Industry Laureate Fellowships - Grant ID: IL230100173
Funder
Australian Research Council
Funding Amount
$3,689,641.00
Summary
Accelerating Green Hydrogen Production with High Efficiency Electrolysers. This project aims to accelerate the decarbonisation of high-carbon industries (eg heavy transport, chemical production, and steel) by advancing the manufacture of high efficiency water electrolysers in Australia. Innovative electrochemical and other techniques that exploit all of the levers for high efficiency in electrolysers, will be applied to support the commercial development of this key component of green hydrogen p ....Accelerating Green Hydrogen Production with High Efficiency Electrolysers. This project aims to accelerate the decarbonisation of high-carbon industries (eg heavy transport, chemical production, and steel) by advancing the manufacture of high efficiency water electrolysers in Australia. Innovative electrochemical and other techniques that exploit all of the levers for high efficiency in electrolysers, will be applied to support the commercial development of this key component of green hydrogen production. Expected outcomes of this project, in collaboration with industry partner Hysata, include a low-cost, simplified design, and ultra-high energy efficiency. This should provide significant benefits to the green hydrogen sector, industry, and contribute to achieving net-zero emissions globally.Read moreRead less
Room-temperature sodium-sulfur batteries for large-scale energy storage. This project aims to develop room-temperature sodium-sulfur batteries for renewable energy storage. Sodium-sulfur batteries are ideal for large-scale energy storage, owing to high energy density and low cost. However, there are significant challenges in attaining practical sodium-sulfur batteries with high capacity and safety. By developing novel high capacity sulphur cathodes, dendrite-free sodium metal anodes and quasi-so ....Room-temperature sodium-sulfur batteries for large-scale energy storage. This project aims to develop room-temperature sodium-sulfur batteries for renewable energy storage. Sodium-sulfur batteries are ideal for large-scale energy storage, owing to high energy density and low cost. However, there are significant challenges in attaining practical sodium-sulfur batteries with high capacity and safety. By developing novel high capacity sulphur cathodes, dendrite-free sodium metal anodes and quasi-solid-state gel polymer electrolytes, this project expects to achieve high-performance sodium-sulfur batteries with high capacity, long cycle life and enhanced safety. Expected benefits will arise from deployment of sodium-sulfur batteries and advances in energy storage technologies that are efficient and cost-effective.Read moreRead less
Solid-state lithium batteries using phase-stabilised electrolytes. This project aims to develop advanced lithium batteries using multifunctional phase-stabilised solid-state electrolytes. Solid-state lithium batteries are the ultimate end goal of the battery industry, owing to their unique features including no fire hazard, high energy and power densities, and long service lifespan. By combining nanofabrication and novel electrolyte materials, the project expects to boost the performances of sol ....Solid-state lithium batteries using phase-stabilised electrolytes. This project aims to develop advanced lithium batteries using multifunctional phase-stabilised solid-state electrolytes. Solid-state lithium batteries are the ultimate end goal of the battery industry, owing to their unique features including no fire hazard, high energy and power densities, and long service lifespan. By combining nanofabrication and novel electrolyte materials, the project expects to boost the performances of solid-state lithium batteries, establishing them as an advanced energy technology to meet future energy storage and conversion needs. The newly developed battery technology will be widely used for portable electronics, electric vehicles and smart electricity grids that integrate renewable energy sources.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
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
Discovery Early Career Researcher Award - Grant ID: DE220101354
Funder
Australian Research Council
Funding Amount
$448,169.00
Summary
Novel Ion Exchange Membrane for High Performance Vanadium Flow battery. This project aims to design and synthesis novel ion exchange membrane with tailored ion selectivity and high proton conductivity for vanadium redox flow battery (VRFB). VRFB is a promising energy storage technology for large scale storing renewable energy due to its advantage of decoupled capacity and power, long lifetime. Currently, VRFB suffers from fast capacity decay and cyclic instability because of severe vanadium ion ....Novel Ion Exchange Membrane for High Performance Vanadium Flow battery. This project aims to design and synthesis novel ion exchange membrane with tailored ion selectivity and high proton conductivity for vanadium redox flow battery (VRFB). VRFB is a promising energy storage technology for large scale storing renewable energy due to its advantage of decoupled capacity and power, long lifetime. Currently, VRFB suffers from fast capacity decay and cyclic instability because of severe vanadium ion permeability of commercial membrane. The expected research outcomes in this project include stable, high ion selectivity membranes made of cost-effective aromatic polymer and robust nanofillers, enabling high performance VRFB. This will place Australia in the forefront of clean energy storage technologies.Read moreRead less
Batteries of the future-a new strategy for CO2 fixation and energy storage. This project aims to develop metal-carbon dioxide batteries with high specific energy densities for carbon dioxide capture as well as energy conversion and storage. Metal-carbon dioxide batteries are promising not only for conversion of waste carbon dioxide to value-added chemicals, but also for storage of electricity from renewable power and balancing of the carbon cycle. By combining experimental work and theoretical m ....Batteries of the future-a new strategy for CO2 fixation and energy storage. This project aims to develop metal-carbon dioxide batteries with high specific energy densities for carbon dioxide capture as well as energy conversion and storage. Metal-carbon dioxide batteries are promising not only for conversion of waste carbon dioxide to value-added chemicals, but also for storage of electricity from renewable power and balancing of the carbon cycle. By combining experimental work and theoretical modelling, this study will explore novel electrode materials via catalyst design and understanding of the underlying reaction mechanisms. The outcomes will revolutionize battery technology and position Australia as a global leader in the critical transition to a decarbonized economy.Read moreRead less
Faster interfacial electron transfer: the effect of molecule shape and size. This project aims to explore the effect of shape and size of pi-conjugated molecules on interfacial electron transfer reactions, which are fundamentally important in all applications of photo-electrochemical conversion and storage of energy. By making two series of pi-conjugated molecules and determining electron transfer rates using a combination of transient spectroscopies and computational chemistry, the project expe ....Faster interfacial electron transfer: the effect of molecule shape and size. This project aims to explore the effect of shape and size of pi-conjugated molecules on interfacial electron transfer reactions, which are fundamentally important in all applications of photo-electrochemical conversion and storage of energy. By making two series of pi-conjugated molecules and determining electron transfer rates using a combination of transient spectroscopies and computational chemistry, the project expects to generate new design principles for molecules with the potential to significantly improve the efficiencies of solar energy conversion and photo-catalytic processes. The new materials and findings will be exploited in a novel redox-mediated water splitting device as a practical outcome with potential end user benefits.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210100680
Funder
Australian Research Council
Funding Amount
$423,275.00
Summary
Solar electrolysis for manufacture of sustainable energy storage materials. This project aims to develop a novel solar-driven manufacturing process able to produce advanced carbon materials which effectively sequester carbon dioxide (negative emission). The project expects to provide key data and insights into a new method of carbon capture and utilisation through advancement of the fundamental science of carbon electrolysis and carbonate regeneration. A combination of advanced electrochemical a ....Solar electrolysis for manufacture of sustainable energy storage materials. This project aims to develop a novel solar-driven manufacturing process able to produce advanced carbon materials which effectively sequester carbon dioxide (negative emission). The project expects to provide key data and insights into a new method of carbon capture and utilisation through advancement of the fundamental science of carbon electrolysis and carbonate regeneration. A combination of advanced electrochemical and engineering techniques will be utilised to achieve this from lab-scale experimental work through to process modelling. Expected outcomes of this project include a clear understanding of the practical potential of this negative emission technology in contributing to offsetting global carbon dioxide emissions.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