Discovery Early Career Researcher Award - Grant ID: DE130100090
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Novel anodic coating of magnesium alloy components for corrosion protection. This research aims to protect magnesium alloys from corrosion, paving a path for them to be used as auto and aircraft components. It will establish novel protective anodic coatings upon magnesium and thereby pioneer implementation of magnesium alloys more generally, as galvanising did for steels.
High performance cast magnesium alloys. Reducing the weight of cars, particularly their engines, enables substantial reductions in fuel consumption and greenhouse gas emissions. A new generation of magnesium alloys will be developed by this project for the manufacture of considerably lighter components with improved mechanical performance for powertrain and structural applications.
Nanostructured soft magnetic alloys for low-carbon cars. The aim of this project is to prepare iron-based magnetic nanostructures that exhibit a magnetic induction of 1.9 tesla and core losses lower than those of iron-silicon steels, which would deliver smaller and efficient magnetic cores for petrol-electric hybrid cars. Preliminary results from the research team show that iron-metalloid alloys with an iron content of 87 per cent meet this magnetic induction with room for further improvement of ....Nanostructured soft magnetic alloys for low-carbon cars. The aim of this project is to prepare iron-based magnetic nanostructures that exhibit a magnetic induction of 1.9 tesla and core losses lower than those of iron-silicon steels, which would deliver smaller and efficient magnetic cores for petrol-electric hybrid cars. Preliminary results from the research team show that iron-metalloid alloys with an iron content of 87 per cent meet this magnetic induction with room for further improvement of magnetic softness. The project aims to systematically investigate the effect of metalloid and micro-alloying elements on the nano-crystallisation behaviour of the precursor amorphous alloys in order to identify the alloy composition and processing conditions for preparing magnetically soft nanostructures.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: De130100090
Funder
Australian Research Council
Summary
Novel anodic coating of magnesium alloy components for corrosion protection. This research aims to protect magnesium alloys from corrosion, paving a path for them to be used as auto and aircraft components. It will establish novel protective anodic coatings upon magnesium and thereby pioneer implementation of magnesium alloys more generally, as galvanising did for steels.
High performance cast magnesium alloys. Reducing the weight of cars, particularly their engines, enables substantial reductions in fuel consumption and greenhouse gas emissions. A new generation of magnesium alloys will be developed by this project for the manufacture of considerably lighter components with improved mechanical performance for powertrain and structural applications.
Deformation mechanisms of metastable titanium alloys. This project aims to understand the response of deformation-induced products in metastable titanium alloys to external loading. Metastable titanium alloys are mechanically tuneable because they can readily twin and phase transform under load during forming or in service. This project will develop a crystal plasticity model that accounts for these deformation mechanisms. These new alloys are expected to make titanium a viable lightweight alter ....Deformation mechanisms of metastable titanium alloys. This project aims to understand the response of deformation-induced products in metastable titanium alloys to external loading. Metastable titanium alloys are mechanically tuneable because they can readily twin and phase transform under load during forming or in service. This project will develop a crystal plasticity model that accounts for these deformation mechanisms. These new alloys are expected to make titanium a viable lightweight alternative for components in the aerospace and transport industries, with the weight savings helping reduce overall energy consumption.Read moreRead less
Growing a multi-scale internal structure: new wrought metals for energy conservation. This research aims to reduce the weight of wrought metal parts so that transport and machinery will use less energy. It will establish how to grow novel multi-scale internal structures and will thereby pioneer a new class of metals that display superior properties.
Discovery Early Career Researcher Award - Grant ID: DE140101596
Funder
Australian Research Council
Funding Amount
$395,220.00
Summary
Development of high performance silicon-based thermoelectrics through band engineering. Thermoelectric (TE) materials, converting waste heat into electricity, have been considered as a sustainable solution to the current energy dilemma. This project aims to realise high-efficiency silicon-based thermoelectrics through rational design of their band structure and nanostructure. This will advance the knowledge of maximising the TE performance in silicon-based thermoelectrics and develop new strateg ....Development of high performance silicon-based thermoelectrics through band engineering. Thermoelectric (TE) materials, converting waste heat into electricity, have been considered as a sustainable solution to the current energy dilemma. This project aims to realise high-efficiency silicon-based thermoelectrics through rational design of their band structure and nanostructure. This will advance the knowledge of maximising the TE performance in silicon-based thermoelectrics and develop new strategies for improving existing TE materials in general. The resulting high performance silicon-based thermoelectrics will greatly promote TE power generation in a more sustainable and environmentally-friendly way, due to their abundance and nontoxicity, benefiting Australia's emerging energy industry, environment and economy.Read moreRead less
Soft magnetic nanostructures for clean automotive technologies: origin of induced magnetic anisotropies. This project will clarify the mechanism of annealing-induced magnetic anisotropies in magnetic nanostructures and thereby establish a basis for further alloy development of efficient core materials for electric motors. The project outcomes will potentially lead to a significant reduction of the heat loss in petrol-electric hybrid cars.
Nanostructured magnetic materials for clean automotive technologies. Greater utilisation of the petrol-electric hybrid technology is an effective and realistic approach to the problem of increasing greenhouse gas emissions from transportation sources. Owing to the requirement of the temperature stability of the magnets used in the electric motors in the current hybrid vehicles, the magnets contain considerable amounts of costly rare-earth elements. This impedes the utilisation of the technology ....Nanostructured magnetic materials for clean automotive technologies. Greater utilisation of the petrol-electric hybrid technology is an effective and realistic approach to the problem of increasing greenhouse gas emissions from transportation sources. Owing to the requirement of the temperature stability of the magnets used in the electric motors in the current hybrid vehicles, the magnets contain considerable amounts of costly rare-earth elements. This impedes the utilisation of the technology and hence alternative cost effective magnets with high temperature stability are needed. In this project we will exploit a range of alloy design strategies in manganese-bismuth/iron nanocomposite magnets, thereby realising a novel permanent magnet, free of costly rare-earth elements.Read moreRead less