Development of electric discharge assisted mechanical milling: blue sky technology for synthesis and processing of materials. This project will develop a novel waste and pollution free rapid powder processing technology. By plasma enhancement of reactivity between ingredients, this project will reduce processing times and save energy by up to 1000 per cent. As well as producing new science, the technological outcomes involve new materials, devices and processes of significance to local industrie ....Development of electric discharge assisted mechanical milling: blue sky technology for synthesis and processing of materials. This project will develop a novel waste and pollution free rapid powder processing technology. By plasma enhancement of reactivity between ingredients, this project will reduce processing times and save energy by up to 1000 per cent. As well as producing new science, the technological outcomes involve new materials, devices and processes of significance to local industries.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0775771
Funder
Australian Research Council
Funding Amount
$280,000.00
Summary
Physical Property Measurement System for Materials Characterisation. The Physical Property Measurement System (PPMS) is a versatile, state-of-the-art instrument that is capable of measuring a broad range of magnetic, electronic and thermodynamic materials properties. The instrument will greatly extend materials characterisation capabilities in the Sydney region, leading to major advances in fundamental and applied research and to essential postgraduate training in chemistry, physics and enginee ....Physical Property Measurement System for Materials Characterisation. The Physical Property Measurement System (PPMS) is a versatile, state-of-the-art instrument that is capable of measuring a broad range of magnetic, electronic and thermodynamic materials properties. The instrument will greatly extend materials characterisation capabilities in the Sydney region, leading to major advances in fundamental and applied research and to essential postgraduate training in chemistry, physics and engineering. The importance of materials discovery and characterisation is vital to the development of new technologies over the next decade, as recognised in the national priority area 'Frontier Technologies for Building and Transforming Australian Industries'. Read moreRead less
Cation Ordering - A Strategy to Prepare Multiferroic Oxides. This project will produce new families of functional metal oxides with technologically relevant properties, especially multiferroic behavior. Such materials are highly sort-after in the rapidly emerging field of spintronics. Through comprehensive experimental studies of a number of such materials this project will enhance the ability of industry to develop new and improved materials.
Nickel(III) Oxyhydroxide (NiOOH) as a Positive Electrode Material in Primary Cells. In recent years, the demands put on batteries has increased due to the development of sophisticated portable electronic devices. With the currently available primary battery systems finding it difficult to cope with these demands, there is considerable incentive to develop an improved system with an appropriate capability. This project focuses on nickel(III) oxyhydroxide (NiOOH) as a cathode material. NiOOH is us ....Nickel(III) Oxyhydroxide (NiOOH) as a Positive Electrode Material in Primary Cells. In recent years, the demands put on batteries has increased due to the development of sophisticated portable electronic devices. With the currently available primary battery systems finding it difficult to cope with these demands, there is considerable incentive to develop an improved system with an appropriate capability. This project focuses on nickel(III) oxyhydroxide (NiOOH) as a cathode material. NiOOH is used widely in rechargeable battery systems, where it performs adequately even under severe discharge conditions. However, in primary battery systems, NiOOH suffers from self discharge. This project aims to use the performance capabilities of NiOOH in a primary system, by investigating ways to improve its stability. The benefits for Delta EMD will be protection of their existing business, as well as opening the door to the commercial manufacture of an advanced export material.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100236
Funder
Australian Research Council
Funding Amount
$180,000.00
Summary
Facilities for spectroscopy and diffraction at high pressures. The provision of infrastructure for the study of novel materials under high pressures will enhance Australia's capability in creating new materials and in creating new devices that meet needs in communication, environment and medicine applications. The new facility will enable researchers to understand the response of structures to extreme pressures and will exploit the unique capabilities of the synchrotron light.
Coordination networks based on carbonate and related ions. The very familiar carbonate ion will be put to use to generate a very unfamiliar family of new coordination polymers with geometries and topologies of fundamental structural significance. Carbonate's ability to bring associated metal centres into close communication may lead to unusual and possibly useful electrical, magnetic and catalytic properties. The ability to deliberately engineer specifically targeted coordination polymers with ....Coordination networks based on carbonate and related ions. The very familiar carbonate ion will be put to use to generate a very unfamiliar family of new coordination polymers with geometries and topologies of fundamental structural significance. Carbonate's ability to bring associated metal centres into close communication may lead to unusual and possibly useful electrical, magnetic and catalytic properties. The ability to deliberately engineer specifically targeted coordination polymers with predetermined properties or functions would make possible diverse applications of great practical value; the project will contribute significantly to the basis for such capabilities leading to ?designer materials? of the future.Read moreRead less
Coordination Networks and Supramolecules with Chemically Active Reaction Sites. Supramolecular chemistry and crystal engineering are two related areas of chemistry which examine the way molecules can come together to form larger structures. Usually, however, the aggregations formed are chemically inert, limiting the scope of their potential applications. This project aims to design and synthesise such assemblies that are capable of actively participating in chemical reactions after assembly. The ....Coordination Networks and Supramolecules with Chemically Active Reaction Sites. Supramolecular chemistry and crystal engineering are two related areas of chemistry which examine the way molecules can come together to form larger structures. Usually, however, the aggregations formed are chemically inert, limiting the scope of their potential applications. This project aims to design and synthesise such assemblies that are capable of actively participating in chemical reactions after assembly. The realisation of these aims will give new routes to the production of new catalysts (analogous to enzymes in biological systems), nanoscale molecular sieves, molecular sensors, or materials that show unusual host-guest chemistryRead moreRead less
Coordination Networks and Supramolecules with Potential Post-Assembly Chemical Activity. Two areas of chemistry currently receiving a great deal of attention are supramolecular chemistry and crystal engineering. However, in the majority of these systems, once synthesised the assemblies are chemically inert. This project aims to assemble supramolecules and coordination polymers which are capable of actively participating in chemical reactions. Such systems show potential as new heterogeneous or h ....Coordination Networks and Supramolecules with Potential Post-Assembly Chemical Activity. Two areas of chemistry currently receiving a great deal of attention are supramolecular chemistry and crystal engineering. However, in the majority of these systems, once synthesised the assemblies are chemically inert. This project aims to assemble supramolecules and coordination polymers which are capable of actively participating in chemical reactions. Such systems show potential as new heterogeneous or homogeneous catalysts, selective molecular sieves, or show unusual host-guest chemistry. Techniques developed will provide a means by which present homogeneous catalysts used widely in industry could be converted into heterogeneous species. This would have many benefits, including improved recovery and re-use of catalysts.Read moreRead less
Advanced Materials constructed from 'Nanoballs' and Variable Length Ligands. Novel types of porous materials will be made using a revolutionary new way to connect metal ions. Remarkable nanometer sized molecules ('nanoballs') will be investigated for their unprecedented variety of useful properties. As well as advancing our understanding of the science of advanced materials, this project will have application in areas such as hydrogen and methane storage, trapping of greenhouse gases such as car ....Advanced Materials constructed from 'Nanoballs' and Variable Length Ligands. Novel types of porous materials will be made using a revolutionary new way to connect metal ions. Remarkable nanometer sized molecules ('nanoballs') will be investigated for their unprecedented variety of useful properties. As well as advancing our understanding of the science of advanced materials, this project will have application in areas such as hydrogen and methane storage, trapping of greenhouse gases such as carbon dioxide, molecular sensing, catalysis, and information storage.Read moreRead less
New Nanoscale Up-converting Photoluminescent Materials for Passive Safety Visual Systems. The demand for safety and security products is growing as the importance of providing an environment safer from natural, accidental or man-made threats increases in the community. Life safety applications in buildings and work environments as well as trains and planes for example are dependent upon the ability for non-powered passive systems to give efficient visual guidance in dangerous dark and smoke fill ....New Nanoscale Up-converting Photoluminescent Materials for Passive Safety Visual Systems. The demand for safety and security products is growing as the importance of providing an environment safer from natural, accidental or man-made threats increases in the community. Life safety applications in buildings and work environments as well as trains and planes for example are dependent upon the ability for non-powered passive systems to give efficient visual guidance in dangerous dark and smoke filled environments. This project will provide a practical demonstration of the successful implementation of nanotechnology to smaller Australian companies where it will overcome significant drawbacks in current manufacturing and yield new products which are activated in darkness by infrared radiation.Read moreRead less