Discovery Early Career Researcher Award - Grant ID: DE220100656
Funder
Australian Research Council
Funding Amount
$406,742.00
Summary
Aqueous-based potassium ion batteries for scalable energy storage. The aim of this project is to develop aqueous-based potassium ion batteries for new energy storage applications that currently have barely been studied. This project will design novel cathode/anode materials and electrolytes to significantly advance knowledge in this new technology. The expected outcomes include high-performance aqueous-based potassium ion batteries, while new fundamental knowledge of the reaction mechanisms will ....Aqueous-based potassium ion batteries for scalable energy storage. The aim of this project is to develop aqueous-based potassium ion batteries for new energy storage applications that currently have barely been studied. This project will design novel cathode/anode materials and electrolytes to significantly advance knowledge in this new technology. The expected outcomes include high-performance aqueous-based potassium ion batteries, while new fundamental knowledge of the reaction mechanisms will enhance our research capabilities to position Australia as a leader in potassium ion storage.Read moreRead less
Recyclable and Rechargeable All-Solid-State Sodium Ion Batteries. This project aims to design a new generation recyclable and rechargeable all-solid-state sodium ion battery. We will use low cost and abundant sodium as a substitute for expensive and limited lithium to reduce material and environmental costs, and will develop ceramic/polymer composites as safe and environmentally friendly solid-state electrolytes to replace flammable and toxic organic liquid electrolytes. Furthermore, we design a ....Recyclable and Rechargeable All-Solid-State Sodium Ion Batteries. This project aims to design a new generation recyclable and rechargeable all-solid-state sodium ion battery. We will use low cost and abundant sodium as a substitute for expensive and limited lithium to reduce material and environmental costs, and will develop ceramic/polymer composites as safe and environmentally friendly solid-state electrolytes to replace flammable and toxic organic liquid electrolytes. Furthermore, we design a recyclable battery configuration to allow rapid, low cost and green recycling of end-of-life batteries. The new battery will be a safe, low cost and sustainable energy storage technology for the multi-billion dollar electric vehicle and smart grid markets while simultaneously addressing battery recycling issues.Read moreRead less
Degradation of atomically dispersed M-N-C carbon catalysts in acidic media. This project aims to provide a clear understanding of the degradation mechanisms of transition metal (M) and nitrogen (N) co-doped carbon (M-N-C) catalysts in acidic media by utilising new model catalysts, standardised degradation tests, comprehensive catalyst characterisation, and machine learning tools to interrogate mechanistic hypotheses and link degradation mechanisms to specific catalyst characteristics. This proje ....Degradation of atomically dispersed M-N-C carbon catalysts in acidic media. This project aims to provide a clear understanding of the degradation mechanisms of transition metal (M) and nitrogen (N) co-doped carbon (M-N-C) catalysts in acidic media by utilising new model catalysts, standardised degradation tests, comprehensive catalyst characterisation, and machine learning tools to interrogate mechanistic hypotheses and link degradation mechanisms to specific catalyst characteristics. This project expects to generate new knowledge on rationally designing robust hydrogen fuel cell catalysts. This will provide significant benefits, such as new knowledge on catalyst degradation, new catalysts for energy conversion applications, and collaborations with the industry to accelerate Australia’s shift to renewable energy.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
Development of ambient air operation rechargeable sodium-air batteries. This project aims to develop Sodium (Na)-air batteries for large-scale renewable energy storage. The expected outcomes include development of new air cathode materials, gel polymer electrolytes and oxygen selective membranes, establishing novel Na-air battery systems for ambient air operation using advanced electrode materials, gel polymer electrolytes, and oxygen selective membranes, and exploring the electrochemical reacti ....Development of ambient air operation rechargeable sodium-air batteries. This project aims to develop Sodium (Na)-air batteries for large-scale renewable energy storage. The expected outcomes include development of new air cathode materials, gel polymer electrolytes and oxygen selective membranes, establishing novel Na-air battery systems for ambient air operation using advanced electrode materials, gel polymer electrolytes, and oxygen selective membranes, and exploring the electrochemical reaction mechanisms and degradation Na-air battery systems by the operando study method and other advanced techniques. The success of this project will contribute to the Australia Science and Research Priority area of energy.Read moreRead less
Lithium-rich cathode materials for high-energy lithium-ion batteries. This project aims to develop lithium-rich cathode materials for a new generation of high-energy lithium-ion batteries. These innovative materials could double the capacity of commercial cathodes, thereby doubling the energy density of lithium-ion batteries. A further increase is anticipated from fundamental insights into anionic redox. Expected outcomes include materials with optimised architecture and chemistry, stabilisation ....Lithium-rich cathode materials for high-energy lithium-ion batteries. This project aims to develop lithium-rich cathode materials for a new generation of high-energy lithium-ion batteries. These innovative materials could double the capacity of commercial cathodes, thereby doubling the energy density of lithium-ion batteries. A further increase is anticipated from fundamental insights into anionic redox. Expected outcomes include materials with optimised architecture and chemistry, stabilisation of lithium-rich cathodes, identification of redox mechanism of lithium-rich cathode materials, technologies for producing lithium-rich cathode materials on a large scale and fabrication of new generation high-energy lithium-ion batteries. This project will have benefits especially in the transport and energy sectors. Read moreRead less
All-Solid-state Sodium-ion Batteries for Renewable Energy Industry. Sodium-ion batteries have been widely recognised as scalable and sustainable system for renewable energy storage and conversion owing to abundant resource of sodium and low cost. However, the electrochemical performance and safety of this technology must be improved for practical deployment. This project aims to rationally design and synthesise solid-state polymer electrolytes with high sodium ion conductivity and high sodium io ....All-Solid-state Sodium-ion Batteries for Renewable Energy Industry. Sodium-ion batteries have been widely recognised as scalable and sustainable system for renewable energy storage and conversion owing to abundant resource of sodium and low cost. However, the electrochemical performance and safety of this technology must be improved for practical deployment. This project aims to rationally design and synthesise solid-state polymer electrolytes with high sodium ion conductivity and high sodium ion transfer number. The expected outcome of the project is to manufacture all-solid-state sodium-ion batteries for renewable energy industry in Australia. The project will support the transition of energy supply to renewables, and therefore attain a secure and reliable zero-carbon emission energy future. Read moreRead less
Silicon-based Anode Materials for Next Generation Lithium-ion Batteries. This project aims to develop low-cost high-performance silicon-based anode materials for next generation high-energy lithium-ion batteries. A cutting-edge in situ reduction and encapsulation technique will be developed to synthesise sub-nanometer silicon nanoparticles homogeneously embedded in graphite matrix. The newly developed silicon-based anode material is expected to deliver high specific capacity and long cycle life. ....Silicon-based Anode Materials for Next Generation Lithium-ion Batteries. This project aims to develop low-cost high-performance silicon-based anode materials for next generation high-energy lithium-ion batteries. A cutting-edge in situ reduction and encapsulation technique will be developed to synthesise sub-nanometer silicon nanoparticles homogeneously embedded in graphite matrix. The newly developed silicon-based anode material is expected to deliver high specific capacity and long cycle life. The novel silicon-based anode materials will boost the energy density of next generation lithium-ion batteries, which will be used to power electric vehicles and renewable energy storage. This project will benefit the industry partner to launch commercial production of silicon-based anode materials for global market. Read moreRead less
Quest for Sustainable Electrochemical Energy Storage System. This project aims to develop high performance aqueous zinc-ion batteries for grid-scale renewable energy storage. Rechargeable zinc-ion battery is a promising electrochemical energy storage technology owing to its high safety, low-cost and environmental friendliness. By developing high capacity cathode materials, dendrite-free zinc metal anodes and advanced electrolytes, this project expects to achieve practical aqueous zinc-ion batter ....Quest for Sustainable Electrochemical Energy Storage System. This project aims to develop high performance aqueous zinc-ion batteries for grid-scale renewable energy storage. Rechargeable zinc-ion battery is a promising electrochemical energy storage technology owing to its high safety, low-cost and environmental friendliness. By developing high capacity cathode materials, dendrite-free zinc metal anodes and advanced electrolytes, this project expects to achieve practical aqueous zinc-ion batteries with high energy density, long cycle life and cost-effectiveness. The deployment of zinc-ion batteries will enable integration of renewable energies and stabilisation of electricity networks. The project will directly support Australia’s commitment to achieve net zero emissions by 2050.Read moreRead less
Electrocatalytic Refinery for Fuels and Chemicals . The aim is to produce the fundamental science for sustainable production of fuels and chemicals through an advanced electrocatalytic approach using abundant small-molecule sources like water, carbon dioxide, and nitrogen oxides as feedstocks. A range of highly active and selective electrode catalysts will be developed for electrolysis processes at ambient temperatures and pressures, by an interdisciplinary approach combining atomic-level materi ....Electrocatalytic Refinery for Fuels and Chemicals . The aim is to produce the fundamental science for sustainable production of fuels and chemicals through an advanced electrocatalytic approach using abundant small-molecule sources like water, carbon dioxide, and nitrogen oxides as feedstocks. A range of highly active and selective electrode catalysts will be developed for electrolysis processes at ambient temperatures and pressures, by an interdisciplinary approach combining atomic-level material design principles, in situ/ex situ instrumental techniques, and modern computation methods. The expected outcomes will be of great significance for renewable energy use and clean fuel generation – the major energy and environmental challenges facing Australia and the world.Read moreRead less