New Copper and Rhenium Radiopharmaceuticals. The aims of this project are to provide new metal-based radiopharmaceuticals for the treatment of cancer, and the imaging of cancer and other conditions through the design and engineering of new coordination complexes of rhenium and copper. Various strategies will be used to selectively and specifically target these metal complexes to the desired areas in vivo for non-invasive imaging and therapeutic applications. The most promising candidates will be ....New Copper and Rhenium Radiopharmaceuticals. The aims of this project are to provide new metal-based radiopharmaceuticals for the treatment of cancer, and the imaging of cancer and other conditions through the design and engineering of new coordination complexes of rhenium and copper. Various strategies will be used to selectively and specifically target these metal complexes to the desired areas in vivo for non-invasive imaging and therapeutic applications. The most promising candidates will be tested in the appropriate cells.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
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
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
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE210100009
Funder
Australian Research Council
Funding Amount
$620,000.00
Summary
Magnetometry Facility for Molecular and Nanoscale Materials. Advances in information and communications technology are critically dependent on increasing the capacity, speed and energy efficiency of logic and memory electronic devices. These improvements can be achieved by reducing component size to the nanoscale and using magnetic spin as well as charge. This Project aims to establish Australia's first integrated Magnetometry Facility for determining the magnetic properties of a range of nanosc ....Magnetometry Facility for Molecular and Nanoscale Materials. Advances in information and communications technology are critically dependent on increasing the capacity, speed and energy efficiency of logic and memory electronic devices. These improvements can be achieved by reducing component size to the nanoscale and using magnetic spin as well as charge. This Project aims to establish Australia's first integrated Magnetometry Facility for determining the magnetic properties of a range of nanoscale materials down to the level of individual nanomagnets. The Facility will provide crucial characterisation capabilities for Australian researchers, building capacity to develop new magnetic nanomaterials and devices for high-density data storage, quantum computing and spintronics.
Read moreRead less
Molecular magnetic materials of the cluster and network types. This research project involves the preparation of new molecular based magnets, using metals such as manganese or dysprosium, together with detailed studies of their physical properties. When groups of these metal ions form in to clusters, bridged by organic molecules, they are nano-sized and display new and useful magnetic and quantum properties.