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Effects of grain size on the deformation mechanisms and mechanical properties of Gum Metals (Ti alloys). The project aims to understand the relationships among grain size, mechanical properties and deformation mechanisms using in-situ deformation transmission electron microscopy techniques. This will provide the fundamental science for designing Gum Metals with superior properties for a range of engineered and biomedical applications.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100030
Funder
Australian Research Council
Funding Amount
$1,200,000.00
Summary
Advanced focused ion beam (FIB) / scanning electron microscopes (SEM) for nanometre scale characterisation and fabrication. These instruments are designed to provide fundamental insights into physical and biological systems though characterisation and fabrication of structures at nanometre length scales. These versatile platforms will support a wide range of projects covering three national research priority areas. These range from the characterisation of light alloys for improving and building ....Advanced focused ion beam (FIB) / scanning electron microscopes (SEM) for nanometre scale characterisation and fabrication. These instruments are designed to provide fundamental insights into physical and biological systems though characterisation and fabrication of structures at nanometre length scales. These versatile platforms will support a wide range of projects covering three national research priority areas. These range from the characterisation of light alloys for improving and building Australia's Aluminium, Magnesium and Titanium alloy industries, to the study of aerosol particles for improved pulmonary drug delivery for asthma patients, the development of advanced solar cells and the study of the integrated behaviour of the soil-microbe system for sustainable agriculture.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100139
Funder
Australian Research Council
Funding Amount
$350,000.00
Summary
A Hot Isostatic Press (HIP) for aerospace and biomedical component processing. This facility will provide a hot isostatic press of sufficiently large capacity to maximise production efficiencies in aerospace and biomedical applications through net shape manufacturing. The facility will be able to process small components or prototypes which will behave in a manner similar to larger scale components.
Development of a solid nitrogen cooled magnesium diboride (MgB2) magnet for persistent-mode operation. Soaring price for liquid helium has increased demand for cryogen-free superconducting magnets more than ever. If magnetic resonance imaging magnets, which represent over 50 per cent of the world superconducting markets, could be operated without liquid helium, magnetic resonance imaging would be much more affordable and enable reduced health care costs.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100028
Funder
Australian Research Council
Funding Amount
$720,000.00
Summary
Ultra-high resolution and advanced analytical scanning electron microscope facility. This scanning electron microscope facility will form an essential part of characterising a broad range of material types, from nanometre sized particles through to cells and their interactions.
Predicting strength of porous materials. This project aims to develop a predictive theory of strength for unflawed, low-ductile porous materials – an unsolved problem in computational solid mechanics. Three-dimensional printing of lightweight, porous materials is used in industry, medicine and science. The project will develop the theory and conduct experiments on porous metallic and polymeric samples made using additive manufacturing, which require understanding and optimisation of the building ....Predicting strength of porous materials. This project aims to develop a predictive theory of strength for unflawed, low-ductile porous materials – an unsolved problem in computational solid mechanics. Three-dimensional printing of lightweight, porous materials is used in industry, medicine and science. The project will develop the theory and conduct experiments on porous metallic and polymeric samples made using additive manufacturing, which require understanding and optimisation of the building of fine scale features. Understanding strength should improve design of stronger materials, by using and extending the capabilities of three-dimensional printing. These advances will further provide a much-needed basis for a fundamental understanding of fracture in other porous materials important to society such as concrete, rocks, porous ceramics and bone implants.Read moreRead less
Accelerating the formation of equilibrium intermetallic compounds. This project aims to develop new processing techniques to accelerate the formation of low temperature intermetallic compounds. Many exciting compounds cannot currently be used in technological applications, as they would require extremely protracted heat treatments to produce. The project will aim to determine if formation of these compounds will be accelerated if the precursor alloys are mechanically disordered so that they cont ....Accelerating the formation of equilibrium intermetallic compounds. This project aims to develop new processing techniques to accelerate the formation of low temperature intermetallic compounds. Many exciting compounds cannot currently be used in technological applications, as they would require extremely protracted heat treatments to produce. The project will aim to determine if formation of these compounds will be accelerated if the precursor alloys are mechanically disordered so that they contain a very high density of defects. This problem will be explored by investigating the formation of prototypical materials including ferromagnetic and precious metal intermetallic compounds from disordered precursors. The project will result in improved strategies for manufacturing intermetallic compounds.Read moreRead less
Porous beta-titanium bone implants optimised for strength and bio-compatibility: design and fabrication. The project aims to develop the scaffold-design and manufacturing techniques that will underpin the next generation of bone implants. The scaffolds will be specifically designed to match the key biomechanical properties of bone, and fabricated from novel titanium alloys using the latest generation of advanced manufacturing technologies.
Microbial infestation of pre-painted steel building materials: chemical and microbial characterization, model development and control strategies. Coated steel building materials are a multi-billion dollar Australian industry. Microorganisms form slime layers on those materials, which are unsightly and reduce their energy benefits. The project will identify the problem organisms, the factors that facilitate their growth and will develop novel biofilm resistant, functional building materials.
Development of new aluminium alloys through big data analytics. This project aims to address a long-term problem to effectively discover new alloys and processes using big data analytics. It expects to develop new and high-performance aluminium alloys and to generate new knowledge in the area of materials science from investigation of the strengthening and toughening mechanisms. The intended outcomes also include a validated big data analytic model for new alloy development, which further enhan ....Development of new aluminium alloys through big data analytics. This project aims to address a long-term problem to effectively discover new alloys and processes using big data analytics. It expects to develop new and high-performance aluminium alloys and to generate new knowledge in the area of materials science from investigation of the strengthening and toughening mechanisms. The intended outcomes also include a validated big data analytic model for new alloy development, which further enhances the interdisciplinary collaboration. The high performance aluminium alloys should provide significant benefits to automotive and aerospace industries as these sectors target at improving fuel efficiency through weight reduction at lower cost.Read moreRead less