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
Discovery Early Career Researcher Award - Grant ID: DE220100527
Funder
Australian Research Council
Funding Amount
$420,000.00
Summary
Novel high-performance copper-based materials via additive manufacturing. This project aims to develop novel high-performance copper-based materials produced by additive manufacturing for the electrification revolution, which will provide significantly higher mechanical performance, superior electrical and thermal properties and enable flexible complex shape options. Atomic-scale microstructural analysis using advanced microscopy techniques will reveal profound new insights into the process-stru ....Novel high-performance copper-based materials via additive manufacturing. This project aims to develop novel high-performance copper-based materials produced by additive manufacturing for the electrification revolution, which will provide significantly higher mechanical performance, superior electrical and thermal properties and enable flexible complex shape options. Atomic-scale microstructural analysis using advanced microscopy techniques will reveal profound new insights into the process-structure-property relationship. Expected outcomes include new understandings of the fundamental physics of new functional materials, eco-friendly products, and an ability to facilitate the increasingly widespread use of the copper-based materials for renewable electricity towards a more sustainable society and economy.Read moreRead less
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
Discovery Early Career Researcher Award - Grant ID: DE200101105
Funder
Australian Research Council
Funding Amount
$423,856.00
Summary
Probing the nanomechanics of single grain boundary with decorated solutes. Grain boundaries (GBs) are thermodynamically susceptible to attract solutes to reduce system energy. Elaborately manipulating the GB nanostructure and chemistry via segregation can essentially be conducive, rather than detrimental, to materials performance. However, the underlying mechanism of GB segregation and its detailed effect on material properties remain elusive due to the GB complexities in the polycrystals. Throu ....Probing the nanomechanics of single grain boundary with decorated solutes. Grain boundaries (GBs) are thermodynamically susceptible to attract solutes to reduce system energy. Elaborately manipulating the GB nanostructure and chemistry via segregation can essentially be conducive, rather than detrimental, to materials performance. However, the underlying mechanism of GB segregation and its detailed effect on material properties remain elusive due to the GB complexities in the polycrystals. Through correlative in-situ nanomechanical testing and atom probe tomography, this project aims to unravel the rationale of segregation behaviour of individual GBs and its effectiveness to enhance the material performance, and hence enable nanostructural design of advanced metallic materials with unprecedented properties.Read moreRead less
Atomic-scale insights into interfaces in ultrafine-grained, low-solute alloys. This project will involve the development and application of innovative advanced microscopy methods for the study of the stability of new, ultrafine-grained alloys. This will allow the design of new alloys with exceptional properties for structural applications in environments that require ultra-high performance.
Discovery Early Career Researcher Award - Grant ID: DE170100307
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
Solute segregation in crystal defects in advanced magnesium alloys. This project aims to investigate solute segregation in crystal defects, and explore its effect on technologically significant lightweight magnesium alloys. Magnesium alloys could improve energy efficiency and system performance in automotive, aerospace, aircraft, mobile electronics, rechargeable batteries and biomedical applications. The intended outcome is a knowledge platform for the physical metallurgy design of magnesium all ....Solute segregation in crystal defects in advanced magnesium alloys. This project aims to investigate solute segregation in crystal defects, and explore its effect on technologically significant lightweight magnesium alloys. Magnesium alloys could improve energy efficiency and system performance in automotive, aerospace, aircraft, mobile electronics, rechargeable batteries and biomedical applications. The intended outcome is a knowledge platform for the physical metallurgy design of magnesium alloys for green environment applications and advancing Australia’s established research capability.Read moreRead less
Understanding grain boundary segregation - a route to developing new advanced engineering materials. This project will investigate atomic-scale grain boundary segregation - one of the most important factors influencing the properties of engineering alloys. This will be applied in the development of new Ti, Zr and nanocrystalline alloys with a large potential market and for which Australia is extremely well positioned to become a major producer.
Quantifying the role of impurities in nanocrystalline metals. This project aims to create new designer nanocrystalline materials with applications in aerospace, transportation and medical devices through the controlled addition of impurity elements. This project will investigate and predict the fundamental role of these impurities to be able to tailor the mechanical properties to particular applications.
Interactions between linear and interfacial crystalline defects and their impact on mechanical properties in nanostructured metals and alloys. The project aims to apply in-situ deformation transmission electron microscopy to investigate the interactions among crystalline defects in nanostructured metallic materials and to explore the effect of the interactions on mechanical properties. The results will guide the structural design of nanomaterials with superior mechanical properties.
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