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
Discovery Early Career Researcher Award - Grant ID: DE200100794
Funder
Australian Research Council
Funding Amount
$419,000.00
Summary
Prediction of new electrolytes for improved electrical energy storage. This project aims to identify new electrolyte solutions with suitable properties for use in improved electrical energy storage technologies. Identifying new electrolyte solutions is a crucial challenge for improving the performance of many technologies including energy storage. This project applies quantum mechanical calculation to develop a fast, accurate and predictive model of the properties of electrolyte solutions. High ....Prediction of new electrolytes for improved electrical energy storage. This project aims to identify new electrolyte solutions with suitable properties for use in improved electrical energy storage technologies. Identifying new electrolyte solutions is a crucial challenge for improving the performance of many technologies including energy storage. This project applies quantum mechanical calculation to develop a fast, accurate and predictive model of the properties of electrolyte solutions. High throughput computational screening based on this model can then identify new electrolytes that can be used in technologies such as energy storage. This should give Australia a competitive edge in the rapidly growing energy storage industry, while also accelerating the shift away from harmful fossil fuels. Read moreRead less