Sodium-Metal-Free, Safe and Sustainable Sodium-Ion Sulfur Batteries. This project aims to develop sodium sulfide cathodes via effective single-atom catalysts and elaborately regulate the solid-electrolyte interphase on the anode by using a new class of electrolytes. Thus, the obtained low-cost, high-energy, safe sodium-ion sulfur batteries can serve as a novel technique for large-scale stationary energy storage, especially for intermittent solar and wind energy storage in Australia. Expected out ....Sodium-Metal-Free, Safe and Sustainable Sodium-Ion Sulfur Batteries. This project aims to develop sodium sulfide cathodes via effective single-atom catalysts and elaborately regulate the solid-electrolyte interphase on the anode by using a new class of electrolytes. Thus, the obtained low-cost, high-energy, safe sodium-ion sulfur batteries can serve as a novel technique for large-scale stationary energy storage, especially for intermittent solar and wind energy storage in Australia. Expected outcomes include a comprehensive understanding and a breakthrough in advances of innovative and affordable battery storage technology, leading to significant scientific, economic, environmental, and social benefits to Australia by integrating this battery system with renewable energy.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE190100504
Funder
Australian Research Council
Funding Amount
$384,000.00
Summary
Interphases and interfaces of nanomaterials in potassium-ion batteries. This project aims to improve the fundamental understanding of interfacial interactions in multicomponent materials, which is a critical precursor to successfully designing and experimentally validating novel layered sulphide systems for potassium-ion batteries. A new layered structure construction technique will be employed to enhance the intrinsic electronic and ionic conductivities in the anode by controllable interphase a ....Interphases and interfaces of nanomaterials in potassium-ion batteries. This project aims to improve the fundamental understanding of interfacial interactions in multicomponent materials, which is a critical precursor to successfully designing and experimentally validating novel layered sulphide systems for potassium-ion batteries. A new layered structure construction technique will be employed to enhance the intrinsic electronic and ionic conductivities in the anode by controllable interphase and interface engineering. The expected outcomes of this project are to generate potassiumion batteries with high energy density, high safety, and long cycle life for next generation energy storage. This project should give Australia a competitive edge in the globally emerging sustainable manufacturing and energy-storage technologies.Read moreRead less
Engineering Nanoionic Interfaces towards High Performance Cathode Coatings. This project aims to develop novel cathode coating materials towards more durable and powerful energy storage devices. Lithium ion battery will be constructed based on perovskite oxides to provide high capacity and stability for potential applications in electric cars, mobile phones and internet of things. The project will address fundamental challenges in this field by developing high voltage cathode coated with nanoion ....Engineering Nanoionic Interfaces towards High Performance Cathode Coatings. This project aims to develop novel cathode coating materials towards more durable and powerful energy storage devices. Lithium ion battery will be constructed based on perovskite oxides to provide high capacity and stability for potential applications in electric cars, mobile phones and internet of things. The project will address fundamental challenges in this field by developing high voltage cathode coated with nanoionic thin layers. Combined with new materials fabrication techniques and innovative strain engineering, the expected outcome is high performance cathodes with enhanced rate capability and cycling life, low fabrication cost and production scalability.
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Discovery Early Career Researcher Award - Grant ID: DE200101103
Funder
Australian Research Council
Funding Amount
$397,286.00
Summary
Stable Lithium-Sodium Metal Anodes for Rechargeable Alkali Metal Batteries. The project aims to address the safety issues derived from the dendritic growth and volume variation of alkali metal anodes, which are a challenge for the practical application of rechargeable alkali metal batteries. This project seeks to design a novel 3D lithium/sodium host featuring a lithiophilic-lithiophobic gradient interfacial layer to achieve uniform deposition and structural stability. The expected outcome of th ....Stable Lithium-Sodium Metal Anodes for Rechargeable Alkali Metal Batteries. The project aims to address the safety issues derived from the dendritic growth and volume variation of alkali metal anodes, which are a challenge for the practical application of rechargeable alkali metal batteries. This project seeks to design a novel 3D lithium/sodium host featuring a lithiophilic-lithiophobic gradient interfacial layer to achieve uniform deposition and structural stability. The expected outcome of this project is to successfully develop alkali metal batteries that are stable, safe and have high energy density. This project should have significant benefits such as the advancement of knowledge in alkali metal batteries and strengthen Australia’s competitiveness in the area of next-generation energy storage technologies.Read moreRead less
Industrial Transformation Research Hubs - Grant ID: IH180100020
Funder
Australian Research Council
Funding Amount
$3,058,152.00
Summary
ARC Research Hub for Integrated Energy Storage Solutions. The ARC Research Hub for Integrated Energy Storage Solutions aims to develop advanced energy storage technologies, including printed batteries, structural supercapacitors, innovative fuel cells and power-to-gas systems. It plans to integrate these storage solutions with existing energy networks and applications using novel storage monitoring, control and optimisation technologies. The Hub is expected to generate new knowledge in storage t ....ARC Research Hub for Integrated Energy Storage Solutions. The ARC Research Hub for Integrated Energy Storage Solutions aims to develop advanced energy storage technologies, including printed batteries, structural supercapacitors, innovative fuel cells and power-to-gas systems. It plans to integrate these storage solutions with existing energy networks and applications using novel storage monitoring, control and optimisation technologies. The Hub is expected to generate new knowledge in storage technology manufacturing, control and management. Expected outcomes include cheaper and more effective storage devices and better storage integration solutions, supporting renewables, reducing carbon emissions, and improving efficiency in the energy sector. Resulting benefits include a more sustainable, secure, reliable and economically efficient energy supply. This Hub will contribute to improving the economic efficiency of Australia’s energy sector.Read moreRead less
Diatomic Electrocatalysts for Efficient Carbon Dioxide Conversion. This project will create novel electrocatalysts to produce valuable C2 compounds (ethylene, ethanol and ethylene glycol) from carbon dioxide reduction reaction. The precise catalyst structure control remains challenging but is crucial for pushing catalyst performance towards practical applications. By innovating organic macrocycle molecules as precursors, this project will generate a new paradigm of diatomic electrocatalysts with ....Diatomic Electrocatalysts for Efficient Carbon Dioxide Conversion. This project will create novel electrocatalysts to produce valuable C2 compounds (ethylene, ethanol and ethylene glycol) from carbon dioxide reduction reaction. The precise catalyst structure control remains challenging but is crucial for pushing catalyst performance towards practical applications. By innovating organic macrocycle molecules as precursors, this project will generate a new paradigm of diatomic electrocatalysts with structure control precision at atomic-scale. Such catalysts are expected to deliver high catalytic performance to accelerate the transformation to a carbon-neutral future. Synchronously, they will also serve as an ideal platform for in-depth mechanism study and establishing guidelines for rational catalyst design Read moreRead less
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
Redox-sensitised dense graphene to boost compact supercapacitors. This project will create redox-sensitised ion-accessible dense graphene to improve the energy density of supercapacitors (SCs). The energy density of SCs is a bottle neck for long-lasting power supply to vehicles, small devices and mobile electronics. By incorporating a redox coordination framework in shrunk graphene to increase the charge storage capacity and speed up the charge movement and further incorporating ionic liquids in ....Redox-sensitised dense graphene to boost compact supercapacitors. This project will create redox-sensitised ion-accessible dense graphene to improve the energy density of supercapacitors (SCs). The energy density of SCs is a bottle neck for long-lasting power supply to vehicles, small devices and mobile electronics. By incorporating a redox coordination framework in shrunk graphene to increase the charge storage capacity and speed up the charge movement and further incorporating ionic liquids in the tailored electrodes, the project will produce SC’s with higher operating voltage and longer cycle life. Such SCs will possess dramatically high energy density, without compromising the power density. This project will improve the efficiency of modern electronics through the development of the next generation of SCs.Read moreRead less
New dielectric materials: Improving storage density of high temperature multilayer ceramic capacitors to sustainably meet future energy demands. Electrical energy generation from renewable sources, such as solar, wind and geothermal, provide enormous potential for meeting future energy demands. However, the ability to store and control this energy for miniaturisation and modularisation in applications requiring a wide temperature usage range is a limiting factor that needs to be addressed. This ....New dielectric materials: Improving storage density of high temperature multilayer ceramic capacitors to sustainably meet future energy demands. Electrical energy generation from renewable sources, such as solar, wind and geothermal, provide enormous potential for meeting future energy demands. However, the ability to store and control this energy for miniaturisation and modularisation in applications requiring a wide temperature usage range is a limiting factor that needs to be addressed. This project aims to develop new bismuth-based lead-free dielectric materials for improving the storage density of high temperature multilayer ceramic capacitors for sustainable applications in the energy and vehicle industries, where high temperature stability and high volumetric efficiency are crucial.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE170100871
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
Carbon-based catalysts for polysulphide redox reactions in lithium-sulfur batteries. This project aims to develop surface-engineered carbons as multifunctional catalysts to accelerate the polysulphide redox reactions for lithium-sulfur batteries. High capacity storage of electricity is the key to efficient use of renewable and clean energy resources and the development of emission-free technologies. This project will provide high-performance lithium-sulfur batteries with high energy density, hig ....Carbon-based catalysts for polysulphide redox reactions in lithium-sulfur batteries. This project aims to develop surface-engineered carbons as multifunctional catalysts to accelerate the polysulphide redox reactions for lithium-sulfur batteries. High capacity storage of electricity is the key to efficient use of renewable and clean energy resources and the development of emission-free technologies. This project will provide high-performance lithium-sulfur batteries with high energy density, high efficiency, and long life. Its success is expected to contribute to energy technologies, reduce the dependence of household and industrial energy consumption on fossil fuels, enhance Australia’s long-term viability, and bring economic, environmental, and social benefits to the nation.Read moreRead less