Microscale evolution of deformed rocks and glaciers. Scientific outcomes from this research have significant implications for predictions on material properties and are applicable to rock behaviour in mineralised systems, a focus of Australia's minerals industry, and the development of new materials for the Australian manufacturing industries. It will help maintain Australia's excellent international research reputation in the fields of microstructural geology and glaciology.
Microstructural analysis using integrated experiments and numerical modelling. Microstructures related to nano-materials and visible up to the scale of a thin section, are important tools for any material scientist, geologist or glaciologist. Microstructural evolution underpins how these disciplines unravel grain-scale structures, deformation conditions and mechanisms to estimate the intensity or amount of deformation. This project will allow us to better interpret microstructural evolution, in ....Microstructural analysis using integrated experiments and numerical modelling. Microstructures related to nano-materials and visible up to the scale of a thin section, are important tools for any material scientist, geologist or glaciologist. Microstructural evolution underpins how these disciplines unravel grain-scale structures, deformation conditions and mechanisms to estimate the intensity or amount of deformation. This project will allow us to better interpret microstructural evolution, in a range of natural, organic and composite materials, by using integrated laboratory experiments and numerical simulations. With these results we will model the conditions that prevail in composite materials, in glaciers and apply them to processes operating in of the Earth's crust.Read moreRead less
Evolution of Contact Damage in Layer Structures. Brittle layer structures (eg brittle coating on ceramic substrate) can be much more damage tolerant than their constituent material components - cracks tend to remain contained within the coating. Very little is known about the factors that control this behaviour. This project will exploit unique local expertise in modelling damage evolution to fill a niche in a large study being carried out at the National Institute of Standards (NIST) in the U ....Evolution of Contact Damage in Layer Structures. Brittle layer structures (eg brittle coating on ceramic substrate) can be much more damage tolerant than their constituent material components - cracks tend to remain contained within the coating. Very little is known about the factors that control this behaviour. This project will exploit unique local expertise in modelling damage evolution to fill a niche in a large study being carried out at the National Institute of Standards (NIST) in the U.S.A. An understanding of the factors that maximise the containment of cracks is essential to the design and development of the next generation of advanced layer composites for many biomechanical and other engineering applications.Read moreRead less
Designs of Periodic Microstructure Materials with Prescribed Multiphysical Properties. The evolutionary structural optimization (ESO) is an Australian initiative, which has made a significant impact on modern structural optimization. In advanced materials areas, Australia has well-established infrastructure and world-class expertise. Exploitation of ESO to advanced materials design will be of "exclusive significance" to Australia. More importantly, the new material design technology will present ....Designs of Periodic Microstructure Materials with Prescribed Multiphysical Properties. The evolutionary structural optimization (ESO) is an Australian initiative, which has made a significant impact on modern structural optimization. In advanced materials areas, Australia has well-established infrastructure and world-class expertise. Exploitation of ESO to advanced materials design will be of "exclusive significance" to Australia. More importantly, the new material design technology will present to Australia an opportunity to lead in this rapidly-growing area, which will definitely underpin Australia's standing as a major contributor and developer in a global materials market. It is expected that fresh classes of futuristic materials can be developed in a cost-effective fashion and add great economic benefits to Australia.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989492
Funder
Australian Research Council
Funding Amount
$350,000.00
Summary
Dynamic Texture Measurement Facility. A texture goniometer is an advanced tool for texture characterisation of steels, light alloys, nanomaterials, superconductors and minerals. The ability to conduct dynamic texture measurements will significantly enhance the effectiveness of four material-based research institutes at the University of Wollongong and at Deakin University, as well as collaborative research with BlueScope Steel. The research is directly aligned to the National Research Priority o ....Dynamic Texture Measurement Facility. A texture goniometer is an advanced tool for texture characterisation of steels, light alloys, nanomaterials, superconductors and minerals. The ability to conduct dynamic texture measurements will significantly enhance the effectiveness of four material-based research institutes at the University of Wollongong and at Deakin University, as well as collaborative research with BlueScope Steel. The research is directly aligned to the National Research Priority of Frontier Technologies for Building and Transforming Australian Industry. The equipment will provide a valuable resource for industries in the Illawarra region of NSW and in regional South-West Victoria.Read moreRead less
Development and Use of Ionic Liquids in Metal Recovery from Ores, Concentrates and Mattes. Ionic liquids, which are liquid over a wide temperature range and can dissolve a wide range of solutes to high concentrations, promise new and yet unexplored approaches in processing ores. We aim to prepare ionic liquids and apply these to increase the intensity of copper and gold sulfide processing, and to explore more efficient separation of platinum group metals from mattes. New oxidative leaching techn ....Development and Use of Ionic Liquids in Metal Recovery from Ores, Concentrates and Mattes. Ionic liquids, which are liquid over a wide temperature range and can dissolve a wide range of solutes to high concentrations, promise new and yet unexplored approaches in processing ores. We aim to prepare ionic liquids and apply these to increase the intensity of copper and gold sulfide processing, and to explore more efficient separation of platinum group metals from mattes. New oxidative leaching techniques will be developed to diminish ore passivation and enhance recovery; high current electrowinning of copper in ionic liquids will be probed. Evolving technology should yield economic and environmental benefits for a nationally important industry.Read moreRead less
Design of Microstructures for Materials and Composites with Desired Functional Properties. The creation of new and advanced materials and composites will underpin the growth in many industrial and economic activities in Australia. This project will meet the substantial scientific and technological challenges in exploring and finding optimal microstructures for materials and composites with desired functional properties. The proposed research will significantly extend a topological optimization t ....Design of Microstructures for Materials and Composites with Desired Functional Properties. The creation of new and advanced materials and composites will underpin the growth in many industrial and economic activities in Australia. This project will meet the substantial scientific and technological challenges in exploring and finding optimal microstructures for materials and composites with desired functional properties. The proposed research will significantly extend a topological optimization technique known as ESO/BESO - an Australian initiative that has earned a widespread international recognition. Its further development and applications will enable the Australian researchers and engineers to maintain and enhance the national capacity to exploit a niche market in the design of novel materials and composites.Read moreRead less
Ab initio Theory in Complex Materials and Surfaces: Prediction and Design of Functional Structures. Using state-of-the-art first-principles theory, this project involves the study of complex materials and surfaces which are central to areas of high technological interest, namely, high temperature ferromagnetic semiconductor materials for spintronics, nitride-based structures for optoelectronic devices, nanocomposites for protective coatings, as well as heterogeneous oxidation catalysis. It wil ....Ab initio Theory in Complex Materials and Surfaces: Prediction and Design of Functional Structures. Using state-of-the-art first-principles theory, this project involves the study of complex materials and surfaces which are central to areas of high technological interest, namely, high temperature ferromagnetic semiconductor materials for spintronics, nitride-based structures for optoelectronic devices, nanocomposites for protective coatings, as well as heterogeneous oxidation catalysis. It will provide fundamental knowledge and understanding on the atomic level, and will facilitate the design and development of functional materials and surfaces of relevance to industry.Read moreRead less
A Novel Approach to Determine Permeability for Cost-Effective Manufacturing of Thermoplastic Matrix Composites. The permeability (resistance of a porous rigid body to a permeating fluid) is an essential parameter for predicting impregnation quality in processing of thermoplastic composite materials. No reliable method exists yet to estimate permeabilities without time-consuming and cost intensive experiments. The aim of the proposed research project is to obtain a basic knowledge in determining ....A Novel Approach to Determine Permeability for Cost-Effective Manufacturing of Thermoplastic Matrix Composites. The permeability (resistance of a porous rigid body to a permeating fluid) is an essential parameter for predicting impregnation quality in processing of thermoplastic composite materials. No reliable method exists yet to estimate permeabilities without time-consuming and cost intensive experiments. The aim of the proposed research project is to obtain a basic knowledge in determining permeabilities of fibre architectures by taking into account their stochastic properties. An innovative approach, based on characterisations of meso-structures of fibre network and simulation of computational fluid dynamics, will be developed to accurately determine permeabilities. The outcome will enable more cost-effective manufacturing of thermoplastic matrix composites.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0237478
Funder
Australian Research Council
Funding Amount
$580,000.00
Summary
A 200 keV Analytical Transmission Electron Microscope. Analytical transmission electron microscopy is one of the most powerful techniques available for investigating and characterising the fine structures, compositions and crystallographic features of geological, biological and engineering materials. It is an essential tool in the arsenal of characterisation equipment for any organisation involved in high quality research and development of materials. The Illawarra region of NSW currently lacks ....A 200 keV Analytical Transmission Electron Microscope. Analytical transmission electron microscopy is one of the most powerful techniques available for investigating and characterising the fine structures, compositions and crystallographic features of geological, biological and engineering materials. It is an essential tool in the arsenal of characterisation equipment for any organisation involved in high quality research and development of materials. The Illawarra region of NSW currently lacks a modern analytical transmission electron microscope to support a wide range of internationally competitive materials research. The aim of this application is to correct this deficiency.Read moreRead less