Functional Strontium Phosphate Coated Magnesium Alloys For ?Orthopaedic Use. This project aims to develop a functional strontium-release surface on magnesium-based orthopaedic implants to suppress the rapid degradation rate of magnesium, facilitate new bone formation and ultimately shorten the healing process. The development of practical, bone-favourable and degradation-inhibiting surfaces for magnesium implants are in demand and can bring significant patient benefits. The project seeks to esta ....Functional Strontium Phosphate Coated Magnesium Alloys For ?Orthopaedic Use. This project aims to develop a functional strontium-release surface on magnesium-based orthopaedic implants to suppress the rapid degradation rate of magnesium, facilitate new bone formation and ultimately shorten the healing process. The development of practical, bone-favourable and degradation-inhibiting surfaces for magnesium implants are in demand and can bring significant patient benefits. The project seeks to establish an understanding of the formation mechanisms of strontium-releasing coatings and determine the critical release rate of strontium to activate bone cell responses.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE210100025
Funder
Australian Research Council
Funding Amount
$468,000.00
Summary
Electron microscopy facilities for in-situ materials characterisation. This project aims to significantly strengthen our national capability in high resolution in-situ transmission electron microscopy through the introduction of special in-situ specimen holders and an imaging detector. The project expects to advance knowledge critical for the design of advanced materials with outstanding properties. Expected outcomes of this project will provide critical support for thorough understanding of how ....Electron microscopy facilities for in-situ materials characterisation. This project aims to significantly strengthen our national capability in high resolution in-situ transmission electron microscopy through the introduction of special in-situ specimen holders and an imaging detector. The project expects to advance knowledge critical for the design of advanced materials with outstanding properties. Expected outcomes of this project will provide critical support for thorough understanding of how the microstructures of materials affect their mechanical, thermal, electrical, and magnetic properties and will facilitate strategic collaborations among Australian scientists. This should promote Australia’s global leadership in materials research and advanced manufacturing.Read moreRead less
Efficient, durable and green chalcopyrite solar powered building steel. This project aims to develop a long-life, stable, high-performance, and green chalcopyrite solar powered building steel, which is expected to offer a shapable truly green building integrated photovoltaic (BIPV) product for building deployment. This will be realized by synergising multidiscipline expertise, integrating established technologies of steel surface treatment, steel and solar cell integration and shaping, high-effi ....Efficient, durable and green chalcopyrite solar powered building steel. This project aims to develop a long-life, stable, high-performance, and green chalcopyrite solar powered building steel, which is expected to offer a shapable truly green building integrated photovoltaic (BIPV) product for building deployment. This will be realized by synergising multidiscipline expertise, integrating established technologies of steel surface treatment, steel and solar cell integration and shaping, high-efficiency chalcopyrite, identified strategies for tackling its durability and toxicity, and advanced macro-to-micro characterizations. The project completion will accelerate the transition to the zero-emission building, establish Australia's excellence in green steel for BIPV, and access a share in the soaring BIPV market.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE220100816
Funder
Australian Research Council
Funding Amount
$430,000.00
Summary
Liquid Metal Nano Metallurgy by Controlled Phase Transition Thermodynamics. The phase transformation thermodynamics of post-transition metals, which form low-melting-point alloys, remain largely unknown. This project aims to explore low-energy metallurgy pathways enabled by liquid metals to discover such dynamics. The strategy is to harvest structured/crystalline materials by incorporating target metal species into liquid metal solvents and stimulating autonomous phase separation and pattern for ....Liquid Metal Nano Metallurgy by Controlled Phase Transition Thermodynamics. The phase transformation thermodynamics of post-transition metals, which form low-melting-point alloys, remain largely unknown. This project aims to explore low-energy metallurgy pathways enabled by liquid metals to discover such dynamics. The strategy is to harvest structured/crystalline materials by incorporating target metal species into liquid metal solvents and stimulating autonomous phase separation and pattern formation during phase transition. Contemporary instruments and technologies will be employed to achieve active control of these fundamental processes at different scales. The expected outcomes will reveal new insights in traditional metallurgy as well as extend metallurgical concepts to electronics, optics, and catalysis.Read moreRead less
Liquid Metal for quench detection sensors and low resistance joints. This project aims to develop next-generation liquid metal-based superconducting joints and quench detection sensors to enable superconducting magnets to operate in “persistent mode”. This would make a significant contribution to improving the safety and performance of superconducting coil systems at a reduced cost. Furthermore, intelligent features will be formulated to prevent hazardous and inefficient operating conditions. Th ....Liquid Metal for quench detection sensors and low resistance joints. This project aims to develop next-generation liquid metal-based superconducting joints and quench detection sensors to enable superconducting magnets to operate in “persistent mode”. This would make a significant contribution to improving the safety and performance of superconducting coil systems at a reduced cost. Furthermore, intelligent features will be formulated to prevent hazardous and inefficient operating conditions. The expected outcome is that an advanced superconducting coil system with improved stability and safety is delivered with newly developed liquid metal-based materials and relevant fabrication techniques.Read moreRead less
Next generation easy-clean lenses by robust liquid-repellent nanotextures. This project aims to produce better performing self-cleaning lenses, which are less likely to get dirty and are easy to clean. It will develop water and oil repellent coatings with superior optical transparency and mechanical, solvent and UV stability for both hard coated and anti-reflection coated optical lenses. Engineering of stable, ultra-liquid repellent nanomaterials on transparent surfaces will create a foundation ....Next generation easy-clean lenses by robust liquid-repellent nanotextures. This project aims to produce better performing self-cleaning lenses, which are less likely to get dirty and are easy to clean. It will develop water and oil repellent coatings with superior optical transparency and mechanical, solvent and UV stability for both hard coated and anti-reflection coated optical lenses. Engineering of stable, ultra-liquid repellent nanomaterials on transparent surfaces will create a foundation of knowledge for the industrial development of the future generation of easy care coatings, with vast application potential.Read moreRead less
Exploiting shear to form new structures of carbon. This project aims to create new, technologically-interesting, materials by combining shear (sliding forces) with high pressure. The work will use both modelling and experiments to understand the pathways to form new materials such as a different form of diamond that is predicted to be harder than regular diamond. Such a material could be used in coatings for cutting tools or ultra-low-scratch surfaces. Expected outcomes include both an understan ....Exploiting shear to form new structures of carbon. This project aims to create new, technologically-interesting, materials by combining shear (sliding forces) with high pressure. The work will use both modelling and experiments to understand the pathways to form new materials such as a different form of diamond that is predicted to be harder than regular diamond. Such a material could be used in coatings for cutting tools or ultra-low-scratch surfaces. Expected outcomes include both an understanding of the importance of shear in the study of high-pressure science, and as a tool to manufacture new functional materials.Read moreRead less
Enhancing biopharmaceuticals: A disruptive bioseparation resin technology. This project aims to develop an innovative and disruptive platform technology for designing and manufacturing tailor-made high-performance bioseparation resins to enhance biopharmaceuticals manufacturing. Bacterial cell factories will be developed to enable biotechnological production of innovative polyester bead-based bioseparation resins, which will revolutionise manufacturing of biopharmaceuticals. Expected outcomes o ....Enhancing biopharmaceuticals: A disruptive bioseparation resin technology. This project aims to develop an innovative and disruptive platform technology for designing and manufacturing tailor-made high-performance bioseparation resins to enhance biopharmaceuticals manufacturing. Bacterial cell factories will be developed to enable biotechnological production of innovative polyester bead-based bioseparation resins, which will revolutionise manufacturing of biopharmaceuticals. Expected outcomes of this project are cost-effective and strongly enhanced approaches for biopharmaceuticals recovery, thereby providing significant benefits to accelerate research and development in early stage discovery and manufacture of biologics, therapeutic proteins and vaccines.Read moreRead less
High performance polymer fibres for recyclable composites . The project aims to develop novel drawn polymer fibres with aligned carbon nanotubes incorporated inside and also grafted nanotubes on their surface. Such polymer fibres can be used to reinforce thermoplastics to make high performance composites with effective recyclability. This is important as the existing thermosetting composites are not recyclable and significant property enhancement require high loading (>30%) of reinforcing fibres ....High performance polymer fibres for recyclable composites . The project aims to develop novel drawn polymer fibres with aligned carbon nanotubes incorporated inside and also grafted nanotubes on their surface. Such polymer fibres can be used to reinforce thermoplastics to make high performance composites with effective recyclability. This is important as the existing thermosetting composites are not recyclable and significant property enhancement require high loading (>30%) of reinforcing fibres. The outcomes of this project will be novel technology for making high stiffness polymer fibres and their use in thermoplastic composites. The benefits will be to allow easy processing and recycling. They will be used in down-sizing of high volume products and high value automotive or aerospace products.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE200100136
Funder
Australian Research Council
Funding Amount
$1,100,000.00
Summary
High Performance Solid State NMR Spectroscopy for Materials Research. The project will support research in a diverse set of fields such as biomedical engineering catalysis, energy storage and waste recovery, with cutting edge next-generation solid state (400 MHz) nuclear magnetic resonance capabilities and research expertise. The system enabling high sensitivity, high throughput analysis over extended temperature range will enable addressing of fundamental questions regarding the structure-prope ....High Performance Solid State NMR Spectroscopy for Materials Research. The project will support research in a diverse set of fields such as biomedical engineering catalysis, energy storage and waste recovery, with cutting edge next-generation solid state (400 MHz) nuclear magnetic resonance capabilities and research expertise. The system enabling high sensitivity, high throughput analysis over extended temperature range will enable addressing of fundamental questions regarding the structure-property relationships of advanced functional materials. Accessible to a wide user base in fundamental and applied research, in medicine, energy, catalysis and recycling of waste, the project will extend the current facilities to develop Sydney as regional centre for advanced solid state nuclear magnetic resonance analysis.Read moreRead less