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Functional biomass carbons for low-cost sodium and potassium-ion batteries. The development of hard carbon anode materials for stationary rechargeable sodium and potassium ion batteries remains a major technological challenge. This project aims to utilise two very different biomass feedstock sources, sorghum and macadamia shell agricultural waste to manufacture low-cost, high-performance carbon anodes. Current carbon anode materials such as graphite or carbonised sucrose, pitch or phenolics suff ....Functional biomass carbons for low-cost sodium and potassium-ion batteries. The development of hard carbon anode materials for stationary rechargeable sodium and potassium ion batteries remains a major technological challenge. This project aims to utilise two very different biomass feedstock sources, sorghum and macadamia shell agricultural waste to manufacture low-cost, high-performance carbon anodes. Current carbon anode materials such as graphite or carbonised sucrose, pitch or phenolics suffer from poor performance, high cost and/or low carbon yield and device durability issues. This project will investigate combinations of biomass precursors, tailored graphene and carbon alloys in order to significantly enhance anode performance while minimising cost.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200100477
Funder
Australian Research Council
Funding Amount
$420,770.00
Summary
Developing sustainable liquid fuels from carbon dioxide conversion. This project aims to develop new electrochemical materials and systems capable of converting carbon dioxide to liquid fuels. It expects to generate new knowledge in the area of advanced materials and systems for sustainable fuel production by interdisciplinary integration of catalyst design, real-time characterisation and system engineering. Expected outcomes include electrochemical carbon dioxide-to-alcohol systems with commerc ....Developing sustainable liquid fuels from carbon dioxide conversion. This project aims to develop new electrochemical materials and systems capable of converting carbon dioxide to liquid fuels. It expects to generate new knowledge in the area of advanced materials and systems for sustainable fuel production by interdisciplinary integration of catalyst design, real-time characterisation and system engineering. Expected outcomes include electrochemical carbon dioxide-to-alcohol systems with commercially relevant performances and in-depth understanding of reaction mechanisms at nano and molecular levels. Significant economic, energy and environmental benefits are expected from the concerted greenhouse gas emissions reduction and the development of sustainable, clean, non-fossil fuels, enabled by this project.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
Advanced Molecular Frameworks for Sodium Battery Electrode Applications. This project aims to develop new molecular materials capable of high capacity sodium-ion insertion. Through an innovative interdisciplinary approach that targets the synthesis and detailed characterisation of an extensive family of materials this project expects to generate major advances in the understanding of how the chemical, physical and structural attributes of the materials relate to their electrical charge/discharge ....Advanced Molecular Frameworks for Sodium Battery Electrode Applications. This project aims to develop new molecular materials capable of high capacity sodium-ion insertion. Through an innovative interdisciplinary approach that targets the synthesis and detailed characterisation of an extensive family of materials this project expects to generate major advances in the understanding of how the chemical, physical and structural attributes of the materials relate to their electrical charge/discharge behaviours. Significant anticipated outcomes and benefits include the development of new material design approaches that optimise battery electrode performance across a diverse parameter space, and the generation of advanced new materials worthy of commercial development in low-cost, large-scale battery applications.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE220100350
Funder
Australian Research Council
Funding Amount
$450,000.00
Summary
Sodium inventory for sodium-ion batteries. This project aims to increase the energy density and cycle life of sodium-ion batteries by investigating practical ways to increase the amount of cycleable sodium ions. This project expects to generate new knowledge in the field of energy storage using an innovative approach to address the key issues facing sodium-ion batteries. Expected outcomes of this project include the development of a novel high-energy sodium-ion battery, achieved by practical sod ....Sodium inventory for sodium-ion batteries. This project aims to increase the energy density and cycle life of sodium-ion batteries by investigating practical ways to increase the amount of cycleable sodium ions. This project expects to generate new knowledge in the field of energy storage using an innovative approach to address the key issues facing sodium-ion batteries. Expected outcomes of this project include the development of a novel high-energy sodium-ion battery, achieved by practical sodium inventory solutions and fundamental understanding of internal battery processes. This should provide significant benefits including lowering the cost of energy storage, decreasing the reliance on lithium, and facilitating society’s shift towards renewable and sustainable energy sources.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
Industrial Transformation Training Centres - Grant ID: IC180100049
Funder
Australian Research Council
Funding Amount
$4,380,454.00
Summary
ARC Training Centre for Future Energy Storage Technologies. The ARC Training Centre for Future Energy Storage Technologies aims to equip the next generation of researchers and the energy technology workforce with the skills needed to drive innovation, exploration and investigation so we safeguard our workers and industries. The Centre aims to challenge existing thinking and expand Australia’s capacity in energy storage and production. The Centre expects to create new knowledge and intellectual p ....ARC Training Centre for Future Energy Storage Technologies. The ARC Training Centre for Future Energy Storage Technologies aims to equip the next generation of researchers and the energy technology workforce with the skills needed to drive innovation, exploration and investigation so we safeguard our workers and industries. The Centre aims to challenge existing thinking and expand Australia’s capacity in energy storage and production. The Centre expects to create new knowledge and intellectual property in advanced energy materials, batteries and battery-control systems for integration into end user industries. This Centre will facilitate small to medium-sized enterprises to take a global leadership role in advancing and producing new age storage technologies. By harnessing the expertise of researchers and industry partners the Centre aims to deliver benefit to our economy, the community and the environment.
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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
Medium voltage DC: Enabling active, flexible and efficient power networks. Medium voltage DC (MVDC) systems promise to offer the required flexibility in next generation active electricity networks to enable higher renewable energy integration, take advantage of more readily available energy storage, and manifest simpler control and operation. The intended outcome of the Project is to address the challenge of developing MVDC networks via an integrated and cohesive approach, from the initial desig ....Medium voltage DC: Enabling active, flexible and efficient power networks. Medium voltage DC (MVDC) systems promise to offer the required flexibility in next generation active electricity networks to enable higher renewable energy integration, take advantage of more readily available energy storage, and manifest simpler control and operation. The intended outcome of the Project is to address the challenge of developing MVDC networks via an integrated and cohesive approach, from the initial design of the individual power electronics converters, right up to network design and "system of systems" implementation. The outcomes of the Project will provide clear pathways and solutions for new topologies, facilitating Australia’s and the world’s transition to next generation electricity infrastructure.Read moreRead less