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
Sustainable high energy sodium batteries with enhanced safety & cycle life. This project aims to deliver a high specific energy, ambient temperature sodium metal battery that is more sustainable, safer and better performing than existing technologies. Innovative chemistry will be used to replace the current flammable and toxic organic solvent-based systems, while novel tools and capabilities will be forged to retain Australian leadership in this sector. These advances will provide a technology ....Sustainable high energy sodium batteries with enhanced safety & cycle life. This project aims to deliver a high specific energy, ambient temperature sodium metal battery that is more sustainable, safer and better performing than existing technologies. Innovative chemistry will be used to replace the current flammable and toxic organic solvent-based systems, while novel tools and capabilities will be forged to retain Australian leadership in this sector. These advances will provide a technology and materials platform to generate and support emerging energy storage industries in Australia. It will strengthen international collaborations with leading research teams and provide opportunities and training for the next generation of energy storage research leaders in both academia and industry.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
Embrittlement-tolerant alloys for safe hydrogen transmission and storage. Hydrogen embrittlement in steels is a major impediment to a safe hydrogen economy. This project will determine how hydrogen affects the deformation behaviour of steel, providing the fundamental information that is required to develop alloys that can be safely used in infrastructure for a future Australian hydrogen industry. We will utilise new technologies that allow us, for the first time, to determine the position of hyd ....Embrittlement-tolerant alloys for safe hydrogen transmission and storage. Hydrogen embrittlement in steels is a major impediment to a safe hydrogen economy. This project will determine how hydrogen affects the deformation behaviour of steel, providing the fundamental information that is required to develop alloys that can be safely used in infrastructure for a future Australian hydrogen industry. We will utilise new technologies that allow us, for the first time, to determine the position of hydrogen atoms around micro-scale features and to compare it to local mechanical behaviour, determined by micro-mechanical tests. The systematic investigation of the effect of hydrogen on different micro-components within steel will allow the development of microstructure-guided alloy design principles.Read moreRead less
Low cost aqueous rechargeable zinc batteries for grid-scale energy storage. This project aims to advance energy storage technology by developing high energy aqueous rechargeable zinc batteries, which are the most promising choice for large-scale electrical energy storage, in particular for smart electric grids, owing to their low cost, high safety, and eco-friendly features. The success of this project will advance our fundamental understanding of aqueous rechargeable batteries, provide techniqu ....Low cost aqueous rechargeable zinc batteries for grid-scale energy storage. This project aims to advance energy storage technology by developing high energy aqueous rechargeable zinc batteries, which are the most promising choice for large-scale electrical energy storage, in particular for smart electric grids, owing to their low cost, high safety, and eco-friendly features. The success of this project will advance our fundamental understanding of aqueous rechargeable batteries, provide techniques for the development of a low-cost, high energy, and long life system for renewable energy storage, and benefit Australia's environment, economy, and sustainability.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200101384
Funder
Australian Research Council
Funding Amount
$411,888.00
Summary
Economical electrode materials for safe sodium ion batteries. The project aims to address the lack of effective anode materials for high performance sodium-ion batteries, through the development of functional titanium-based materials, realizing high energy/power density, long cycle life, low cost and high safety sodium ion batteries. Expected outcomes of this project will address the limitation of current energy storage technologies and be beneficial for the development of large-scale energy sto ....Economical electrode materials for safe sodium ion batteries. The project aims to address the lack of effective anode materials for high performance sodium-ion batteries, through the development of functional titanium-based materials, realizing high energy/power density, long cycle life, low cost and high safety sodium ion batteries. Expected outcomes of this project will address the limitation of current energy storage technologies and be beneficial for the development of large-scale energy storage systems that are efficient, cost-effective and reliable in Australia. This project will explore titanium-based materials with advantageous architectures and deeply doped heteroatoms by novel synthetic strategies and will be assessed as electrode materials for high performance batteries.Read moreRead less
Next-generation fluid-in-solid capacitor materials. This project will create next-generation materials to maximize the energy and power densities of electrochemical capacitors (ECs). The performance gap between batteries and ECs remains paradox. Devices with high energy and power densities will largely boost the performance of electric vehicles, mobile devices and smart grids. By innovating the design of capacitor materials using layered fluid-in-solid architecture, the project will produce new- ....Next-generation fluid-in-solid capacitor materials. This project will create next-generation materials to maximize the energy and power densities of electrochemical capacitors (ECs). The performance gap between batteries and ECs remains paradox. Devices with high energy and power densities will largely boost the performance of electric vehicles, mobile devices and smart grids. By innovating the design of capacitor materials using layered fluid-in-solid architecture, the project will produce new-concept ECs with energy density approaching to batteries. Such ECs will synchronously possess dramatically high power density, intrinsically unlike hybrid battery-capacitor. This project will maximize the efficiency of future electronics, vehicles and grids with the new generation ECs.Read moreRead less
A thermal battery for dish-Stirling concentrated solar power systems. This project will investigate new high temperature (> 600 degrees Celsius) metal hydrides and carbonates suitable for thermochemical energy storage in dish-Stirling Concentrated Solar Power systems. The intended outcome is to discover cost effective, energy dense materials that are capable of operating over a 30 year life span in a solar power plant. This will enable 24/7 electricity production from renewable sources in a disp ....A thermal battery for dish-Stirling concentrated solar power systems. This project will investigate new high temperature (> 600 degrees Celsius) metal hydrides and carbonates suitable for thermochemical energy storage in dish-Stirling Concentrated Solar Power systems. The intended outcome is to discover cost effective, energy dense materials that are capable of operating over a 30 year life span in a solar power plant. This will enable 24/7 electricity production from renewable sources in a dispatchable solar platform, ideal for remote locations. The successful development of high temperature metal hydrides and carbonates will finally provide an energy storage solution to dish-Stirling Concentrated Solar Power systems, which will greatly reduce our reliance on fossil fuels to produce electricity.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