Potassium ion batteries for large scale renewable energy storage. The project aims to develop potassium ion batteries for renewable energy storage and conversion. Potassium ion batteries could be the most promising choice for large-scale electrical energy storage, particularly for renewable energy sources and smart electrical grids, due to their low cost, natural abundance and the advantages of potassium compared to lithium/sodium ion batteries. This study will research the electrochemical react ....Potassium ion batteries for large scale renewable energy storage. The project aims to develop potassium ion batteries for renewable energy storage and conversion. Potassium ion batteries could be the most promising choice for large-scale electrical energy storage, particularly for renewable energy sources and smart electrical grids, due to their low cost, natural abundance and the advantages of potassium compared to lithium/sodium ion batteries. This study will research the electrochemical reactions and charge transfer pathway of electrode materials with excellent potassium ion storage performance. This project is expected to develop high performance potassium ion batteries and advance the prominence of Australia in the global renewable energy market.Read moreRead less
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
Discovery Early Career Researcher Award - Grant ID: DE120102836
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
A novel fully inorganic quantum dots based solar cell. A fully-inorganic quantum dots solar cell will be constructed by using cheap chemical solution techniques. The development of the new 3rd generation solar cell is aimed to realise the high-efficiency, low-cost, and well-stability of solar cells. It would dramatically increase commercial viability of quantum solar cells.
Exploration of Advanced Nanostructures for Sodium-ion Battery Application. The aim of this project is to develop advanced nanostructured electrode materials for high energy, long service life sodium-ion batteries. Sodium-ion batteries are the most promising choice for large-scale electrical energy storage, in particular for renewable energy sources and smart electric grids, owing to their low cost and natural abundance of sodium. The success of this project will advance fundamental understanding ....Exploration of Advanced Nanostructures for Sodium-ion Battery Application. The aim of this project is to develop advanced nanostructured electrode materials for high energy, long service life sodium-ion batteries. Sodium-ion batteries are the most promising choice for large-scale electrical energy storage, in particular for renewable energy sources and smart electric grids, owing to their low cost and natural abundance of sodium. The success of this project will advance fundamental understanding of sodium-ion batteries, and provide techniques for the development of a promising low-cost system for renewable energy storage, which is urgently needed in smart electricity grids. Read moreRead less
Improving battery safety with boron nitride nanotube separators. This project aims to improve the safety of lithium ion batteries by developing high –temperature, stable separators. The use of batteries in a hot Australian summer is a major safety issue for our society. This project will develop a new and safe battery technology with the help of boron nitride nanotubes to effectively reduce the risk of thermal runaway of battery cells. The expected outcomes will have a global impact on the safet ....Improving battery safety with boron nitride nanotube separators. This project aims to improve the safety of lithium ion batteries by developing high –temperature, stable separators. The use of batteries in a hot Australian summer is a major safety issue for our society. This project will develop a new and safe battery technology with the help of boron nitride nanotubes to effectively reduce the risk of thermal runaway of battery cells. The expected outcomes will have a global impact on the safety of the current battery technology and the innovative application of boron nitride nanotubes in battery technology. It will position industry on the cutting edge of battery technology required for energy storage development in Australia.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE170101009
Funder
Australian Research Council
Funding Amount
$349,208.00
Summary
Materials architecture design for low-cost energy storage application. This project aims to develop anode materials for high energy, long service life sodium-ion batteries. The natural abundance of sodium makes sodium-ion batteries the most promising low cost system for large-scale electrical energy storage. However, they are limited by the low rate of diffusion through their anodes. This project will investigate the electrochemical sodiation/desodiation anisotropy on different crystalline facet ....Materials architecture design for low-cost energy storage application. This project aims to develop anode materials for high energy, long service life sodium-ion batteries. The natural abundance of sodium makes sodium-ion batteries the most promising low cost system for large-scale electrical energy storage. However, they are limited by the low rate of diffusion through their anodes. This project will investigate the electrochemical sodiation/desodiation anisotropy on different crystalline facets of anode materials to identify more rapid diffusion pathways and develop a better, high-rate. Success is expected to improve battery performance and enable energy distributors to lower the cost of renewable electrical energy, encouraging its adoption.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE160101163
Funder
Australian Research Council
Funding Amount
$365,000.00
Summary
Design of Nanostructured Electrocatalysts for Water Splitting. The project intends to develop electrocatalysts for water splitting (where a chemical reaction separates water into oxygen and hydrogen, providing clean renewable fuel). The efficient use of renewable energy to generate clean fuels will provide a direct solution to the energy issues in Australia. This project aims to develop new catalysts for the water splitting process by taking into account their electronic structures and verifying ....Design of Nanostructured Electrocatalysts for Water Splitting. The project intends to develop electrocatalysts for water splitting (where a chemical reaction separates water into oxygen and hydrogen, providing clean renewable fuel). The efficient use of renewable energy to generate clean fuels will provide a direct solution to the energy issues in Australia. This project aims to develop new catalysts for the water splitting process by taking into account their electronic structures and verifying their apparent activities in devices. The universal principles to be discovered in the project may be important for the discovery of new electrocatalysts for key energy conversion reactions to develop a feasible clean energy infrastructure and solve environmental issues.Read moreRead less
In pursuit of high performance lithium-oxygen batteries. This project aims to achieve high-energy lithium-oxygen batteries for electric vehicles. Electrification of road transport will minimise consumption of fossil fuels, reduce carbon dioxide emissions, and increase energy security. Lithium-oxygen batteries have the highest energy density among all rechargeable battery systems, which is more than 10 times the density of current lithium-ion batteries. Through exploration of new catalysts, redox ....In pursuit of high performance lithium-oxygen batteries. This project aims to achieve high-energy lithium-oxygen batteries for electric vehicles. Electrification of road transport will minimise consumption of fossil fuels, reduce carbon dioxide emissions, and increase energy security. Lithium-oxygen batteries have the highest energy density among all rechargeable battery systems, which is more than 10 times the density of current lithium-ion batteries. Through exploration of new catalysts, redox mediators, and porous material architectures, this project intends to significantly improve the performance of lithium-oxygen batteries, including specific capacity, cycle life and round-trip efficiency.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100017
Funder
Australian Research Council
Funding Amount
$300,000.00
Summary
An integrated system for measuring thermoelectric properties of advanced materials. This facility will establish an integrated measuring system which will form the key step in developing thermoelectric materials. The instruments will support groundbreaking research in developing advanced materials with significant economic and environmental benefits for many industries, such as materials manufacturing and improving automobile energy efficiency.
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.