Tunable metallophthalocyanine complexes for molecular electronics. There is growing momentum in the use of molecules, both synthetic and natural, in nanotechnological electronic devices. This research investigates technologically interesting electronic materials using new metal-containing compounds and explores their application as components of molecular electronic systems.
Because fundamental aspects of molecular electronic systems have been targeted, the knowledge gained from these investiga ....Tunable metallophthalocyanine complexes for molecular electronics. There is growing momentum in the use of molecules, both synthetic and natural, in nanotechnological electronic devices. This research investigates technologically interesting electronic materials using new metal-containing compounds and explores their application as components of molecular electronic systems.
Because fundamental aspects of molecular electronic systems have been targeted, the knowledge gained from these investigations will have significant impact on the field of nanotechnology and contribute to Australia's reputation as a source of innovative research and ideas in an area where there is growing international interest.
Read moreRead less
Dinuclear Ruthenium Complexes as Sequence- and Structure-Selective Binding Agents for DNA. Studies of the interaction of mononuclear metal complexes with DNA have greatly increased our understanding of the ways that small molecules recognise particular sites on DNA. However, in order to design drugs that target specific genes, and hence be potentially capable of controlling gene expression, it is necessary to study the binding of metal complexes that can associate with larger segments of DNA. ....Dinuclear Ruthenium Complexes as Sequence- and Structure-Selective Binding Agents for DNA. Studies of the interaction of mononuclear metal complexes with DNA have greatly increased our understanding of the ways that small molecules recognise particular sites on DNA. However, in order to design drugs that target specific genes, and hence be potentially capable of controlling gene expression, it is necessary to study the binding of metal complexes that can associate with larger segments of DNA. Using the combined expertise of the applicants, it is proposed to stereospecifically synthesise dinuclear complexes and study their DNA binding. This will greatly assist in the development of drugs that can selectively target genes and altered DNA.Read moreRead less
Polynuclear Metal Complexes as Molecular Nanomagnets. Computer hard drives and other devices use tiny particles of magnetic materials to store digital information. Technological advances require an increase in the density of information storage and therefore even smaller magnetic particles. This project has the potential to synthesise materials where a single molecule could act as the smallest possible unit of magnetic memory. The future application of these materials may provide an increase ....Polynuclear Metal Complexes as Molecular Nanomagnets. Computer hard drives and other devices use tiny particles of magnetic materials to store digital information. Technological advances require an increase in the density of information storage and therefore even smaller magnetic particles. This project has the potential to synthesise materials where a single molecule could act as the smallest possible unit of magnetic memory. The future application of these materials may provide an increase of three orders of magnitude in information storage density. In addition, they may find employment in quantum computers, which can perform calculations exponentially faster than conventional computers.Read moreRead less
Spotlighting biologically active Iron (Fe) chelators within cells. Anti-cancer drugs that act in ways different from traditional chemotherapeutics offer hope in evading acquired drug resistance. Previously we have studied compounds that can enter cancer cells, bind iron and halt cellular proliferation. However, there are many sources of iron in cells and we do not know from where these iron chelators acquire their iron or how these iron complexes kill cancer cells. We will tackle this problem by ....Spotlighting biologically active Iron (Fe) chelators within cells. Anti-cancer drugs that act in ways different from traditional chemotherapeutics offer hope in evading acquired drug resistance. Previously we have studied compounds that can enter cancer cells, bind iron and halt cellular proliferation. However, there are many sources of iron in cells and we do not know from where these iron chelators acquire their iron or how these iron complexes kill cancer cells. We will tackle this problem by attaching light emitting probes to known iron chelators and mapping their location within cells with high resolution fluorescence microscopy. These experiments will spotlight the cellular location of these potential drugs bound to iron for the first time, providing crucial information on their mode of action.Read moreRead less
New Frontiers in Molybdenum Chemistry: Electronic Structure and Molybdoenzyme Function. Molybdenum enzymes play key roles in biology and environmental, biogeochemical and meteorological processes. This international, multidisciplinary project will employ advanced synthetic, instrumental and theoretical techniques to establish the link between electronic structures and molybdenum enzyme behaviour and function. The insights gained will inform the continuing development of agricultural, veterinary ....New Frontiers in Molybdenum Chemistry: Electronic Structure and Molybdoenzyme Function. Molybdenum enzymes play key roles in biology and environmental, biogeochemical and meteorological processes. This international, multidisciplinary project will employ advanced synthetic, instrumental and theoretical techniques to establish the link between electronic structures and molybdenum enzyme behaviour and function. The insights gained will inform the continuing development of agricultural, veterinary and medical treatments for diseases associated with enzyme dysfunction; these outcomes would be of enormous economic and societal benefit to Australia. The training of skilled scientists, access to advanced overseas facilities, and international recognition of Australian research, are important immediate benefits of the project.Read moreRead less
New Methods to Harvest Light: Towards Better Dye-Sensitized Solar Cells. Dye-sensitized solar cell (DSC) technology has emerged as a complementary energy source to silicon photovoltaic technology. The efficiency of the DSC relies heavily on sensitizing molecules to absorb solar photons and then transfer electrons to a semi-conducting particle. This project will investigate new sensitizing methods using a combination of different dyes which work cooperatively to absorb a large part of the solar ....New Methods to Harvest Light: Towards Better Dye-Sensitized Solar Cells. Dye-sensitized solar cell (DSC) technology has emerged as a complementary energy source to silicon photovoltaic technology. The efficiency of the DSC relies heavily on sensitizing molecules to absorb solar photons and then transfer electrons to a semi-conducting particle. This project will investigate new sensitizing methods using a combination of different dyes which work cooperatively to absorb a large part of the solar spectrum and efficiently inject electrons into a semi-conducting particles. The development and understanding of these new methods to sensitize the dye-sensitized solar cell should lead to new and better solar cells.Read moreRead less
Gas Phase Studies to Catalyze a Better Understanding of Metal Reactivity. The proposed research will increase knowledge of fundamental questions related to the mechanisms of catalysis and metal ion reactivity. The insights gained will be an important addition to the knowledge base of our culture, both nationally and in the wider international context. We note that research into the behaviour and design of catalysts is a burgeoning field which reflects the great importance of this area in the int ....Gas Phase Studies to Catalyze a Better Understanding of Metal Reactivity. The proposed research will increase knowledge of fundamental questions related to the mechanisms of catalysis and metal ion reactivity. The insights gained will be an important addition to the knowledge base of our culture, both nationally and in the wider international context. We note that research into the behaviour and design of catalysts is a burgeoning field which reflects the great importance of this area in the international scientific community. Our proposal will add to fundamental knowledge and may also result in practical applications. More importantly, we will train and equip talented young people with a spectrum of skills which will make them well placed to meet the demand for highly skilled professional scientists.Read moreRead less
New approaches to bistable spin clusters. Future advances in data storage technology and other areas of electronics depend on the miniaturisation of the relevant components. The goal of this project is to create materials where individual molecules can be the units of magnetic memory for high density data storage or the switches in electronic devices. Fundamental research in these areas is being pursued vigourously overseas and Australian involvement through this project is important for the p ....New approaches to bistable spin clusters. Future advances in data storage technology and other areas of electronics depend on the miniaturisation of the relevant components. The goal of this project is to create materials where individual molecules can be the units of magnetic memory for high density data storage or the switches in electronic devices. Fundamental research in these areas is being pursued vigourously overseas and Australian involvement through this project is important for the possibility of local development of devices based on the new materials. The students and postdoctoral fellows involved in this work will receive world class training in the synthetic and physical techniques that underpin the emerging fields of molecular magnetism and molecular electronics.Read moreRead less
Studies of metal compounds containing carbon chains - approaches to novel materials. There is an increasing need to design functional devices on the molecular scale ("nanotechnology"). We are developing the chemistry of compounds which contain chains of up to 12 carbon atoms to allow electronic communication between metal centres attached to each end. This projects seeks to extend this work, to discover new and more effective compounds, and to develop the associated chemistry to provide synthese ....Studies of metal compounds containing carbon chains - approaches to novel materials. There is an increasing need to design functional devices on the molecular scale ("nanotechnology"). We are developing the chemistry of compounds which contain chains of up to 12 carbon atoms to allow electronic communication between metal centres attached to each end. This projects seeks to extend this work, to discover new and more effective compounds, and to develop the associated chemistry to provide syntheses of novel compounds of potential use in the fine chemicals industry. Extensive collaboration with French colleagues exists and will continue.Read moreRead less
All-carbon molecules in metal complexes - novel materials and intermediates. An important requirement for the future is new materials with unusual properties that can be controlled. The need for ever smaller electronic devices requires knowledge about appropriate properties (particularly electronic) of molecules designed to model devices such as wires, switches, etc. This work seeks to design, measure and evaluate such molecules, which are based on chains of carbon atoms linking metal centres ....All-carbon molecules in metal complexes - novel materials and intermediates. An important requirement for the future is new materials with unusual properties that can be controlled. The need for ever smaller electronic devices requires knowledge about appropriate properties (particularly electronic) of molecules designed to model devices such as wires, switches, etc. This work seeks to design, measure and evaluate such molecules, which are based on chains of carbon atoms linking metal centres which can gain or lose electrons readily. As the electronic structure changes, so do the physical (photo, solid-state) and chemical properties (reactivity). Improved understanding of these features will benefit development of advanced technology and new materials.Read moreRead less