Linkage Infrastructure, Equipment And Facilities - Grant ID: LE130100051
Funder
Australian Research Council
Funding Amount
$200,000.00
Summary
Fabrication and characterisation facilities for lithium rechargeable batteries and supercapacitors. The facility, unlike any currently existing in Australia, will help researchers studying electrodes and cells at a high level. It will provide a new path to high-level research performance and will significantly enhance Australia’s research capability to bring new materials/technologies under development closer to application.
Nanostrutured Magnesium-base Composites for High-density Hydrogen Storage. This project aims to develop nanocrstalline magnesium-based composites for effective hydrogen storage, overcoming two main technical barriers of current metal hydride systems: high charging/discharging temperature and slow kinetics. Nanoscale catalysts based on mesoporous carbons and metal nanoparticles will be introduced into the magnesium to increase storage capacity and increase the rate at low temperatures. Fundament ....Nanostrutured Magnesium-base Composites for High-density Hydrogen Storage. This project aims to develop nanocrstalline magnesium-based composites for effective hydrogen storage, overcoming two main technical barriers of current metal hydride systems: high charging/discharging temperature and slow kinetics. Nanoscale catalysts based on mesoporous carbons and metal nanoparticles will be introduced into the magnesium to increase storage capacity and increase the rate at low temperatures. Fundamental understanding on the effects of catalysts, and adsorption and desorption mechanisms will be obtained to optimise the composite materials. This project will lead to effective and practical technology for hydrogen storage that will meet the target of commercial fuel cell vehicles.Read moreRead less
New Mg-based hydrogen storage material with destabilised hydrides. This project will develop a new magnesium-based hydrogen storage material for applications such as hydrogen-powered automobiles. Clean energy is a global challenge to reduce greenhouse emissions. Safe storage of hydrogen is a key barrier to the widespread implementation of hydrogen as a clean energy carrier. Magnesium is amongst the few materials able to meet the requirements for effective, safe, light-weight and cheap hydrogen s ....New Mg-based hydrogen storage material with destabilised hydrides. This project will develop a new magnesium-based hydrogen storage material for applications such as hydrogen-powered automobiles. Clean energy is a global challenge to reduce greenhouse emissions. Safe storage of hydrogen is a key barrier to the widespread implementation of hydrogen as a clean energy carrier. Magnesium is amongst the few materials able to meet the requirements for effective, safe, light-weight and cheap hydrogen storage. Light metals is a priority area for Australia with our large resources of aluminium and magnesium. Magnesium-based hydrogen storage could create a huge market for Australian magnesium and hydrogen storage systems. Read moreRead less
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.
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
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