Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0346515
Funder
Australian Research Council
Funding Amount
$507,000.00
Summary
Fluorescence Detector for the Australian National Beamline Facility. X-ray absorption spectroscopy (XAS) is an extremely important synchrotron radiation tool for determining the local structure around an X-ray absorbing atom. This has many applications in the study of materials, minerals, metal complexes, and metalloproteins and can often be used to obtain information that is not available by other techniques, because structural information can be obtained in the solid or solution state and in ....Fluorescence Detector for the Australian National Beamline Facility. X-ray absorption spectroscopy (XAS) is an extremely important synchrotron radiation tool for determining the local structure around an X-ray absorbing atom. This has many applications in the study of materials, minerals, metal complexes, and metalloproteins and can often be used to obtain information that is not available by other techniques, because structural information can be obtained in the solid or solution state and in mixtures. The current proposal is aimed at introducing new technology into the Australian National Beamline Facility that will greatly improve the quality and quantity of experiments that can be performed and extend studies into dilute solutions and protein samples.Read moreRead less
Smart Molecular Materials for Sensors, Displays and Nanodevices. The aims of this project are to synthesise new smart molecular materials and elucidate the chemical origin of the physical properties they exhibit. Exposure of these transition metal-based compounds to heat or light will induce changes in colour and magnetic behaviour, affording potential roles as the smallest possible electronic components or addressable entities for high density data storage. It is expected that the materials wil ....Smart Molecular Materials for Sensors, Displays and Nanodevices. The aims of this project are to synthesise new smart molecular materials and elucidate the chemical origin of the physical properties they exhibit. Exposure of these transition metal-based compounds to heat or light will induce changes in colour and magnetic behaviour, affording potential roles as the smallest possible electronic components or addressable entities for high density data storage. It is expected that the materials will also exhibit tunable thermochromic and photochromic properties, which are important for applications in photoresponsive devices or temperature sensors. The structure-function relationships determined will inform the development of molecular materials for future nanodevices, sensors or displays.Read moreRead less
Reactivity and Spectroscopy of Gas Phase Metal Oxide Cluster Ions: Structure-Reactivity Correlations and Fundamental Insights into Heterogeneous Catalysis. This project will make use of world class ARC funded instrumentation to carry out breakthrough science. The research will contribute fundamental insights into chemical bond activation relevant to industrial catalytic processes important to national manufacturing industries. These insights will improve the efficiency and selectivity of catal ....Reactivity and Spectroscopy of Gas Phase Metal Oxide Cluster Ions: Structure-Reactivity Correlations and Fundamental Insights into Heterogeneous Catalysis. This project will make use of world class ARC funded instrumentation to carry out breakthrough science. The research will contribute fundamental insights into chemical bond activation relevant to industrial catalytic processes important to national manufacturing industries. These insights will improve the efficiency and selectivity of catalytic processes and lead to increased profitability and/or a reduction in unwanted side products and pollution. The project will train young scientists in important experimental and theoretical chemical techniques, and will enhance and contribute to Australia's international research profile.Read moreRead less
Novel Photo-Catalysts for Water Oxidation: Linking Nature to New Technologies. Photosynthesis is the catalytic process used by biology to convert the sun's light into energy. This project aims to mimic photosynthesis with cheap and robust molecules. The approach has great potential for development of renewable energy production and benign industrial chemical processes. The project will bring Australia to the international forefront of this field. It will provide excellent research training in a ....Novel Photo-Catalysts for Water Oxidation: Linking Nature to New Technologies. Photosynthesis is the catalytic process used by biology to convert the sun's light into energy. This project aims to mimic photosynthesis with cheap and robust molecules. The approach has great potential for development of renewable energy production and benign industrial chemical processes. The project will bring Australia to the international forefront of this field. It will provide excellent research training in a range of scientific skills for Australian research students. Read moreRead less
Polyoxometalate Clusters: Catalytic Chemistry in Solution and Condensed States. Polyoxometalate cluster anions are soluble metal-oxygen clusters that are cheap, robust and non-toxic.
Conditions for systematic tuning of redox potentials over the range +2 to -3 V have become accessible via certain photo-active polyoxometalates. The same system can provide powerful oxidants (that rival chlorine) and powerful reductants (that rival potassium).
The program will take advantage of this unique ....Polyoxometalate Clusters: Catalytic Chemistry in Solution and Condensed States. Polyoxometalate cluster anions are soluble metal-oxygen clusters that are cheap, robust and non-toxic.
Conditions for systematic tuning of redox potentials over the range +2 to -3 V have become accessible via certain photo-active polyoxometalates. The same system can provide powerful oxidants (that rival chlorine) and powerful reductants (that rival potassium).
The program will take advantage of this unique range of properties to explore:-
(i) coupling of photo- and electro-chemical processes into effective catalytic cycles;
(ii) photo- and electro-chemical processes in ionic liquid solvents;
(iii) synthesis and redox reactivity of nanoparticles stabilised by polyoxometalates.
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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
Metal-Based Molecular Materials: From Electronic Structure to Functionality. This project aims to develop and explore new metal-based molecular materials, focusing on molecules that can act as magnets or be switched between multiple states by heating/cooling. This project expects to deliver an improved understanding of how the molecular electronic structure engenders desired physical properties in the target species. This insight will allow development of design principles for robust systems for ....Metal-Based Molecular Materials: From Electronic Structure to Functionality. This project aims to develop and explore new metal-based molecular materials, focusing on molecules that can act as magnets or be switched between multiple states by heating/cooling. This project expects to deliver an improved understanding of how the molecular electronic structure engenders desired physical properties in the target species. This insight will allow development of design principles for robust systems for nanodevices or advanced materials. As well as achieving important advances in fundamental chemistry, this project is anticipated to help lay the foundations for development of novel materials for high density data storage, quantum computing, molecular electronics/spintronics, optical displays or temperature/solvent sensors.Read moreRead less
Molecular Spin Switching with Earth Abundant Metals. This project aims to develop molecular materials based on non-precious metals that respond to stimuli, including heat or light, by switching between forms with different properties, such as colour and electrical conductivity. The project expects to deliver enhanced control over the switching characteristics and incorporation of the materials into responsive thin films, ready for integration into devices. These molecular switches are promising ....Molecular Spin Switching with Earth Abundant Metals. This project aims to develop molecular materials based on non-precious metals that respond to stimuli, including heat or light, by switching between forms with different properties, such as colour and electrical conductivity. The project expects to deliver enhanced control over the switching characteristics and incorporation of the materials into responsive thin films, ready for integration into devices. These molecular switches are promising for molecular electronics, spintronics and colour-based sensing and display devices. Their fast response time and small component size imply less heat to dissipate and therefore less electricity required for cooling upon implementation in information communications and other technologies.Read moreRead less
Harnessing redox-active ligands in functional metal complexes. This project aims to synthesise and investigate metal-based molecules that can be reversibly switched between forms with different physical properties, such as colour or electrical conductivity, upon exposure to heat, light or electrical potential. The project expects to develop compounds that offer physical properties relevant for deployment in advanced materials or nanodevices. Expected outcomes of this project include elucidation ....Harnessing redox-active ligands in functional metal complexes. This project aims to synthesise and investigate metal-based molecules that can be reversibly switched between forms with different physical properties, such as colour or electrical conductivity, upon exposure to heat, light or electrical potential. The project expects to develop compounds that offer physical properties relevant for deployment in advanced materials or nanodevices. Expected outcomes of this project include elucidation of chemical routes to tuning the switchability and candidate compounds for future applications. As well as achieving important advances in fundamental chemistry, this project should provide significant benefits, such as novel materials for molecular electronics/spintronics, photoresponsive devices or sensors.Read moreRead less