Discovery Early Career Researcher Award - Grant ID: DE180101300
Funder
Australian Research Council
Funding Amount
$368,446.00
Summary
Probing interfacial impedance in all-solid-state lithium-ion batteries. This project aims to investigate the mechanism behind the high impedance at the interface between electrodes and the solid electrolyte in solid-state lithium-ion batteries using advanced in-situ transmission electron microscopy. The outcomes will deepen knowledge in chemical and structural evolution at the electrode–electrolyte interface during battery operation under different conditions, and thus inform the design and fabr ....Probing interfacial impedance in all-solid-state lithium-ion batteries. This project aims to investigate the mechanism behind the high impedance at the interface between electrodes and the solid electrolyte in solid-state lithium-ion batteries using advanced in-situ transmission electron microscopy. The outcomes will deepen knowledge in chemical and structural evolution at the electrode–electrolyte interface during battery operation under different conditions, and thus inform the design and fabrication of safe, high power, and long lasting solid-state batteries for a myriad of portable electronic devices and the emerging electric vehicles.Read moreRead less
Future sodium based electrochemical energy storage technologies. New rechargeable batteries will be developed through the use of breakthrough electrolytes based on liquid salts. These batteries are vital for the widespread use of renewables in Australia's electricity grid. They will also enable new generations of environmental sensor technology.
Discovery Early Career Researcher Award - Grant ID: DE190100005
Funder
Australian Research Council
Funding Amount
$404,000.00
Summary
Perovskite-based electrocatalysts for water electrolysis. This project aims to develop novel perovskite-based catalysts with high catalytic activity and long-term stability for the practical application of alkaline water splitting. A new family of overall water-splitting materials in alkaline media based on low-cost and earth-abundant perovskite oxides will be developed, which offer a viable alternative to the benchmark noble metal-based catalysts. Clean hydrogen energy generated by these effici ....Perovskite-based electrocatalysts for water electrolysis. This project aims to develop novel perovskite-based catalysts with high catalytic activity and long-term stability for the practical application of alkaline water splitting. A new family of overall water-splitting materials in alkaline media based on low-cost and earth-abundant perovskite oxides will be developed, which offer a viable alternative to the benchmark noble metal-based catalysts. Clean hydrogen energy generated by these efficient perovskite catalysts will not only reduce carbon dioxide emissions and alleviate air pollution, but also create opportunities for Australian industries, such as the widespread use of renewable solar and wind energy and fuel cell vehicles.Read moreRead less
Smart utilisation of cobaltite based electrodes on solid oxide fuel cells. This project aims to develop solid oxide fuel cell technologies with significantly simplified fabrication steps and at low cost. It aims to generate fundamental knowledge on the polarisation induced electrode/electrolyte interfaces under fuel cell operation conditions. The advanced fuel cell technologies will in turn substantially increase the energy conversion efficiency and provide significant benefit in the reduction o ....Smart utilisation of cobaltite based electrodes on solid oxide fuel cells. This project aims to develop solid oxide fuel cell technologies with significantly simplified fabrication steps and at low cost. It aims to generate fundamental knowledge on the polarisation induced electrode/electrolyte interfaces under fuel cell operation conditions. The advanced fuel cell technologies will in turn substantially increase the energy conversion efficiency and provide significant benefit in the reduction of greenhouse emission.Read moreRead less
Metal-free catalysts for clean production of energy and hydrogen peroxide. This project aims to create novel metal-free carbon-based catalysts to replace the scarce and expensive noble metal catalysts. Noble metal catalysts are needed for clean production of electricity by fuel cells or hydrogen peroxide from hydrogen and oxygen gases. A combined theoretical and experimental approach will be developed for controlled synthesis of heteroatom-doped carbon catalysts and to improve our understanding ....Metal-free catalysts for clean production of energy and hydrogen peroxide. This project aims to create novel metal-free carbon-based catalysts to replace the scarce and expensive noble metal catalysts. Noble metal catalysts are needed for clean production of electricity by fuel cells or hydrogen peroxide from hydrogen and oxygen gases. A combined theoretical and experimental approach will be developed for controlled synthesis of heteroatom-doped carbon catalysts and to improve our understanding of the catalytic mechanism and structure-activity relationship for the novel carbon catalysts. The project is expected to lay fundamental groundwork for a new paradigm in carbon-based catalysts that should be of considerable significance for energy and chemical production in a clean and cost effective way.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE220101484
Funder
Australian Research Council
Funding Amount
$449,000.00
Summary
Towards Electrochemical Fertiliser Production Powered by Renewable Energy. The electrochemical manufacturing system is a sustainable alternative to traditional fertiliser manufacturing plants. The system can be assembled inexpensively and readily integrated into the renewable electricity grid, solving the greenhouse gas emission issues of the fertiliser plants. This project will identify ground-breaking electrochemical pathways for urea fertiliser and other value-added C-N containing chemicals s ....Towards Electrochemical Fertiliser Production Powered by Renewable Energy. The electrochemical manufacturing system is a sustainable alternative to traditional fertiliser manufacturing plants. The system can be assembled inexpensively and readily integrated into the renewable electricity grid, solving the greenhouse gas emission issues of the fertiliser plants. This project will identify ground-breaking electrochemical pathways for urea fertiliser and other value-added C-N containing chemicals synthesis. Gaseous CO2 and N2 will be electrochemically reacted to produce the C-N bonds. Therefore, a suite of new materials and electrochemical systems for sustainable fertiliser manufacturing will be developed. It is anticipated that the technology will revolutionise Australian fertiliser manufacturing and agriculture.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL110100013
Funder
Australian Research Council
Funding Amount
$2,260,000.00
Summary
New materials for a sustainable energy future. This project will research and develop new selective transport materials to create new sustainable technologies for energy storage (e.g. batteries and capacitors) which will allow greater use of renewable energy sources, desalination and CO2 capture.
Future electrochemical energy storage technologies. New rechargeable batteries will be developed through the use of breakthrough electrolytes based on liquid salts. These batteries are vital for the widespread use of renewables in Australia's electricity grid. They will also enable new generations of environmental sensor technology.