Large-scale rechargeable lithium battery for power storage and electric vehicle applications. This project aims to develop large-scale rechargeable lithium batteries for power storage and electric vehicles. In order to achieve this target, the related cathode materials, anode materials and electrolyte systems will be developed. The design of battery modules and assembly of prototype lithium ion batteries will be performed. The success of the research will encourage the production of electrode ma ....Large-scale rechargeable lithium battery for power storage and electric vehicle applications. This project aims to develop large-scale rechargeable lithium batteries for power storage and electric vehicles. In order to achieve this target, the related cathode materials, anode materials and electrolyte systems will be developed. The design of battery modules and assembly of prototype lithium ion batteries will be performed. The success of the research will encourage the production of electrode materials and manufacture of rechargeable lithium batteries in Australia. The utilisation of advanced rechargeable lithium batteries in electric vehicles will provide sustainable energy for transportation and greatly reduce green-house emissions in Australian urban areas.Read moreRead less
Functional topological materials for superior thermoelectric applications. The efficient generation of electricity from waste heat remains a significant technological challenge, hampered by the absence of efficient materials for conversion. This project aims to develop functionalized topological materials with ultra-high thermoelectric and photothermal performance for harvesting heat into electricity. A recent breakthrough in device efficiency will be a game-changer and position Australian acade ....Functional topological materials for superior thermoelectric applications. The efficient generation of electricity from waste heat remains a significant technological challenge, hampered by the absence of efficient materials for conversion. This project aims to develop functionalized topological materials with ultra-high thermoelectric and photothermal performance for harvesting heat into electricity. A recent breakthrough in device efficiency will be a game-changer and position Australian academics and industries at the forefront of next generation of renewable power generation and refrigeration products. The outcomes will provide an advantage to end-users and industry, and will open a new market for advanced thermoelectric devices in multidisciplinary fields, communities and emerging industries.Read moreRead less
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
Solid-state lithium batteries using phase-stabilised electrolytes. This project aims to develop advanced lithium batteries using multifunctional phase-stabilised solid-state electrolytes. Solid-state lithium batteries are the ultimate end goal of the battery industry, owing to their unique features including no fire hazard, high energy and power densities, and long service lifespan. By combining nanofabrication and novel electrolyte materials, the project expects to boost the performances of sol ....Solid-state lithium batteries using phase-stabilised electrolytes. This project aims to develop advanced lithium batteries using multifunctional phase-stabilised solid-state electrolytes. Solid-state lithium batteries are the ultimate end goal of the battery industry, owing to their unique features including no fire hazard, high energy and power densities, and long service lifespan. By combining nanofabrication and novel electrolyte materials, the project expects to boost the performances of solid-state lithium batteries, establishing them as an advanced energy technology to meet future energy storage and conversion needs. The newly developed battery technology will be widely used for portable electronics, electric vehicles and smart electricity grids that integrate renewable energy sources.Read moreRead less
Advanced glazing systems for solar energy harvesting and radiation control. Development of advanced energy-saving glass and glazings capable of generating electricity is expected to lead towards new products of significant commercial potential. The outcomes of this project undertaken by Edith Cowan University and Tropiglas will raise the energy efficiency of commercial buildings and vehicles to levels not possible with other technologies.
Development of novel safe lithium metal-free sulphur batteries. Development of novel safe lithium metal-free sulphur batteries. This project aims to develop a lithium-metal-free sulphur battery system, and technology to commercialise this battery technology. Expected outcomes include an electrochemical system consisting of a selected promising lithium sulphide cathode, an alloying type anode and a liquid-based electrolyte, and large lithium-ion sulphur batteries with selected advanced electrode ....Development of novel safe lithium metal-free sulphur batteries. Development of novel safe lithium metal-free sulphur batteries. This project aims to develop a lithium-metal-free sulphur battery system, and technology to commercialise this battery technology. Expected outcomes include an electrochemical system consisting of a selected promising lithium sulphide cathode, an alloying type anode and a liquid-based electrolyte, and large lithium-ion sulphur batteries with selected advanced electrode materials and electrolytes. Anticipated outcomes are the improved safety of typical lithium-sulphur batteries; that Australia will be internationally competitive in the area of energy storage; and increased overseas demand for Australian raw materials for manufacturing lithium-ion batteries.Read moreRead less
High energy density, long life, safe lithium Ion battery for electric cars. This project aims to develop next-generation lithium-ion batteries with high energy density, safety, long cycle life, and fast charge capability, using a Ni-rich layered oxide cathode and silicon/carbon composite anode. This lithium-ion battery system is expected to meet 2020 targets for electric vehicles. The project will also investigate the reaction/electrode fading mechanism of the proposed anode/cathode materials fo ....High energy density, long life, safe lithium Ion battery for electric cars. This project aims to develop next-generation lithium-ion batteries with high energy density, safety, long cycle life, and fast charge capability, using a Ni-rich layered oxide cathode and silicon/carbon composite anode. This lithium-ion battery system is expected to meet 2020 targets for electric vehicles. The project will also investigate the reaction/electrode fading mechanism of the proposed anode/cathode materials for the deep understanding of these electrode materials, and provide guidance for future electrode materials design and battery research. This will provide significant benefits for automotive industries, smart grid, and business in storing renewable energy and better environment and sustainability.Read moreRead less
Novel lithium iron based olivine phosphates as cathode materials for the development of new generation power batteries. Global warming and climate change are a serious threat to our society today. We must reduce greenhouse gas emissions by using renewable energy for sustainable development. Battery technology is regarded as one of the green technologies that can be widely used to power vehicles and store energy. This project will develop new generation lithium-ion power batteries using novel lit ....Novel lithium iron based olivine phosphates as cathode materials for the development of new generation power batteries. Global warming and climate change are a serious threat to our society today. We must reduce greenhouse gas emissions by using renewable energy for sustainable development. Battery technology is regarded as one of the green technologies that can be widely used to power vehicles and store energy. This project will develop new generation lithium-ion power batteries using novel lithium iron based phosphate cathode materials. The success of the research will provide advanced rechargeable batteries for electric bicycles, electric motorcycles and hybrid electric vehicles, contributing to the reduction of CO2 emissions. Read moreRead less
New generation high efficiency thermoelectric materials and modules for waste heat recovery in steelworks. The development of thermoelectric materials and devices, and their subsequent uptake by the steel industry, will bring tremendous socio-economic benefits in terms of decreased operational costs, a significantly reduced carbon footprint and will set an excellent example for other industries on how to comply with strict environmental regulations.
Exploration of new catalyst materials for hydrogen/air fed proton exchange membrane fuel cells. Fuel cell technology is the most critical technology for the hydrogen economy. Hydrogen/air fed fuel cells can provide pollution-free power sources for vehicles and distributed power generation. A breakthrough in fuel cell technology using hydrogen as fuel will supply us with clean and sustainable energy sources, dramatically improve our environment, and maintain national energy security. The success ....Exploration of new catalyst materials for hydrogen/air fed proton exchange membrane fuel cells. Fuel cell technology is the most critical technology for the hydrogen economy. Hydrogen/air fed fuel cells can provide pollution-free power sources for vehicles and distributed power generation. A breakthrough in fuel cell technology using hydrogen as fuel will supply us with clean and sustainable energy sources, dramatically improve our environment, and maintain national energy security. The success of fuel cell technology will also significantly reduce our dependence on oil. This research project is expected to establish local expertise, and scientific and industrial know-how on fuel-cell technology.Read moreRead less