Structure-property relationships in compositionally complex alloys. Physical metallurgy has entered a new era of compositionally complex metallic alloys that show unprecedented combinations of mechanical properties enabling the design of more energy-efficient and economically viable applications. This project aims to generate new knowledge about how locally-resolved, nano-scale atomic arrangements control macroscopic deformation behavior in these materials and develop a fundamental understanding ....Structure-property relationships in compositionally complex alloys. Physical metallurgy has entered a new era of compositionally complex metallic alloys that show unprecedented combinations of mechanical properties enabling the design of more energy-efficient and economically viable applications. This project aims to generate new knowledge about how locally-resolved, nano-scale atomic arrangements control macroscopic deformation behavior in these materials and develop a fundamental understanding of their processing-structure-fracture toughness relationships. Expected outcomes include an enhanced capacity to design materials with damage-tolerant properties superior to existing alloys from bottom up, thereby allowing for commercial benefits throughout transportation, defense, and biomedical device sectors.Read moreRead less
Next generation titanium alloys for additive manufacturing. The rise of 3D printing creates unique opportunities for Australian manufacturers to participate in high value global supply chains. However, the lack of development in high quality printable materials is stopping manufacturers from accessing the full potential of 3D printing. This project aims to develop a design strategy for the next generation of titanium metals designed for 3D printing. This project expects to improve functionality ....Next generation titanium alloys for additive manufacturing. The rise of 3D printing creates unique opportunities for Australian manufacturers to participate in high value global supply chains. However, the lack of development in high quality printable materials is stopping manufacturers from accessing the full potential of 3D printing. This project aims to develop a design strategy for the next generation of titanium metals designed for 3D printing. This project expects to improve functionality of 3D printed metals with qualities that go beyond the most demanding industry acceptance criteria. This project should provide significant benefits by creating new capabilities and improving the productivity of Australian manufacturers while lowering the cost of products for consumers.Read moreRead less
Additive Manufacturing of Nanotwinned Titanium Alloys for Critical Use. The project aims to use 3D printing technology to create new titanium alloy components that are substantially lighter and stronger than current versions and therefore highly relevant for high temperature and stress uses in leading-edge industries such as aeroplane manufacture. The project expects to create new means to strengthen and improve the resilience of the commercial alloys’ microstructure with unprecedented in-servic ....Additive Manufacturing of Nanotwinned Titanium Alloys for Critical Use. The project aims to use 3D printing technology to create new titanium alloy components that are substantially lighter and stronger than current versions and therefore highly relevant for high temperature and stress uses in leading-edge industries such as aeroplane manufacture. The project expects to create new means to strengthen and improve the resilience of the commercial alloys’ microstructure with unprecedented in-service performance and thereby substantially broaden the industrial adoptions of 3D-printed products. This should also provide significant cost and environmental benefits and enhance Australia’s international standing in cutting-edge research on advanced manufacturing and materials.Read moreRead less
Mechanics of micro/nanoscale multilayers: theories and applications. The purpose of the project is to develop novel theoretical models, advanced numerical techniques and guidelines for the design and application of micro/nanoscale multilayers. The expected outcomes are fundamental contributions to the knowledge base of micro/nanoscale multilayered materials which are increasingly used in micro/nanotechnology.
Biocompatible magnesium alloys with specific materials properties. This project aims to develop biocompatible magnesium alloys with highly desirable mechanical properties and degradation on demand, and the fundamental science to achieve the materials properties. Injured human bones often need biomaterials to restore function. This project’s magnesium biomaterials could change the biomaterials field by making implant removal surgery unnecessary, and avoiding the adverse tissue reactions and stres ....Biocompatible magnesium alloys with specific materials properties. This project aims to develop biocompatible magnesium alloys with highly desirable mechanical properties and degradation on demand, and the fundamental science to achieve the materials properties. Injured human bones often need biomaterials to restore function. This project’s magnesium biomaterials could change the biomaterials field by making implant removal surgery unnecessary, and avoiding the adverse tissue reactions and stress shielding typically associated with conventional implanting metals. The outcomes are expected to provide insights in designing biodegradable magnesium alloys and surface coating technology, and generate intellectual properties and advanced biomaterials that will benefit the Australian ageing population.Read moreRead less
The role of structure in the formation and properties of glasses. This project aims to investigate the role of local atomic structure in the formation and mechanical properties of glasses by applying newly developed structure-determination methods. This project expects to establish why glasses form and how their structure gives rise to their undesirable, and limiting, brittle mechanical failure. The anticipated outcomes of this project are better ways to measure the atomic structure of disorder ....The role of structure in the formation and properties of glasses. This project aims to investigate the role of local atomic structure in the formation and mechanical properties of glasses by applying newly developed structure-determination methods. This project expects to establish why glasses form and how their structure gives rise to their undesirable, and limiting, brittle mechanical failure. The anticipated outcomes of this project are better ways to measure the atomic structure of disordered materials and the generation of more clear-cut structure-property relationships for glasses. This will provide significant benefit to Australian industries by enabling the design of better glass-forming systems and stronger, tougher glasses.Read moreRead less