Special Research Initiatives - Grant ID: SR0354521
Funder
Australian Research Council
Funding Amount
$10,000.00
Summary
Network for Advanced Materials for Engineering Applications. Advances in modern technology and a competitive manufacturing industry depend critically on new and improved materials. The pace of change is rapid, and many countries are taking steps to improve and coordinate developments. Australia has a very successful record of materials research and innovation and is developing a substantial infrastructure in the area. However, the materials research community is scattered, and research effect ....Network for Advanced Materials for Engineering Applications. Advances in modern technology and a competitive manufacturing industry depend critically on new and improved materials. The pace of change is rapid, and many countries are taking steps to improve and coordinate developments. Australia has a very successful record of materials research and innovation and is developing a substantial infrastructure in the area. However, the materials research community is scattered, and research effectiveness is sometimes lessened by a lack of critical mass. This network will bring together university, government and industry researchers, and promote collaborative research, access to each other's facilities, staff and student exchanges, improved access to existing infrastructure and coordinated planning for new acquisitions.Read moreRead less
Processing - Structure Relationships in Thermal Spray Coatings. Researchers in New Zealand have developed novel thermal spray processing treatments which can be used to enahnce the wear, oxidation and corrosion resisitance of materials. However, characterization of the coatings using electron microscopy is essential to understand the relationship between processing conditions and properties. The aim of this project is to draw together specialist expertise and equipment that allows integration ....Processing - Structure Relationships in Thermal Spray Coatings. Researchers in New Zealand have developed novel thermal spray processing treatments which can be used to enahnce the wear, oxidation and corrosion resisitance of materials. However, characterization of the coatings using electron microscopy is essential to understand the relationship between processing conditions and properties. The aim of this project is to draw together specialist expertise and equipment that allows integration of microscopy into the development of these films. Australian researchers will gain access to specialized preparation and testing facilities in New Zealand, whilst researchers from New Zealand will perform structural analysis of these films in Australia.Read moreRead less
Interfacial Structures in Thermal Spray Coatings. The use of coatings on the surfaces of components provides high levels of resistance to mechanical damage, corrosion, oxidation or thermal degradation. As a result, coated components exhibit increased lifetimes and reliability. However, the durability of such components is still crucially limited by the quality of the coating. An improved understanding of the bonding mechanisms that occur during the deposition of such coatings, prepared through t ....Interfacial Structures in Thermal Spray Coatings. The use of coatings on the surfaces of components provides high levels of resistance to mechanical damage, corrosion, oxidation or thermal degradation. As a result, coated components exhibit increased lifetimes and reliability. However, the durability of such components is still crucially limited by the quality of the coating. An improved understanding of the bonding mechanisms that occur during the deposition of such coatings, prepared through thermal spray methods, will provide improvements in coating structure and thus, component performance and lifetime. This will benefit a wide range of manufacturing industries that use such coatings. Read moreRead less
Transmission electron microscopy investigation of the deformation mechanisms of nanostructured materials. Structural materials with high strength and high ductility are desirable because high strength allows structural components to carry high load and high ductility is essential to prevent catastrophic failure. The combination of high strength and high ductility has never been achieved in coarse-grained materials but has been realized in some nanostructured materials. This project aims to unde ....Transmission electron microscopy investigation of the deformation mechanisms of nanostructured materials. Structural materials with high strength and high ductility are desirable because high strength allows structural components to carry high load and high ductility is essential to prevent catastrophic failure. The combination of high strength and high ductility has never been achieved in coarse-grained materials but has been realized in some nanostructured materials. This project aims to understand the mechanisms responsible for the combined high strength and high ductility in nanostructured materials. The results obtained from this research will be very important for guiding the structural design of materials with high strength and high ductility which will find a wide range of civil and defence applications.Read moreRead less
High Strength Steel Protection Bollards. Terrorist attacks cost Australians much human grief and millions of dollars. Prevention of an attack is paramount. Passive road bollards are commonly used to stop a vehicle approaching and/or entering security sensitive infrastructure. Thin-walled tubes are used to manufacture such bollards. However there is a lack of knowledge about their behaviour, and in particular high strength alloy steel bollards, when subjected to impact loads. The investigators wi ....High Strength Steel Protection Bollards. Terrorist attacks cost Australians much human grief and millions of dollars. Prevention of an attack is paramount. Passive road bollards are commonly used to stop a vehicle approaching and/or entering security sensitive infrastructure. Thin-walled tubes are used to manufacture such bollards. However there is a lack of knowledge about their behaviour, and in particular high strength alloy steel bollards, when subjected to impact loads. The investigators will apply their extensive knowledge in thin-walled tubular structures to establish the most economical means of designing high strength bollards. This knowledge will be transferred into design standards and Australia's limited defence resources.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0882926
Funder
Australian Research Council
Funding Amount
$100,000.00
Summary
Transmission Electron Microscope-Nanoindenter for Nano-Mechanical Testing. A transmission electron microscope (TEM)-nanoindenter enables us to record simultaneously the mechanical behaviour of materials under force and their structures and structural evolutions at sub-nanometre resolution. The acquisition of a TEM-nanoindenter will significantly enhance the capability of investigating the structural effect on the behaviour of materials under applied force, which is a key issue in materials scien ....Transmission Electron Microscope-Nanoindenter for Nano-Mechanical Testing. A transmission electron microscope (TEM)-nanoindenter enables us to record simultaneously the mechanical behaviour of materials under force and their structures and structural evolutions at sub-nanometre resolution. The acquisition of a TEM-nanoindenter will significantly enhance the capability of investigating the structural effect on the behaviour of materials under applied force, which is a key issue in materials science and engineering. The results obtained using the TEM-nanoindenter will reveal the fundamental origins of materials mechanical properties and will be used to improve materials processing procedures and to guide the design of stronger and lighter materials for structural applications.Read moreRead less
Dynamically responding metals: a new generation of engineering alloys. The manufacture of engineering metals is a major Australian industry and the worldwide metal manufacturing sector is estimated to be worth $1 trillion USD per annum. Advanced materials and, particularly the light metals, are both designated national research priority areas. The availability of new classes of metals with greatly improved combinations of properties will profoundly affect not only metal use by existing industry, ....Dynamically responding metals: a new generation of engineering alloys. The manufacture of engineering metals is a major Australian industry and the worldwide metal manufacturing sector is estimated to be worth $1 trillion USD per annum. Advanced materials and, particularly the light metals, are both designated national research priority areas. The availability of new classes of metals with greatly improved combinations of properties will profoundly affect not only metal use by existing industry, through the introduction of new, stronger and safer metal grades, but also allows for new engineering designs which will lead, for example, to lighter and more efficient automobiles and more sustainable construction.Read moreRead less
ARC Centre of Excellence - Design in Light Metals. Under the national Light Metals Action Agenda, Australia recognizes a strategic interest in the production, processing and applications of the light metals, and a growth in global markets for light metals technology. Light metals research is a designated national priority, and this Centre will provide the national focus in strategic fundamental research, the critical level of investment and the level of innovation necessary to achieve competiti ....ARC Centre of Excellence - Design in Light Metals. Under the national Light Metals Action Agenda, Australia recognizes a strategic interest in the production, processing and applications of the light metals, and a growth in global markets for light metals technology. Light metals research is a designated national priority, and this Centre will provide the national focus in strategic fundamental research, the critical level of investment and the level of innovation necessary to achieve competitive advantage from an outstanding research base. As a major contributor to a strategic network of national research capabilities, it will underpin substantial developments in the light metals industry nationally and globally, and extend linkages with major research centres internationally.Read moreRead less
New nanolaminate ternary and quaternary alloy phases by thin film synthesis. The availability of suitable materials is a driver of new technologies. We will develop a new class of ternary and quaternary alloys with nanolaminate structures at the atomic scale using a combination of theoretical modeling, novel thin film synthesis and advanced characterization methods. The nanostructure of these materials is expected to promote a rare combination of metallic and ceramic like properties, such as low ....New nanolaminate ternary and quaternary alloy phases by thin film synthesis. The availability of suitable materials is a driver of new technologies. We will develop a new class of ternary and quaternary alloys with nanolaminate structures at the atomic scale using a combination of theoretical modeling, novel thin film synthesis and advanced characterization methods. The nanostructure of these materials is expected to promote a rare combination of metallic and ceramic like properties, such as low friction, high mechanical strength, resistance to heat shock, fracture, corrosion and oxidation, up to very high temperatures. Careful characterisation of the growth process and structure-property relationships will allow us to develop methods of tailoring the property mix for operation in harsh environments.Read moreRead less
First-Principles Engineering of Advanced Multicomponent Materials for Clean, Energy Efficient Thermoelectric and Catalytic Technologies. The quantum mechanical, first-principles calculations for studying advanced multicomponent materials and surfaces of high current technological interest will produce significant results as well as fundamental knowledge of key mechanisms that will aid in the design and tailoring of new catalytic and thermoelectric materials. The project is directly relevant to ....First-Principles Engineering of Advanced Multicomponent Materials for Clean, Energy Efficient Thermoelectric and Catalytic Technologies. The quantum mechanical, first-principles calculations for studying advanced multicomponent materials and surfaces of high current technological interest will produce significant results as well as fundamental knowledge of key mechanisms that will aid in the design and tailoring of new catalytic and thermoelectric materials. The project is directly relevant to the designated priority area - Frontier Technologies for Building and Transforming Australian Industries. It will involve collaboration with leading international experts, thus enhancing Australia's knowledge base and research capacity. This clearly has immediate benefits through the transfer and propagation of cutting-edge knowledge and skills to students and post-docs.Read moreRead less