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.
Improving the ductility of amorphous alloys via severe plastic deformation. Amorphous alloys are the strongest metallic materials. However, the brittle nature of the materials has significantly limited their applicability in reliability-critical structural applications. Despite significant worldwide efforts, improvement of the ductility has been limited to amorphous alloys with only a few specific compositions. This project aims to develop a universal approach to substantially enhancing the duct ....Improving the ductility of amorphous alloys via severe plastic deformation. Amorphous alloys are the strongest metallic materials. However, the brittle nature of the materials has significantly limited their applicability in reliability-critical structural applications. Despite significant worldwide efforts, improvement of the ductility has been limited to amorphous alloys with only a few specific compositions. This project aims to develop a universal approach to substantially enhancing the ductility of amorphous alloys through the application of severe plastic deformation, to explore the effect of severe plastic deformation on structure, and to reveal the fundamental mechanisms of the mechanical behaviour of amorphous alloys. The results are expected to enable structural design of amorphous alloys with excellent ductility.Read moreRead less
Design of Composites for Exceptional Functional Properties by Maximising the Poisson Effect. This project will establish an effective and efficient computational framework for the topological optimisation of composites whose constituent phases possess significantly different Poisson ratios. In particular, the proposed research will be focused on exploiting the dramatic improvements in functional properties of composites when the Poisson ratio of one of the constituent phases is either negative o ....Design of Composites for Exceptional Functional Properties by Maximising the Poisson Effect. This project will establish an effective and efficient computational framework for the topological optimisation of composites whose constituent phases possess significantly different Poisson ratios. In particular, the proposed research will be focused on exploiting the dramatic improvements in functional properties of composites when the Poisson ratio of one of the constituent phases is either negative or near its incompressibility limit. The expected outcomes will be a new methodology and an advanced engineering design tool that can be used for the development of a new class of composites with exceptional properties. Such new composite systems will have many potential applications, particularly in aerospace, defence and medical industries.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE130100274
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Design of alloys over multiple grain scales for improving fatigue performance. The project will significantly improve the development of engineering alloy design with high fatigue resistance and produce important benefits to Australian manufacturing industries. It will also establish new knowledge and capability in modelling fatigue behaviours, thus producing great benefits to many science and engineering fields.
Discovery Early Career Researcher Award - Grant ID: DE170100053
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Quantitatively probing the nanoscale plasticity of a single grain boundary. This project aims to study grain boundaries, which are important in the mechanical behaviour of nanomaterials. However, the exact contribution of individual grain boundaries to mechanical properties is not well understood, affecting advanced materials design. This project will use in-situ deformation transmission electron microscopy techniques to reveal how individual grain boundaries deform and interact with dislocation ....Quantitatively probing the nanoscale plasticity of a single grain boundary. This project aims to study grain boundaries, which are important in the mechanical behaviour of nanomaterials. However, the exact contribution of individual grain boundaries to mechanical properties is not well understood, affecting advanced materials design. This project will use in-situ deformation transmission electron microscopy techniques to reveal how individual grain boundaries deform and interact with dislocations, and to link directly the structures and orientation of individual grain boundaries with mechanical behaviours. Expected results are better structural design of advanced metallic nanomaterials with superior mechanical performance.Read moreRead less
Flexible roll forming of advanced high strength steel sheet . This project will develop light weight automotive components to assist fuel economy and crash worthiness through flexible roll forming. This process has the potential to form complex shapes from very high strength steels in a very cost effective and efficient small scale operation, highly suited to Australian manufacturing.
Making Strong Alloys Ductile and Hydrogen-Tolerant via Tuning Nanogradients. This project aims to develop a novel design concept of gradient segregation engineering (GSE) to produce high-performance alloys. The innovative GSE will synergistically introduce a chemical gradient via grain boundary segregation and a physical gradient by microstructure control to simultaneously achieve an excellent strength-ductility combination and exceptional resistance to hydrogen embrittlement. This project expec ....Making Strong Alloys Ductile and Hydrogen-Tolerant via Tuning Nanogradients. This project aims to develop a novel design concept of gradient segregation engineering (GSE) to produce high-performance alloys. The innovative GSE will synergistically introduce a chemical gradient via grain boundary segregation and a physical gradient by microstructure control to simultaneously achieve an excellent strength-ductility combination and exceptional resistance to hydrogen embrittlement. This project expects to create new fundamental knowledge and provide critical perspectives for future mechanistic alloy design. The results will enhance Australia’s capacity to develop next-generation advanced alloys to underpin current and emerging industrial applications and strengthen the country’s leading position in materials engineering.Read moreRead less
Topology optimisation? An engineering approach to design of metamaterials. Metamaterials offer unusual physical properties and have significant potential to many technological innovations in precision instrument, medical, telecommunication, space and defence industries in the future. This project aims to develop a computational method for metamaterials so that they can be designed in an effective way.
Real-time imaging of crystal strengthening mechanisms in metals. The strength limit of a metal is marked by rapid motion of crystalline defects. The associated speeds can locally approach that of sound. To probe the associated mechanisms clearly requires both spatial and temporal resolution. We propose to create a new bulk x-ray technique with an unprecedented combination of temporal and spatial resolution. We plan to exploit the technique to mediate a step change in modelling strength based on ....Real-time imaging of crystal strengthening mechanisms in metals. The strength limit of a metal is marked by rapid motion of crystalline defects. The associated speeds can locally approach that of sound. To probe the associated mechanisms clearly requires both spatial and temporal resolution. We propose to create a new bulk x-ray technique with an unprecedented combination of temporal and spatial resolution. We plan to exploit the technique to mediate a step change in modelling strength based on twinning. The formation of crystalline twins is known to dictate the strength of the light metal magnesium. A fuller understanding of the effect of twinning on strength in this metal will provide much needed confidence to implement it more widely in energy saving applications.Read moreRead less
Metal folding fundamentals to shape new corrugated building products . FormFlow has developed a ground-breaking forming process enabling the use of corrugated iron as a structural element. This is a step change for Australia`s steel and building industry and will provide a direct benefit to fireproofing homes. Up scaling of this new technology poses significant challenges due to the lack of understanding in the new forming process and the effect of pre-processing on the incoming material. Fundam ....Metal folding fundamentals to shape new corrugated building products . FormFlow has developed a ground-breaking forming process enabling the use of corrugated iron as a structural element. This is a step change for Australia`s steel and building industry and will provide a direct benefit to fireproofing homes. Up scaling of this new technology poses significant challenges due to the lack of understanding in the new forming process and the effect of pre-processing on the incoming material. Fundamental knowledge of material behaviour will be developed with advanced models that account for the unique process deformation conditions. The intended outcome includes computer software for process design and new concepts for part shape control to improve product quality, repeatability and enable high volume manufacture.Read moreRead less