ARC Research Network for Advanced Materials. Materials science/engineering is decidedly interdisciplinary, covering all science and impacting on all manufacturing industry. This network will promote interactions that do not usually occur between materials researchers and students across Australia and internationally from diverse disciplines. The scope is broadly based on advanced materials production, processing and properties but focused in four areas, involving: i) innovative structural/functi ....ARC Research Network for Advanced Materials. Materials science/engineering is decidedly interdisciplinary, covering all science and impacting on all manufacturing industry. This network will promote interactions that do not usually occur between materials researchers and students across Australia and internationally from diverse disciplines. The scope is broadly based on advanced materials production, processing and properties but focused in four areas, involving: i) innovative structural/functional materials, ii) high-tech IT/communications/sensing materials, iii) materials solutions for manufacturing, iv) materials for a sustainable Australia, and v) emerging materials technologies. Key programs will promote interdisciplinary workshops and early career researcher interactions.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0453973
Funder
Australian Research Council
Funding Amount
$696,093.00
Summary
Surface Spectroscopic and Microstructure Analysis. Funding is requested for an X-ray Photoelectron Spectrometer (XPS) and an Image Plate Guinier Camera (IPGC), to update and expand capabilities in surface spectroscopic and microstructural analysis of a wide range of materials. The XPS unit, to be located at the University of SA, will replace two 18-year old XPS units at UniSA and Flinders University. The IPGC is a new and unique instrument which will be located at the University of Adelaide. The ....Surface Spectroscopic and Microstructure Analysis. Funding is requested for an X-ray Photoelectron Spectrometer (XPS) and an Image Plate Guinier Camera (IPGC), to update and expand capabilities in surface spectroscopic and microstructural analysis of a wide range of materials. The XPS unit, to be located at the University of SA, will replace two 18-year old XPS units at UniSA and Flinders University. The IPGC is a new and unique instrument which will be located at the University of Adelaide. These items will be incorporated into the SA Regional Facility, which provides seamless access to instrumentation across nodes. Applications include materials science, geological and biological research projects.Read moreRead less
Protein Fibre Powders: Production, Characterisation and Applications. Australia leads the world in the production of protein fibres such as wool. Traditionally, these fibres are used primarily for textile related applications, which have been increasingly relying on the much cheaper synthetic fibres. The outcome from this research will be very significant in that it will underpin the future development of a sustainable protein fibre industry, through value-added and high-end applications. It wil ....Protein Fibre Powders: Production, Characterisation and Applications. Australia leads the world in the production of protein fibres such as wool. Traditionally, these fibres are used primarily for textile related applications, which have been increasingly relying on the much cheaper synthetic fibres. The outcome from this research will be very significant in that it will underpin the future development of a sustainable protein fibre industry, through value-added and high-end applications. It will further strengthen our world leading position in the production, characterisation and application of protein powder materials.Read moreRead less
Nanostructured Al Alloys: SPD Processing and Properties. The use of conventional Al alloys in automotive and airspace industries is often restricted by their low room temperature strength. Development of high strength Al alloys which could replace much more expensive Ti alloys or heavier steel in constructions is a very promising way to reduce structural weight and cost. Using the Severe Plastic Deformation (SPD) technique, namely high pressure torsion and equal-channel angular extrusion, we ai ....Nanostructured Al Alloys: SPD Processing and Properties. The use of conventional Al alloys in automotive and airspace industries is often restricted by their low room temperature strength. Development of high strength Al alloys which could replace much more expensive Ti alloys or heavier steel in constructions is a very promising way to reduce structural weight and cost. Using the Severe Plastic Deformation (SPD) technique, namely high pressure torsion and equal-channel angular extrusion, we aim to develop a new method for production of bulk nanostructured Al alloy with high room temperature strength for automotive and airspace applications.
Read moreRead less
Boosting photosynthetic efficiency using a plant nanobionics approach. The project aims to improve light capture and enhance electron transport rates using a plant nanobionics approach. Biocompatible plasmonic low-dimensional transition metal oxides with unique optical and electronics properties will be selected as the bioinspired materials. The investigation will focus on developing oxide compounds as artificial antenna, capturing extended optical wavelengths that are not normally available to ....Boosting photosynthetic efficiency using a plant nanobionics approach. The project aims to improve light capture and enhance electron transport rates using a plant nanobionics approach. Biocompatible plasmonic low-dimensional transition metal oxides with unique optical and electronics properties will be selected as the bioinspired materials. The investigation will focus on developing oxide compounds as artificial antenna, capturing extended optical wavelengths that are not normally available to natural plants. Energetic hot electrons excited from plasmonic materials injected into the plant system will further be explored, achieving unprecedented energy conversion from solar to chemical. The anticipated findings will provide a strong base to develop new plant systems with improved photosynthetic efficiency.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0453803
Funder
Australian Research Council
Funding Amount
$535,452.00
Summary
High Performance Optical and Electronic Coatings Facility. The main aim of this project is to establish a state-of-the-art optical and electronic coatings facility for the Australian optoelectronics and nanotechnology research community to develop novel technologies of interest to communications, information technology and nanotechnology industries. The facility will allow the fabrication of a range of active and passive devices including photonic integrated circuits. The facility is f ....High Performance Optical and Electronic Coatings Facility. The main aim of this project is to establish a state-of-the-art optical and electronic coatings facility for the Australian optoelectronics and nanotechnology research community to develop novel technologies of interest to communications, information technology and nanotechnology industries. The facility will allow the fabrication of a range of active and passive devices including photonic integrated circuits. The facility is flexible enough to allow the deposition of a range of dielectric and metal layers with different structural, optical and electrical characteristics of fundamental as well as applied interest. This facility may open up new opportunities to develop microcavities, nanocrystals, tunable lasers and detectors, novel cantilevers for atomic force microscopy.
Read moreRead less
Development of a Superplastic Forming Capabilities in Magnesium-Based Alloys through Processing using Severe Plastic Deformation. This research will provide a basis for advancing the structural use of magnesium alloys in the building and transportation industries. It is anticipated the project will lower the cost of producing lightweight structures and extend the range of alloys that can be used in such applications. With the growing magnesium industry in Australia, and with the potential for Au ....Development of a Superplastic Forming Capabilities in Magnesium-Based Alloys through Processing using Severe Plastic Deformation. This research will provide a basis for advancing the structural use of magnesium alloys in the building and transportation industries. It is anticipated the project will lower the cost of producing lightweight structures and extend the range of alloys that can be used in such applications. With the growing magnesium industry in Australia, and with the potential for Australia to become a major world supplier of magnesium, the development of advanced processing technology for magnesium-based alloys is of national importance. The project will play a vital role in strengthening the Australian technological position and increasing the opportunities for professional Australians.Read moreRead less
Cost effective carbon fibres from polyethylene for lightweight applications. This project aims to deliver cost-effective, high-performance carbon fibres from polyethylene through the use of novel catalysts and advanced processing techniques. Carbon fibre-reinforced composites are extremely strong and light fibre-reinforced polymers that are commonly used wherever high strength-to-weight ratio and rigidity are required, such as in aerospace, automotive and civil engineering applications. However, ....Cost effective carbon fibres from polyethylene for lightweight applications. This project aims to deliver cost-effective, high-performance carbon fibres from polyethylene through the use of novel catalysts and advanced processing techniques. Carbon fibre-reinforced composites are extremely strong and light fibre-reinforced polymers that are commonly used wherever high strength-to-weight ratio and rigidity are required, such as in aerospace, automotive and civil engineering applications. However, broader market uptake is currently limited by carbon fibre costs. The project aims to deliver high-quality fibre with real potential to capture a share of the $14-billion carbon fibre composite market.Read moreRead less
Harnessing properties of liquid metals for future devices. This project aims to hybridise low toxicity liquid metal alloys of gallium with surface confined functional micro/nano materials and explore fundamental new fluidic and physical-chemistry phenomena. Liquid metals are an under-used group of materials, but their combination of flexibility, bestowed by their room temperature fluidity, and metallic properties means they demonstrate startling behaviour. The expected outcomes are new devices a ....Harnessing properties of liquid metals for future devices. This project aims to hybridise low toxicity liquid metal alloys of gallium with surface confined functional micro/nano materials and explore fundamental new fluidic and physical-chemistry phenomena. Liquid metals are an under-used group of materials, but their combination of flexibility, bestowed by their room temperature fluidity, and metallic properties means they demonstrate startling behaviour. The expected outcomes are new devices and systems such as reconfigurable and highly efficient actuators/generators, catalysts, sensors, and electronic and optical components.Read moreRead less
High performance sustainable carbon fibres from Australian spinifex grass. Spinifex grasses cover approximately 30 per cent of our Australian continent, in the driest regions. It has been found that, presumably because of this harsh environment, they are uniquely easy to break down into ultra-long, thin cellulose nanofibrils. Through the use of novel catalysts and advanced processing techniques, this project aims to take advantage of this trait to deliver the cost-effective production of high st ....High performance sustainable carbon fibres from Australian spinifex grass. Spinifex grasses cover approximately 30 per cent of our Australian continent, in the driest regions. It has been found that, presumably because of this harsh environment, they are uniquely easy to break down into ultra-long, thin cellulose nanofibrils. Through the use of novel catalysts and advanced processing techniques, this project aims to take advantage of this trait to deliver the cost-effective production of high strength, sustainable carbon fibres from nanocellulose. It is expected that the use of the world's first university based research facility capable of producing high quality carbon fibre (CarbonNexus) will ensure the product is industrially relevant, with real potential to capture a share of the $14 billion carbon-fibre-composite market.Read moreRead less