Advanced electrochemical capacitors. This project aims to design electrochemical capacitors that can provide self-sustaining power for equipment using renewable energy sources, such as sunlight. Electrical power systems are needed to supply both the peak power and the energy demand that users, particularly those without grid electricity, and their equipment need. This project will match the capacitator electrochemistry to the power attributes of the load and charging source, making them more eff ....Advanced electrochemical capacitors. This project aims to design electrochemical capacitors that can provide self-sustaining power for equipment using renewable energy sources, such as sunlight. Electrical power systems are needed to supply both the peak power and the energy demand that users, particularly those without grid electricity, and their equipment need. This project will match the capacitator electrochemistry to the power attributes of the load and charging source, making them more efficiently charged and able to supply both peak power and energy demand for improved off-grid power supplies and integration of renewable energy into electricity grids.Read moreRead less
Degradation conscious grid-scale battery energy management scheme. The project aims to develop an improved battery management system to smooth the intermittent contribution of renewable energy sources to the grid. As the level of penetration of renewable energy sources into electrical grids increases, energy storage will play an increasingly important role in solving some of the technical challenges caused by the intermittent nature of the renewable sources. The existing design methods for gri ....Degradation conscious grid-scale battery energy management scheme. The project aims to develop an improved battery management system to smooth the intermittent contribution of renewable energy sources to the grid. As the level of penetration of renewable energy sources into electrical grids increases, energy storage will play an increasingly important role in solving some of the technical challenges caused by the intermittent nature of the renewable sources. The existing design methods for grid-scale battery management systems do not take into consideration the degradation of the battery banks. Thus, this project aims to fill this gap by developing an electrochemical-based, degradation-conscious, battery management system. The proposed system aims to increase the life span and capacity use of the batteries.Read moreRead less
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
Highly-efficient, reversible fuel cell. This project aims to develop a reversible fuel cell - electrolyser capable of storing electricity (in the form of hydrogen gas) with the same overall energy efficiency as the best present storage system, pumped hydro. Whereas pumped hydro requires large infrastructure like dams, the proposed cell will be extremely inexpensive and easily scalable.
Early Career Industry Fellowships - Grant ID: IE230100468
Funder
Australian Research Council
Funding Amount
$450,000.00
Summary
Scalable high-performance electrolytic hydrogen generator. The project aims to demonstrate energy-efficient generation of compressed hydrogen by water electrolysis in a high pressure electrolyser test-rig produced by Melbourne company Energys Australia P/L, using high-performance membrane-electrode assemblies. Innovative electrode architectures, membranes, and method for their high through-put lamination will be developed. New knowledge in catalysis, device fabrication and materials science is e ....Scalable high-performance electrolytic hydrogen generator. The project aims to demonstrate energy-efficient generation of compressed hydrogen by water electrolysis in a high pressure electrolyser test-rig produced by Melbourne company Energys Australia P/L, using high-performance membrane-electrode assemblies. Innovative electrode architectures, membranes, and method for their high through-put lamination will be developed. New knowledge in catalysis, device fabrication and materials science is expected to be generated. The major project outcome is sustainable method for generation of compressed hydrogen at significantly reduced cost as compared to the existing technologies. Benefits include industry-ready processes for electrolyser and hydrogen production that support Australian energy industries.Read moreRead less
Charge transfer kinetics at nanostructured semiconductor surfaces. This project aims to enhance understanding of the interface science associated with charge-transfer reactions at nanostructured semiconductor surfaces. Experimental and modelling approaches will be used to unravel the contributions of surface wetting and nanostructure geometry to the kinetics of charge transfer reactions at the surfaces. Expected outcomes include an enhanced capacity to engineer nanostructured semiconductor surf ....Charge transfer kinetics at nanostructured semiconductor surfaces. This project aims to enhance understanding of the interface science associated with charge-transfer reactions at nanostructured semiconductor surfaces. Experimental and modelling approaches will be used to unravel the contributions of surface wetting and nanostructure geometry to the kinetics of charge transfer reactions at the surfaces. Expected outcomes include an enhanced capacity to engineer nanostructured semiconductor surfaces for designed functionality and an extended collaborative network which can collectively address significant problems in energy science. It is anticipated that these outcomes will be realised in reliable, low-cost metallisation for silicon photovoltaics and increased power densities for electrochemical storage systems.Read moreRead less
Improving solar energy utilisation by splitting water with visible light. The project seeks to improve solar-hydrogen fuel production via water splitting by addressing a fundamental scientific roadblock. By engineered nanostructures with controlled charge transfer abilities, the most desirable route to water splitting will be promoted; granting Australia an opportunity to develop a solar-based renewable fuel.
Novel nanostructured high energy cathode material. Recently, the demand for rechargeable batteries has exploded due to the enormous increase in the variety and number of miniaturized devices. It is expected that this demand for high capacity rechargeable batteries as energy sources will become even greater in the future. This program is focused to develop novel high performance cathode materials for lithium rechargeable batteries. The outcomes of the project will be of great benefit to develop ....Novel nanostructured high energy cathode material. Recently, the demand for rechargeable batteries has exploded due to the enormous increase in the variety and number of miniaturized devices. It is expected that this demand for high capacity rechargeable batteries as energy sources will become even greater in the future. This program is focused to develop novel high performance cathode materials for lithium rechargeable batteries. The outcomes of the project will be of great benefit to develop new class rechargeable batteries that are economical, lightweight, environmentlly benign and high energy.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE160101293
Funder
Australian Research Council
Funding Amount
$350,000.00
Summary
Nanoporous Iron-Based Oxygen Evolution Electrocatalysts for Water Splitting. This project aims to develop high-performance water splitting devices based on nanoporous iron-based oxygen evolution electrocatalysts. The devices, which will produce hydrogen to relieve the energy shortage in Australia, can be powered by photovoltaic and wind-generated electricity or directly use solar energy. The development of new energy materials that can be used to make renewable and clean fuels from abundant and ....Nanoporous Iron-Based Oxygen Evolution Electrocatalysts for Water Splitting. This project aims to develop high-performance water splitting devices based on nanoporous iron-based oxygen evolution electrocatalysts. The devices, which will produce hydrogen to relieve the energy shortage in Australia, can be powered by photovoltaic and wind-generated electricity or directly use solar energy. The development of new energy materials that can be used to make renewable and clean fuels from abundant and easily accessible resources is among the most challenging and demanding tasks today. The combination of iron doping and nanoporous structure are intended to improve both the intrinsic and extrinsic catalytic activities of the electrocatalysts to be developed in the project.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE150101306
Funder
Australian Research Council
Funding Amount
$365,000.00
Summary
Porous Metal Phosphonate Ion Exchange Membranes for Redox Flow Batteries. The high-performance storage and utilisation of renewable energy, such as solar and wind energy, will provide a direct response to Australia's energy and climate issues. This project aims to develop porous metal phosphonate ion exchange membranes, which can be used in the redox flow battery, one of the most powerful, large-scale energy storage devices, with large capacity, high efficiency, long life and low cost. The proje ....Porous Metal Phosphonate Ion Exchange Membranes for Redox Flow Batteries. The high-performance storage and utilisation of renewable energy, such as solar and wind energy, will provide a direct response to Australia's energy and climate issues. This project aims to develop porous metal phosphonate ion exchange membranes, which can be used in the redox flow battery, one of the most powerful, large-scale energy storage devices, with large capacity, high efficiency, long life and low cost. The project aims to improve the overall performance and fabrication of redox flow batteries, promote capacity and efficiency, and reduce the cost of renewable energy storage thereby benefiting the Australian economy and environment.Read moreRead less