Development of novel high efficiency thermoelectric oxides for high temperature power generation. Thermoelectric materials are considered as a key factor in clean energy production, based on the conversion of waste heat emitted by power plants and automobiles to electricity. A series of novel high performance Co-based oxide thermoelectric materials will be developed by this project using nanotechnology and advanced material processing techniques. Significant improvement of the heat-to-electricit ....Development of novel high efficiency thermoelectric oxides for high temperature power generation. Thermoelectric materials are considered as a key factor in clean energy production, based on the conversion of waste heat emitted by power plants and automobiles to electricity. A series of novel high performance Co-based oxide thermoelectric materials will be developed by this project using nanotechnology and advanced material processing techniques. Significant improvement of the heat-to-electricity conversion factor is expected to result from the proposed program. The novel thermoelectric oxides with high thermoelectric performance will be practically used for high temperature power generation. This will provide a long-term solution to the global warming threat through decreasing amounts of waste heat presently generated. Read moreRead less
Nanostructured materials for development of advanced lithium energy storage systems. This project is expected to bring several national benefits. Novel nanostructured electro-active materials and high energy density rechargeable lithium batteries will be developed. The application of advanced lithium batteries as power sources for electric vehicles (EVs) and hybrid electric vehicles (HEVs) will realise nearly zero emission transportation. The widespread usage of EVs and HEVs could significantly ....Nanostructured materials for development of advanced lithium energy storage systems. This project is expected to bring several national benefits. Novel nanostructured electro-active materials and high energy density rechargeable lithium batteries will be developed. The application of advanced lithium batteries as power sources for electric vehicles (EVs) and hybrid electric vehicles (HEVs) will realise nearly zero emission transportation. The widespread usage of EVs and HEVs could significantly reduce air pollution, improve urban environment and increase national energy security and energy independence.Read moreRead less
Combined Particle Image Velocimetry (PIV) and CFD modelling to study particle deposition in conduits. System geometry greatly influences flow hydrodynamics and hence the transport of colloidal particles and ionic species from the bulk to the surfaces that result in formation of unwanted deposit matter on the surface. The formation of unwanted deposits has significant environmental and economic penalties. This project uses a new approach that is combining the CFD modelling and experimentation inc ....Combined Particle Image Velocimetry (PIV) and CFD modelling to study particle deposition in conduits. System geometry greatly influences flow hydrodynamics and hence the transport of colloidal particles and ionic species from the bulk to the surfaces that result in formation of unwanted deposit matter on the surface. The formation of unwanted deposits has significant environmental and economic penalties. This project uses a new approach that is combining the CFD modelling and experimentation including flow visualization by PIV to systematically investigate the effect of channel geometry and flow on deposit formation. The outcomes of the project will result in a better understanding and formulating of the effect of geometry on deposition of colloidal particles and ionic species on the surfaces. The results contribute not only towards the mitigation processes for unwanted deposition; it also advances the knowledge in coating applications.Read moreRead less
In pursuit of high performance lithium-oxygen batteries. This project aims to achieve high-energy lithium-oxygen batteries for electric vehicles. Electrification of road transport will minimise consumption of fossil fuels, reduce carbon dioxide emissions, and increase energy security. Lithium-oxygen batteries have the highest energy density among all rechargeable battery systems, which is more than 10 times the density of current lithium-ion batteries. Through exploration of new catalysts, redox ....In pursuit of high performance lithium-oxygen batteries. This project aims to achieve high-energy lithium-oxygen batteries for electric vehicles. Electrification of road transport will minimise consumption of fossil fuels, reduce carbon dioxide emissions, and increase energy security. Lithium-oxygen batteries have the highest energy density among all rechargeable battery systems, which is more than 10 times the density of current lithium-ion batteries. Through exploration of new catalysts, redox mediators, and porous material architectures, this project intends to significantly improve the performance of lithium-oxygen batteries, including specific capacity, cycle life and round-trip efficiency.Read moreRead less
Integration of large capacity Superconducting Magnetic Energy Storage with Active Power Filter switching technology to achieve a complete power quality device. The aim of this project is to integrate large capacity SMES with Active Power Filter (APF) switching technology to achieve a complete power quality control device.
The expected outcomes of the research are 1) An SMES design suitable for APF integration, 2) Development and implementation of lossless energy switching technologies, 3) D ....Integration of large capacity Superconducting Magnetic Energy Storage with Active Power Filter switching technology to achieve a complete power quality device. The aim of this project is to integrate large capacity SMES with Active Power Filter (APF) switching technology to achieve a complete power quality control device.
The expected outcomes of the research are 1) An SMES design suitable for APF integration, 2) Development and implementation of lossless energy switching technologies, 3) Development of suitable APF switching algorithms, 4) An integrated design with competitive commercial analysis, and 5) A fully characterised prototype.
This project is innovative as the marriage of large capacity SMES with APF switching technology is essentially absent from the literature, and so there are high expectations for innovative applications and methodologies of fabrication.
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Designing integrated photocatalytic systems for simultaneous clean energy generation and water remediation. The proposal addresses the core issues of energy and water, two highly critical resources in Australia as well as worldwide. Utilising our geographically-abundant solar energy and through designing novel photocatalytic systems, the proposed research provides an ultimately clean solution by efficiently harnessing and converting the solar energy to hydrogen while remediating wastewater. Give ....Designing integrated photocatalytic systems for simultaneous clean energy generation and water remediation. The proposal addresses the core issues of energy and water, two highly critical resources in Australia as well as worldwide. Utilising our geographically-abundant solar energy and through designing novel photocatalytic systems, the proposed research provides an ultimately clean solution by efficiently harnessing and converting the solar energy to hydrogen while remediating wastewater. Given the high intensity and consistent solar output in Australia, such technology provides an almost ideal and sustainable outcome in terms of clean energy and water supply. Success in this area will place Australian researchers at the forefront of practical and functional photocatalytic technologiesRead moreRead less
Exploration of Advanced Nanostructures for Sodium-ion Battery Application. The aim of this project is to develop advanced nanostructured electrode materials for high energy, long service life sodium-ion batteries. Sodium-ion batteries are the most promising choice for large-scale electrical energy storage, in particular for renewable energy sources and smart electric grids, owing to their low cost and natural abundance of sodium. The success of this project will advance fundamental understanding ....Exploration of Advanced Nanostructures for Sodium-ion Battery Application. The aim of this project is to develop advanced nanostructured electrode materials for high energy, long service life sodium-ion batteries. Sodium-ion batteries are the most promising choice for large-scale electrical energy storage, in particular for renewable energy sources and smart electric grids, owing to their low cost and natural abundance of sodium. The success of this project will advance fundamental understanding of sodium-ion batteries, and provide techniques for the development of a promising low-cost system for renewable energy storage, which is urgently needed in smart electricity grids. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180100036
Funder
Australian Research Council
Funding Amount
$359,446.00
Summary
Rechargeable room-temperature sodium-oxygen batteries. This project aims to develop high performance room-temperature sodium-oxygen batteries as a green and low-cost power source for large scale electrical energy storage. Through electrode architecture design, this research intends to significantly improve the performance of sodium-oxygen batteries, including specific capacity, cycle life and round-trip energy efficiency. Expected outcomes include reducing consumption of fossil fuels to generate ....Rechargeable room-temperature sodium-oxygen batteries. This project aims to develop high performance room-temperature sodium-oxygen batteries as a green and low-cost power source for large scale electrical energy storage. Through electrode architecture design, this research intends to significantly improve the performance of sodium-oxygen batteries, including specific capacity, cycle life and round-trip energy efficiency. Expected outcomes include reducing consumption of fossil fuels to generate electricity, with benefits for the environment, climate change and energy security.Read moreRead less
A green technology for liquefied natural gas (LNG) regasification. Upon arrival to its destination, the liquefied natural gas (LNG) exported from Australia must be converted back into gas to make it suitable for distribution to end users, for which the current technologies burn up to two per cent our LNG exports. This project will design a technology that will use the energy of ambient air, which will not only increase the profit but also reduce carbon dioxide emissions.
Sodium-ion batteries for renewable energy storage. This project aims to develop sodium-ion batteries for renewable energy storage and conversion. Electrical energy storage is important for integrating renewable energy sources, improving grid reliability, and intelligently managing peak demand. Sodium-ion batteries are promising for large scale energy storage applications because of low cost and natural abundance of sodium. This project will integrate materials architecture design, synthesise cat ....Sodium-ion batteries for renewable energy storage. This project aims to develop sodium-ion batteries for renewable energy storage and conversion. Electrical energy storage is important for integrating renewable energy sources, improving grid reliability, and intelligently managing peak demand. Sodium-ion batteries are promising for large scale energy storage applications because of low cost and natural abundance of sodium. This project will integrate materials architecture design, synthesise cathode materials, model and test electrochemistry, and make prototype batteries. This project is expected to help the Government meet its renewable energy target, improve utilities’ power quality and reliability, create industry opportunities, and maintain Australia’s high standing in energy research.Read moreRead less