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
Discovery Early Career Researcher Award - Grant ID: DE240100868
Funder
Australian Research Council
Funding Amount
$453,847.00
Summary
High-energy lithium-air batteries, a breathable future for renewable energy. Lithium-air (Li-air) batteries have the highest energy density which is ten folds over commercial lithium-ion batteries. However, the development of Li-air batteries has been impeded by challenges including low capacity, poor energy efficiency and limited cycle life. This project aims to develop a high-energy Li-air battery prototype with long cycle life by designing functional quasi-solid gel polymer electrolytes with ....High-energy lithium-air batteries, a breathable future for renewable energy. Lithium-air (Li-air) batteries have the highest energy density which is ten folds over commercial lithium-ion batteries. However, the development of Li-air batteries has been impeded by challenges including low capacity, poor energy efficiency and limited cycle life. This project aims to develop a high-energy Li-air battery prototype with long cycle life by designing functional quasi-solid gel polymer electrolytes with multi-layer structures via molecular tuning, which could potentially power next-generation electric vehicles. This project is expected to facilitate the commercialisation of high-performance Li-air batteries and promote the development of energy storage devices that are reliable, benefiting both the economy and environment.Read moreRead less
Industry Laureate Fellowships - Grant ID: IL230100039
Funder
Australian Research Council
Funding Amount
$3,516,522.00
Summary
Aqueous sodium batteries for household and smart-grid electricity storage. This project aims to design and commercialise safe, cost-effective, long-lasting, fast-charging, high energy density aqueous sodium-based batteries to store renewable energy for use in households and smart grids. With a focus on developing and scaling technology and in collaboration with industry partners, the project’s expected outcomes include an enhanced ability to store excess energy and modulate its release into a sm ....Aqueous sodium batteries for household and smart-grid electricity storage. This project aims to design and commercialise safe, cost-effective, long-lasting, fast-charging, high energy density aqueous sodium-based batteries to store renewable energy for use in households and smart grids. With a focus on developing and scaling technology and in collaboration with industry partners, the project’s expected outcomes include an enhanced ability to store excess energy and modulate its release into a smart grid during peak demand. Of benefits to Australia, this project will deliver access to reliable, safe and cheap batteries for smart-grid electricity storage in households and a competitive industry manufacturing capability. The downstream benefit is a reduction in energy costs and a contribution to net-zero emissions.
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Adaptive nanofabrication of monolithic multifunctional sensing chips. This project aims to develop a new miniaturised graphene sensing platform integrating multiparameter sensing, wireless charging and data communication on a single chip to revolutionise the ubiquitous wireless sensing networks. By exploring the versatile laser nanofabrication, multiple devices can be inscribed into one flexible mini-chip for the first time. The chip can transform any objects into intelligent, multifunctional an ....Adaptive nanofabrication of monolithic multifunctional sensing chips. This project aims to develop a new miniaturised graphene sensing platform integrating multiparameter sensing, wireless charging and data communication on a single chip to revolutionise the ubiquitous wireless sensing networks. By exploring the versatile laser nanofabrication, multiple devices can be inscribed into one flexible mini-chip for the first time. The chip can transform any objects into intelligent, multifunctional and energy-efficient sensors and find enormous applications in advanced manufacturing, logistics, health monitoring, supply chain and security. It underpins almost every sector of our daily life, securing Australia’s internationally leading position in digitalisation and creating significant social and economic benefits.Read moreRead less
Developing lithium metal batteries – a game-changer for renewable energy. This project aims to develop nanostructured lithium metal anodes for rechargeable lithium metal batteries with high energy density and excellent cycle life. Lithium metal batteries such as lithium-sulfur batteries and lithium carbon-dioxide batteries present great opportunities for long-range electric vehicles and high-efficient renewable energy storage. Through the rational structure design and advanced interface engineer ....Developing lithium metal batteries – a game-changer for renewable energy. This project aims to develop nanostructured lithium metal anodes for rechargeable lithium metal batteries with high energy density and excellent cycle life. Lithium metal batteries such as lithium-sulfur batteries and lithium carbon-dioxide batteries present great opportunities for long-range electric vehicles and high-efficient renewable energy storage. Through the rational structure design and advanced interface engineering, the developed lithium metal anodes are expected to overcome the critical issues that hindered their practical application for high-energy batteries. The success of this project will provide new technological solutions for next-generation energy storage devices.Read moreRead less
Electrolyte and interface engineering of solid-state sodium batteries. This project aims to develop large-scale solid-state sodium-ion batteries exhibiting better safety compared to classic liquid electrolyte batteries without compromising on performance, thus addressing the significant issue of safety in batteries. This will be achieved by novel engineering of solid-state electrolytes and electrolyte-electrode interfacing by a fundamental understanding of sodium-ion transport using statistical ....Electrolyte and interface engineering of solid-state sodium batteries. This project aims to develop large-scale solid-state sodium-ion batteries exhibiting better safety compared to classic liquid electrolyte batteries without compromising on performance, thus addressing the significant issue of safety in batteries. This will be achieved by novel engineering of solid-state electrolytes and electrolyte-electrode interfacing by a fundamental understanding of sodium-ion transport using statistical and machine-learning techniques. Expected outcomes include an understanding of ion-transport mechanisms in batteries, delivery of advanced solid-state electrolytes with high ionic conductivity, and batteries with excellent performance and safety characteristics, which benefits Australia's environment and sustainability.Read moreRead less
Enabling High-performance Layered Oxide Sodium-Ion Battery Cathodes. The great abundance of sodium on the earth's crust and similar work principles have made sodium-ion batteries the most promising replacement for commercial lithium-ion batteries, which are struggling with the increasing cost. This project studies the layered oxides for use as cathodes in sodium-ion batteries. The cross-disciplinary strategy and approaches will be employed to address the weaknesses of such oxides and release the ....Enabling High-performance Layered Oxide Sodium-Ion Battery Cathodes. The great abundance of sodium on the earth's crust and similar work principles have made sodium-ion batteries the most promising replacement for commercial lithium-ion batteries, which are struggling with the increasing cost. This project studies the layered oxides for use as cathodes in sodium-ion batteries. The cross-disciplinary strategy and approaches will be employed to address the weaknesses of such oxides and release the hidden potential to achieve commercialisation. The expected outcome includes advancement in fundamental knowledge of cathode materials design and the development of clean energy, revamping the energy structure of Australia. Read moreRead less