex fluidic mediated chemical transformations. This project aims to develop a continuous flow vortex fluidic device (VFD) for chemical and biochemical transformations. Vortex fluidic devices should lead to cleaner and faster ways of preparing complex molecules. Depending on the VFD’s operating parameters, including applying field effects such as Faraday waves, plasmas and light sources, reactions could have higher yields and selectivity than traditional batch processing. This will be translated into molecular assembly line syntheses in a single unit or a series. Such syntheses should provide a versatile toolbox for molecular transformations, under continuous flow conditions where scalability is addressed upfront. This will be attractive to industry and minimise effects on the environment.Read moreRead less
Modular Vortex Fluidic Mediated Molecular Transformations. The project aims to develop the use of electric and magnetic fields to control chemical and biochemical reactions in high shear thin films under readily scalable continuous flow conditions to then be able to precisely build complex functional molecules. Depending on the orientation, strength and frequency of external electric and magnetic fields, and novel shear stress induced electric fields in solution, rates of reactions can be enhanc ....Modular Vortex Fluidic Mediated Molecular Transformations. The project aims to develop the use of electric and magnetic fields to control chemical and biochemical reactions in high shear thin films under readily scalable continuous flow conditions to then be able to precisely build complex functional molecules. Depending on the orientation, strength and frequency of external electric and magnetic fields, and novel shear stress induced electric fields in solution, rates of reactions can be enhanced, with higher yields and tunable selectivity, and reduced waste and energy usage, which is not possible using traditional batch processing. This will be translated into molecular assembly line processing and the development of a new synthetic toolbox, with applications in preparing pharmaceuticals.
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A radical approach to the design of components for molecular electronics. This project aims to develop highly conductive organometallic molecular wires for use in future molecular electronics technology. Metal complexes have immense potential as components in future electronic circuits, offering function on a size impossible to meet in conventional solid-state devices, and helping overcome limits in 'top-down' scaling. Whilst organic molecules that display electronic function are known, their pe ....A radical approach to the design of components for molecular electronics. This project aims to develop highly conductive organometallic molecular wires for use in future molecular electronics technology. Metal complexes have immense potential as components in future electronic circuits, offering function on a size impossible to meet in conventional solid-state devices, and helping overcome limits in 'top-down' scaling. Whilst organic molecules that display electronic function are known, their performance remains poor. Just as doping a semiconductor results in higher electrical conductance by placing additional electrons (holes) into the conduction (valence) band, this project will use transition metal organometallic complexes bearing radical ligands as innovative motifs in the design of novel molecular components.Read moreRead less