Prediction of Atomic Transport Properties in Multicomponent Engineering Alloys. Technological advances bring demands for new engineering materials and the improvement of existing ones. Since almost every property of such materials depends directly or indirectly on matter transport, it is imperative that the materials designer can accurately predict its direction and extent. This theoretical project, supported and tested by computer simulation, will provide this knowledge. It will develop a toolb ....Prediction of Atomic Transport Properties in Multicomponent Engineering Alloys. Technological advances bring demands for new engineering materials and the improvement of existing ones. Since almost every property of such materials depends directly or indirectly on matter transport, it is imperative that the materials designer can accurately predict its direction and extent. This theoretical project, supported and tested by computer simulation, will provide this knowledge. It will develop a toolbox of robust and versatile expressions for predicting and interpreting matter transport in alloy systems at high temperatures. With these expressions in hand, the designer will be in a superior position to tailor the properties of such materials.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0560705
Funder
Australian Research Council
Funding Amount
$825,000.00
Summary
Advanced Deformation Simulation Laboratory. For Australia to maintain its position as a world leader in the science of metals processing it must have the capability for state-of-the-art physical simulation. The present proposal is for the purchase and installation of two leading edge simulation tools: a high rate/short inter-pass hot deformation simulator and a hot equal channel angular extrusion press. Advanced hot deformation simulation is required for the development and optimisation of "fast ....Advanced Deformation Simulation Laboratory. For Australia to maintain its position as a world leader in the science of metals processing it must have the capability for state-of-the-art physical simulation. The present proposal is for the purchase and installation of two leading edge simulation tools: a high rate/short inter-pass hot deformation simulator and a hot equal channel angular extrusion press. Advanced hot deformation simulation is required for the development and optimisation of "fast" industrial processes and for understanding the complex microstructural reactions associated with them. High temperature extrusion is required for the development of ultra-fine and nano-grained light metals.Read moreRead less
A Predictive Theory of Kinetic Demixing in Engineering Ceramics. Technological advances bring demands for new engineering ceramics and the improvement of existing ones. The properties of engineering ceramics are critically dependent on the composition and distribution of atomic components. However, separation or demixing of the components occurs in-service at high temperatures as a result of stress, electric fields or oxygen gradients. Demixing causes a major loss of performance and longevity. T ....A Predictive Theory of Kinetic Demixing in Engineering Ceramics. Technological advances bring demands for new engineering ceramics and the improvement of existing ones. The properties of engineering ceramics are critically dependent on the composition and distribution of atomic components. However, separation or demixing of the components occurs in-service at high temperatures as a result of stress, electric fields or oxygen gradients. Demixing causes a major loss of performance and longevity. This Project will develop a robust and versatile theory of demixing to enhance longevities of engineering ceramics. It will also guide the deliberate manipulation of demixing to generate novel compositionally-graded engineering ceramics having new properties of technological interest.Read moreRead less
A Theory to Predict and Control Porosity Occurring During Diffusion-Bonding. This Project will guide the design of strategies that will substantially improve the diffusion-bonding process and broaden the range of materials possible for bonding. Many Australian industries, from manufacturers of computer chip connectors to aircraft engines, could benefit significantly from the results of this research. By means of the training of computational and theoretical materials scientists/engineers, this P ....A Theory to Predict and Control Porosity Occurring During Diffusion-Bonding. This Project will guide the design of strategies that will substantially improve the diffusion-bonding process and broaden the range of materials possible for bonding. Many Australian industries, from manufacturers of computer chip connectors to aircraft engines, could benefit significantly from the results of this research. By means of the training of computational and theoretical materials scientists/engineers, this Project will also make a substantial contribution to building Australia's research capacity in this internationally recognized growth area.Read moreRead less
Reducing tool wear through novel surface treatments and improved lubrication. High strength steels can be used to make vehicles lighter and safer but forming them into parts requires large forces. This can lead to problems with tool wear and poor surface finish. This project will lead to improved understanding of what makes a lubricant effective and how to design a tool surface to reduce wear. This new knowledge will lead to improved tool designs and products. The competitiveness of the Australi ....Reducing tool wear through novel surface treatments and improved lubrication. High strength steels can be used to make vehicles lighter and safer but forming them into parts requires large forces. This can lead to problems with tool wear and poor surface finish. This project will lead to improved understanding of what makes a lubricant effective and how to design a tool surface to reduce wear. This new knowledge will lead to improved tool designs and products. The competitiveness of the Australian automotive manufacturing industry will be improved and there will be benefits for the local tooling industry, especially in the competition for overseas markets.Read moreRead less
Modelling of Nanostructuring of Bulk Metallic Materials by Severe Plastic Deformation. The use of ultrafine grained alloys is expected to lead to significant breakthroughs in relation to fuel-efficient cars, light weight/high strength designs in aerospace and structural applications, and bio-medical implants. It will provide a wider market for such metals and create niche applications in domestic and export manufacturing industry. The development of technologically viable processes of nanostruct ....Modelling of Nanostructuring of Bulk Metallic Materials by Severe Plastic Deformation. The use of ultrafine grained alloys is expected to lead to significant breakthroughs in relation to fuel-efficient cars, light weight/high strength designs in aerospace and structural applications, and bio-medical implants. It will provide a wider market for such metals and create niche applications in domestic and export manufacturing industry. The development of technologically viable processes of nanostructuring hinges on the fundamental understanding of the fundamental mechanisms of microstructure and texture development. The knowledge base to be developed through this project will bring Australia to the international forefront in the area of structural nanomaterials and prepare the ground for future frontier technologies. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0775721
Funder
Australian Research Council
Funding Amount
$520,000.00
Summary
Near Net Shaped Casting and Alloy Development Facility. Nearly all metal production is based around an initial casting phase, often followed by other deformation and thermal processes. This facility will allow us to study current and future advanced alloys and processing routes, including metals of strategic importance to Australia such as aluminium, titanium and magnesium. One of the major innovations for these metals is to directly cast to strip, followed by minimal processing to provide str ....Near Net Shaped Casting and Alloy Development Facility. Nearly all metal production is based around an initial casting phase, often followed by other deformation and thermal processes. This facility will allow us to study current and future advanced alloys and processing routes, including metals of strategic importance to Australia such as aluminium, titanium and magnesium. One of the major innovations for these metals is to directly cast to strip, followed by minimal processing to provide strip products with novel properties, low capital costs and short lead times. The outcomes from this research will support the development of existing and new metal industries in Australia.Read moreRead less
Strength Enhancement of Aluminium Extrusion Alloys via Novel Thermal Processes and Alloy Composition Control. The aluminium industry in Australia produces ~4% of total goods and services exports nationally and over $2 billon per year in export earnings. The importance of developing energy-efficient processing and manufacturing technologies for aluminium and its alloys is reflected in the Federal Government's Light Metals Action Agenda. The proposed project has the potential to establish a platfo ....Strength Enhancement of Aluminium Extrusion Alloys via Novel Thermal Processes and Alloy Composition Control. The aluminium industry in Australia produces ~4% of total goods and services exports nationally and over $2 billon per year in export earnings. The importance of developing energy-efficient processing and manufacturing technologies for aluminium and its alloys is reflected in the Federal Government's Light Metals Action Agenda. The proposed project has the potential to establish a platform for intelligent design and development of thermal processing technologies for aluminium extrusion alloys with improved mechanical properties. Such technologies are expected to help the Australian aluminium industry to expand its international market share.Read moreRead less
Intelligent Materials Processing: Microstructure And Texture Control In Bcc Metals. In Australia, steel companies are continuing to search for cost effective steel compositions and processing routes. Concurrently, applications for Ti alloys in chemical, medical and aerospace industries are continuing to widen. As an outcome of this project, the basis for the optimisation of processing routes in order to achieve enhanced product properties at lower cost will be established. In the course of this ....Intelligent Materials Processing: Microstructure And Texture Control In Bcc Metals. In Australia, steel companies are continuing to search for cost effective steel compositions and processing routes. Concurrently, applications for Ti alloys in chemical, medical and aerospace industries are continuing to widen. As an outcome of this project, the basis for the optimisation of processing routes in order to achieve enhanced product properties at lower cost will be established. In the course of this work, a new model for the prediction of microstructure and texture evolution during recrystallisation will be developed and new process routes will be designed. Read moreRead less
Interactions between Lattice Defects and Nanoscale Solute Aggregates: Strengthening and Creep Mechanisms in Magnesium Alloys. Advances in manufacturing and processing technologies in recent years have brought renewed interests in magnesium alloys for applications at elevated temperatures (100-200°C). Improvement in strength and creep resistance of existing alloys and development of new alloys require better understanding of strengthening and creep mechanisms and their correlations with deformat ....Interactions between Lattice Defects and Nanoscale Solute Aggregates: Strengthening and Creep Mechanisms in Magnesium Alloys. Advances in manufacturing and processing technologies in recent years have brought renewed interests in magnesium alloys for applications at elevated temperatures (100-200°C). Improvement in strength and creep resistance of existing alloys and development of new alloys require better understanding of strengthening and creep mechanisms and their correlations with deformation behaviour of the alloys. In this project, advanced imaging techniques of transmission electron microscopy and three-dimensional atom probe field-ion microscopy, combined with tensile and creep tests, will be used to study interactions between lattice defects and nanoscale solute aggregates and their quantitative effects on deformation behaviour of magnesium alloys at elevated temperatures. The aim of this project is to develop a robust theory for the design of magnesium alloys with improved strength and creep resistance.Read moreRead less