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
Sodium borohydride for solid-state green hydrogen export. This project aims to develop a new method of producing, storing, and exporting green hydrogen using Australian resources. Sodium borohydride will be produced from borax using renewable energy and exported internationally to countries that desire hydrogen from renewable sources to replace fossil fuels. Green hydrogen will be released from sodium borohydride by adding water. The spent material will then be shipped back to Australia for recy ....Sodium borohydride for solid-state green hydrogen export. This project aims to develop a new method of producing, storing, and exporting green hydrogen using Australian resources. Sodium borohydride will be produced from borax using renewable energy and exported internationally to countries that desire hydrogen from renewable sources to replace fossil fuels. Green hydrogen will be released from sodium borohydride by adding water. The spent material will then be shipped back to Australia for recycling back to sodium borohydride, creating a closed-loop energy cycle using renewable energy. This will create a new export industry in Australia by expanding current mining expertise whilst harnessing our wealth of renewable energy to potentially deliver billions of dollars of revenue.Read moreRead less
CO2 Utilisation for Energy Storage. This project aims to develop a novel technology that can convert carbon dioxide into useful products while storing intermittent renewable energy as green stable chemical energy. The project plans to focus on the development of a robust cathode for the conversion of carbon dioxide with optimum physical and chemical structure to achieve long-term stable performance. This technology would make a significant contribution to increasing the proportion of renewable e ....CO2 Utilisation for Energy Storage. This project aims to develop a novel technology that can convert carbon dioxide into useful products while storing intermittent renewable energy as green stable chemical energy. The project plans to focus on the development of a robust cathode for the conversion of carbon dioxide with optimum physical and chemical structure to achieve long-term stable performance. This technology would make a significant contribution to increasing the proportion of renewable energy in our energy supply and reducing our carbon dioxide emissions.Read moreRead less
Interface/Boundary Engineering Towards Better Solid-State Lithium Batteries. This project aims to develop high-performance solid-state lithium batteries by engineering the design of grain boundaries within the oxide electrolyte and interfaces between the electrolyte and both anode and cathode. This project expects to propose a novel cation exsolution strategy for comprehensively engineering the interfaces and boundaries. This project should provide significant benefits on energy safety and susta ....Interface/Boundary Engineering Towards Better Solid-State Lithium Batteries. This project aims to develop high-performance solid-state lithium batteries by engineering the design of grain boundaries within the oxide electrolyte and interfaces between the electrolyte and both anode and cathode. This project expects to propose a novel cation exsolution strategy for comprehensively engineering the interfaces and boundaries. This project should provide significant benefits on energy safety and sustainable development of Australia. The successful completion of this project can lead to the development of battery technologies that may lift Australia to a better position in the international market and may also help boost the prosperity of Australia’s world-leading lithium mining industry.Read moreRead less
New carbon nanotube electrocatalysts for water splitting and fuel cells. The demand for clean, secure and sustainable energy sources has stimulated great interest in electrochemical energy storage and conversion technologies such as water splitting and fuel cells. The efficiency of water splitting and fuel cells is however strongly dependent on the activity of the electrocatalysts. The objective of the project is to develop new electrocatalysts based on the recently discovered phenomena that car ....New carbon nanotube electrocatalysts for water splitting and fuel cells. The demand for clean, secure and sustainable energy sources has stimulated great interest in electrochemical energy storage and conversion technologies such as water splitting and fuel cells. The efficiency of water splitting and fuel cells is however strongly dependent on the activity of the electrocatalysts. The objective of the project is to develop new electrocatalysts based on the recently discovered phenomena that carbon nanotubes with specific size and number of walls are very active and significantly promote the reaction of water splitting and fuel cells. The proposed project is expected to open a new research field in the development of new electrocatalysts and photoelectrocatalysts for advanced energy conversion and storage technologies.Read moreRead less
metal hydride reactors for high temperature thermochemical heat storage. The aim of this project is to develop a laboratory-based prototype for energy storage in concentrating solar power (CSP) systems using metal hydrides as a chemical energy storage medium. The successful development of cost-effective energy storage technologies is expected to dramatically increase the deployability of CSP systems and this, in turn, will greatly enhance our capacity to reduce reliance on fossil fuels. The outc ....metal hydride reactors for high temperature thermochemical heat storage. The aim of this project is to develop a laboratory-based prototype for energy storage in concentrating solar power (CSP) systems using metal hydrides as a chemical energy storage medium. The successful development of cost-effective energy storage technologies is expected to dramatically increase the deployability of CSP systems and this, in turn, will greatly enhance our capacity to reduce reliance on fossil fuels. The outcomes of the project are planned to be used towards the development of a commercially viable solar thermal energy storage system. The project also plans to conduct fundamental research into the development of new high-temperature metal hydrides suitable for energy storage in CSP systems.Read moreRead less
Concentrating solar thermal energy storage using metal hydrides. This project will investigate energy storage for concentrating solar thermal energy systems. These systems can be used to efficiently generate electricity in remote locations, day and night, using solar energy. The solar energy is converted to heat energy and then chemical energy stored in a metal-hydrogen compound.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100099
Funder
Australian Research Council
Funding Amount
$290,000.00
Summary
A complete near-field scanning optical microscope for advanced characterisation of novel and functional materials. This near-field optical scanning microscope will be unique in Australia and will substantially enhance national research capabilities in functional materials, nanotechnology, biotechnology and chemistry. It will create a platform to advance Australian research to new levels in pharmaceuticals, nanomaterials and energy storage materials.