Corrosion of heat resisting alloys in steam/hydrogen-rich environment . Hydrogen is a clean fuel for energy future. Its production and utilisation unavoidably involve water vapour and hydrogen at high temperature which is however corrosive to materials used in the system. This project aims to investigate corrosion behaviour of heat resistant alloys in the presence of both hydrogen and water vapour, mechanisms of water transport in oxide scale, and the effect of hydrogen on water vapour corrosion ....Corrosion of heat resisting alloys in steam/hydrogen-rich environment . Hydrogen is a clean fuel for energy future. Its production and utilisation unavoidably involve water vapour and hydrogen at high temperature which is however corrosive to materials used in the system. This project aims to investigate corrosion behaviour of heat resistant alloys in the presence of both hydrogen and water vapour, mechanisms of water transport in oxide scale, and the effect of hydrogen on water vapour corrosion. Alloying effects on corrosion rates will be defined and methods of slowing or preventing water vapour corrosion in the presence of hydrogen will be devised. The results will provide a basis for improved design/selection of heat resisting alloys for hydrogen production and hydrogen utilisation industries.Read moreRead less
Solid Oxide Electrolysis Cells with Novel Perovskite-based Cathode. The electrochemical reduction of CO2 and steam to value-added fuels in a high-temperature solid oxide electrolysis cell (SOEC) is practically promising, but technologically challenging. This project aims to develop next generation SOECs using a perovskite-based cathode and scale-up engineering for rapid, bulk production of H2, CO and syngas fuels. Expected outcomes include material engineering, new knowledge on energy conversion ....Solid Oxide Electrolysis Cells with Novel Perovskite-based Cathode. The electrochemical reduction of CO2 and steam to value-added fuels in a high-temperature solid oxide electrolysis cell (SOEC) is practically promising, but technologically challenging. This project aims to develop next generation SOECs using a perovskite-based cathode and scale-up engineering for rapid, bulk production of H2, CO and syngas fuels. Expected outcomes include material engineering, new knowledge on energy conversion technology, and advanced manufacturing technologies. The success of the project will provide a practical solution to reduce fossil CO2 emissions and potential technology for hydrogen production. These will significantly aid Australia in important climate goals and ambitions.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180100773
Funder
Australian Research Council
Funding Amount
$354,446.00
Summary
Electric power and useful chemicals co-generation. This project aims to design and develop a fuel cell-reactor that can simultaneously produce electric power and value-added useful chemicals by utilising abundant and cheap gaseous fossil fuels such as natural gas and coal-seam gas. This project expects to realise zero greenhouse gas emissions during the use of fossil fuels to generate electricity, meanwhile opening up a new strategy in the development of highly efficient electro-catalysts for th ....Electric power and useful chemicals co-generation. This project aims to design and develop a fuel cell-reactor that can simultaneously produce electric power and value-added useful chemicals by utilising abundant and cheap gaseous fossil fuels such as natural gas and coal-seam gas. This project expects to realise zero greenhouse gas emissions during the use of fossil fuels to generate electricity, meanwhile opening up a new strategy in the development of highly efficient electro-catalysts for the advanced energy conversion and storage devices. The new technology developed in this project will lead to new breakthroughs in the commercial viability of fuel cell industries.Read moreRead less