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
Advanced Functional Properties in Coordination Framework Materials. The design and construction of advanced nanomaterials represents both a key area of fundamental research and a critical step in the push towards smarter and more efficient high-level technologies. Here we explore the strategic synthesis of molecular materials that have entirely new and highly useful properties, namely, nanoporosity and negative thermal expansion. This innovative work will lead to important fundamental advances ....Advanced Functional Properties in Coordination Framework Materials. The design and construction of advanced nanomaterials represents both a key area of fundamental research and a critical step in the push towards smarter and more efficient high-level technologies. Here we explore the strategic synthesis of molecular materials that have entirely new and highly useful properties, namely, nanoporosity and negative thermal expansion. This innovative work will lead to important fundamental advances in nanoscience and will forge deep understandings of how physical properties relate to nanoscale structure. These advances will spur a wide range of important new technologies, with future application of the materials in molecular separations, sensing, energy conversion, electronics and photonics.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
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
ARC Molecular and Materials Structure Research Network. The Network will build powerful e-Science resources for the structural sciences. Collaborative remote access will be developed for sophisticated instrumentation, including instruments planned for the Replacement Research Reactor and Australian Synchrotron. A structure database service with cross disciplinary content and versatile visualisation and analysis capabilities will further exemplify smart information use. The internet services will ....ARC Molecular and Materials Structure Research Network. The Network will build powerful e-Science resources for the structural sciences. Collaborative remote access will be developed for sophisticated instrumentation, including instruments planned for the Replacement Research Reactor and Australian Synchrotron. A structure database service with cross disciplinary content and versatile visualisation and analysis capabilities will further exemplify smart information use. The internet services will ultimately harness the Grid, enabling linkage into other national and international Grid systems. Encompassing physics, computer science, applied mathematics, chemistry and biochemistry, and catalysing interaction across these disciplines, the MMSN will impact all five National Research Priority 3 goals.Read moreRead less
Thin Films of Oxide Ceramics. Aluminium oxide films are used extensively in the Australian industries of Protective & Decorative Coatings (examples include door-knobs and cutting-tools). The industry will be offered a remarkably simple process for preparation of high quality films. In the microelectronic industry, the uses of aluminium oxide films as a dielectric alternative to silicon dioxide has just started to emerge world - wide and this new process would make a dramatic impact with commerci ....Thin Films of Oxide Ceramics. Aluminium oxide films are used extensively in the Australian industries of Protective & Decorative Coatings (examples include door-knobs and cutting-tools). The industry will be offered a remarkably simple process for preparation of high quality films. In the microelectronic industry, the uses of aluminium oxide films as a dielectric alternative to silicon dioxide has just started to emerge world - wide and this new process would make a dramatic impact with commercial benefits for Australia. Read moreRead less
Molecular Framework Materials: Nanoporosity and Anomalous Thermal Expansion. The design and construction of advanced nanomaterials represents both a key area of fundamental research and a critical step in the push towards smarter and more efficient high-level technologies. Here we explore the strategic assembly of molecular materials that have entirely new and highly useful properties, namely, nanoporosity and anomalous thermal expansion. This innovative work will lead to important fundamental ....Molecular Framework Materials: Nanoporosity and Anomalous Thermal Expansion. The design and construction of advanced nanomaterials represents both a key area of fundamental research and a critical step in the push towards smarter and more efficient high-level technologies. Here we explore the strategic assembly of molecular materials that have entirely new and highly useful properties, namely, nanoporosity and anomalous thermal expansion. This innovative work will lead to important fundamental advances in nanoscience and will forge deep understandings of how materials properties relate to nanoscale structure. These advances will spur a wide range of important new technologies, with application of the materials in molecular separations and sensing, clean energy storage, electronics and photonics.Read moreRead less
Advanced Molecular Nanomaterials. The design and construction of advanced nanomaterials is a key step in the push towards smarter and more efficient high-level technologies. Here we mount a major research program into the strategic assembly of molecular nanomaterials that have entirely new and highly useful properties. This innovative work will lead to important fundamental advances in nanoscience and will forge deep understandings of how materials properties relate to nanoscale structure. Th ....Advanced Molecular Nanomaterials. The design and construction of advanced nanomaterials is a key step in the push towards smarter and more efficient high-level technologies. Here we mount a major research program into the strategic assembly of molecular nanomaterials that have entirely new and highly useful properties. This innovative work will lead to important fundamental advances in nanoscience and will forge deep understandings of how materials properties relate to nanoscale structure. These advances will spur a wide range of important new technologies, with application of the materials in electronics, photonics, molecular sensing, drug synthesis and purification, clean energy and the controlled release of agrochemicals and pharmaceuticals.Read moreRead less
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
Special Research Initiatives - Grant ID: SR0354691
Funder
Australian Research Council
Funding Amount
$30,000.00
Summary
A Grid Enabled Network for the Molecular and Materials Structure Sciences. The Molecular and Materials Structure Network will propel leading-edge Science by building powerful e-Science resources that will compel innovative collaborations of profound National benefit. Remote access will be developed for structure determination instruments, including the Research Reactor and Australian Synchrotron. A structure database with cross disciplinary content and powerful visualisation and analysis capabil ....A Grid Enabled Network for the Molecular and Materials Structure Sciences. The Molecular and Materials Structure Network will propel leading-edge Science by building powerful e-Science resources that will compel innovative collaborations of profound National benefit. Remote access will be developed for structure determination instruments, including the Research Reactor and Australian Synchrotron. A structure database with cross disciplinary content and powerful visualisation and analysis capabilities will exemplify "smart information use". Encompassing physics, computer science, chemistry and biochemistry, and catalysing interaction across these disciplines, the MMSN will impact all four National Research Priority 3 goals, and will be linked to other national and international Grids to become part of the emerging global Grid.Read moreRead less