Design and fabrication of custom titanium implant scaffolds produced by selective laser melting. The development of implants that can be tailored to match individual patient requirements will result in increased functionality and longevity of the device, decreased pain and suffering and a reduction in hospitalisation time and medical costs. This is especially true where massive bone loss has occurred. Research in this area is vital to underpin Australian technological progress in a field of ris ....Design and fabrication of custom titanium implant scaffolds produced by selective laser melting. The development of implants that can be tailored to match individual patient requirements will result in increased functionality and longevity of the device, decreased pain and suffering and a reduction in hospitalisation time and medical costs. This is especially true where massive bone loss has occurred. Research in this area is vital to underpin Australian technological progress in a field of rising economic and social importance, especially given Australia's aging population. The project will strengthen expertise in materials science and mathematical optimization. Further, the coupling of these fields will allow Australian scientists and technologists to exploit the full potential of solid freeform fabrication in new applications.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE170101069
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
Two-dimensional inorganic nanostructures for hydrogen evolution reaction. This project aims to synthesise highly active electrochemical catalysts of two-dimensional (2D) inorganic nanostructure for hydrogen evolution reaction (HER). The electrocatalysis of water to produce hydrogen gas could generate clean energy, but the platinum catalyst’s cost and low activity make it impractical. This project will develop 2D inorganic nanosheets with tuneable pores and electronic band structures, hybridised ....Two-dimensional inorganic nanostructures for hydrogen evolution reaction. This project aims to synthesise highly active electrochemical catalysts of two-dimensional (2D) inorganic nanostructure for hydrogen evolution reaction (HER). The electrocatalysis of water to produce hydrogen gas could generate clean energy, but the platinum catalyst’s cost and low activity make it impractical. This project will develop 2D inorganic nanosheets with tuneable pores and electronic band structures, hybridised with organic and/or inorganic semiconductor nanomaterials for HER, and use density functional theory calculation to investigate these hybridised nanosheets’ mechanisms for HER. These highly efficient and low-cost catalysts are expected to generate clean energy and create opportunities for Australian industries.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.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE130100072
Funder
Australian Research Council
Funding Amount
$350,000.00
Summary
An x-ray scattering facility for advanced characterisation of natural and novel materials. This project will establish an analytical facility that will enable measurement of the atomic and finescale structure of materials. This facility will be used to help design novel materials for industrial, environmental and biomedical applications and to develop green technologies and processes for energy production and mining.
Multi-scale Modelling and Simulation of Self-assembling Photonic Crystals. By using bandgaps and introduced defect states, photonic crystals provide the opportunities to shape and mould the flow of light. A success in fabricating 3D photonic crystals with complete bandgaps in a controllable and large-scale fashion will revolutionise the information & telecommunication industry. This ability will provide Australia with a significant niche opportunity at the leading edge of this frontier technolog ....Multi-scale Modelling and Simulation of Self-assembling Photonic Crystals. By using bandgaps and introduced defect states, photonic crystals provide the opportunities to shape and mould the flow of light. A success in fabricating 3D photonic crystals with complete bandgaps in a controllable and large-scale fashion will revolutionise the information & telecommunication industry. This ability will provide Australia with a significant niche opportunity at the leading edge of this frontier technology. It builds on Australia's established strength in material science, photonics, and information & communication technology. The mathematical models, simulation platform, and fabrication methods developed in this project will also be applicable to creating other highly-structured, functional materials.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100094
Funder
Australian Research Council
Funding Amount
$300,000.00
Summary
Selective laser melting - an advanced manufacturing and physical modelling technology for the digital age. Selective laser melting is a new manufacturing technology that creates parts layer by layer directly from a computer model, eliminating the need for tooling or machining. This technology will be applied to a diverse range of research areas from producing the next generation of medical implants and devices to improving our understanding of geo-materials.
Advanced computational techniques for micro/nano multiscale systems of NEMS/BioMEMS. The outcome of this project will have the following benefits to Australia.
1) It will improve the research level in the area of multiscale simulation of NEMS/BioMEMS;
2) The project will be beneficial to possibly establish new industries in the areas of nanotechnology as well as to make good use of today's microelectronics, mircofabrication and computer technology that have already established in Australia;
....Advanced computational techniques for micro/nano multiscale systems of NEMS/BioMEMS. The outcome of this project will have the following benefits to Australia.
1) It will improve the research level in the area of multiscale simulation of NEMS/BioMEMS;
2) The project will be beneficial to possibly establish new industries in the areas of nanotechnology as well as to make good use of today's microelectronics, mircofabrication and computer technology that have already established in Australia;
3) The manpower trained by this project in the areas of multi-scale simulation of MEMS/NEMS/BioMEMS will provide a crucial support for the future industry of Australia.
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Advanced electrochemical capacitors. This project aims to design electrochemical capacitors that can provide self-sustaining power for equipment using renewable energy sources, such as sunlight. Electrical power systems are needed to supply both the peak power and the energy demand that users, particularly those without grid electricity, and their equipment need. This project will match the capacitator electrochemistry to the power attributes of the load and charging source, making them more eff ....Advanced electrochemical capacitors. This project aims to design electrochemical capacitors that can provide self-sustaining power for equipment using renewable energy sources, such as sunlight. Electrical power systems are needed to supply both the peak power and the energy demand that users, particularly those without grid electricity, and their equipment need. This project will match the capacitator electrochemistry to the power attributes of the load and charging source, making them more efficiently charged and able to supply both peak power and energy demand for improved off-grid power supplies and integration of renewable energy into electricity grids.Read moreRead less
Design of reactive foils for joining amorphous alloys. Amorphous alloys or metallic glasses are special materials that retain the random structure of a liquid but in a solid form. They can show special properties of very high strength, toughness and corrosion resistance. The enormous difficulty in joining amorphous alloys to make larger assemblies is greatly curbing their uptake in technology. In this research, state of the art experimental and computational tools will be used to investigate the ....Design of reactive foils for joining amorphous alloys. Amorphous alloys or metallic glasses are special materials that retain the random structure of a liquid but in a solid form. They can show special properties of very high strength, toughness and corrosion resistance. The enormous difficulty in joining amorphous alloys to make larger assemblies is greatly curbing their uptake in technology. In this research, state of the art experimental and computational tools will be used to investigate the extremely fast high temperature reactions occurring in reactive foils of layered metals which, when inserted at the proposed join and ignited, quickly produce a bond. The research will lay the foundation for a robust and reliable means for joining amorphous alloys by means of reactive foils. Read moreRead less
Modelling soft filled viscoelastic solids. Wheat flour doughs are made in vast quantities daily, and improvements in processing, especially in sheeting (rolling) and extrusion are needed. To enable this we will create a novel mathematical description of the material which will be useful for predicting the shapes of processed products. Wheat breeding cycles can be shortened by using the model rheological parameters, since baking quality is closely linked to dough rheology. A number of Australian ....Modelling soft filled viscoelastic solids. Wheat flour doughs are made in vast quantities daily, and improvements in processing, especially in sheeting (rolling) and extrusion are needed. To enable this we will create a novel mathematical description of the material which will be useful for predicting the shapes of processed products. Wheat breeding cycles can be shortened by using the model rheological parameters, since baking quality is closely linked to dough rheology. A number of Australian wheats will be considered and their rheologies will be compared.Read moreRead less