Discovery Early Career Researcher Award - Grant ID: DE230100789
Funder
Australian Research Council
Funding Amount
$397,613.00
Summary
Photo-thermal ammonia decomposition . This project aims to develop of novel catalysts targeted to utilise light and heat for the photo-thermal decomposition of ammonia to produce hydrogen and generate new understanding on the role of light in thermal catalytic reactions. The emergence of the hydrogen economy has resulted in the urgent need for safe and efficient hydrogen transport and storage vectors. Ammonia, a hydrogen carrier, is being increasingly considered as a potential key to facilitate ....Photo-thermal ammonia decomposition . This project aims to develop of novel catalysts targeted to utilise light and heat for the photo-thermal decomposition of ammonia to produce hydrogen and generate new understanding on the role of light in thermal catalytic reactions. The emergence of the hydrogen economy has resulted in the urgent need for safe and efficient hydrogen transport and storage vectors. Ammonia, a hydrogen carrier, is being increasingly considered as a potential key to facilitate the hydrogen economy due to its relative ease of storage. The development of catalysts tailored toward capturing light for ammonia decomposition will enable a new potential pathway for the hydrogen economy, with ammonia as a hydrogen vector. Read moreRead less
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
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
Discovery Early Career Researcher Award - Grant ID: DE230101396
Funder
Australian Research Council
Funding Amount
$360,218.00
Summary
Designing Single-atom catalysts for Renewable Waste Conversion to Urea. This DECRA aims to realise the direct electrochemical conversion of waste resources using renewable energy to generate urea at ambient conditions. By designing impurity-tolerant single atom catalysts and unearthing their structure-activity relationships, the utilisation of flue gas and wastewater will be materialised. This will advance our understanding in the field as current energy conversion reactions require pure feedsto ....Designing Single-atom catalysts for Renewable Waste Conversion to Urea. This DECRA aims to realise the direct electrochemical conversion of waste resources using renewable energy to generate urea at ambient conditions. By designing impurity-tolerant single atom catalysts and unearthing their structure-activity relationships, the utilisation of flue gas and wastewater will be materialised. This will advance our understanding in the field as current energy conversion reactions require pure feedstocks. Expected outcomes from the program is envisioned to lead to deployment of scalable decentralised modes of green urea production (substituting imports), and the knowledge transferrable to other areas of Australia’s emerging hydrogen economy, extending the scope of renewable Power-to-X to realise a circular economy.Read moreRead less