Hydrogen fuel cells with non-precious metal cathode catalysts. Low-cost and robust fuel cell technology is a cornerstone towards the success of the hydrogen economy. The project aims to address the cost and durability of hydrogen fuel cells by advancing low-cost electrocatalysts for oxygen reduction reactions. Novel non-precious catalysts will be developed, and their stability understood in fuel cells using a new approach with in situ current mapping and X-ray computed tomography. The expected ....Hydrogen fuel cells with non-precious metal cathode catalysts. Low-cost and robust fuel cell technology is a cornerstone towards the success of the hydrogen economy. The project aims to address the cost and durability of hydrogen fuel cells by advancing low-cost electrocatalysts for oxygen reduction reactions. Novel non-precious catalysts will be developed, and their stability understood in fuel cells using a new approach with in situ current mapping and X-ray computed tomography. The expected outcomes of this project include material development, improved characterisation techniques and new knowledge on electrocatalysis. The project will benefit Kohodo Hydrogen Energy by positioning them as an Australian leader in low-cost catalysts, and to Australian industries in developing the hydrogen economy. Read moreRead less
Low-temperature ceramic electrolysis cells for renewable energy technology. This project aims to develop advanced protonic ceramic electrolysis cells for greatly improving the efficiency of hydrogen production and carbon dioxide conversion using renewable energy. This will be achieved by nanoscale integration of proton-conducting two-dimensional materials with solid acids and ceramic proton conductors to lower the manufacturing costs and operating temperature of protonic ceramic electrolysis cel ....Low-temperature ceramic electrolysis cells for renewable energy technology. This project aims to develop advanced protonic ceramic electrolysis cells for greatly improving the efficiency of hydrogen production and carbon dioxide conversion using renewable energy. This will be achieved by nanoscale integration of proton-conducting two-dimensional materials with solid acids and ceramic proton conductors to lower the manufacturing costs and operating temperature of protonic ceramic electrolysis cells. Expected outcomes of the project include new intellectual property on materials formulation and process parameters for commercial development of this new type of ceramic electrolysis cell, thereby contributing to the growth of Australian manufacturing and renewable energy industries and reduction of carbon emissions.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
Tailoring smart film for energy efficient protected cropping. Cooling cost represents a major running cost for greenhouse, preventing the wide adoption of highly beneficial protected cropping technology. This project aims at solving this critical issue by developing a world-first tailored smart film that can simultaneously reject solar heat, cool down the greenhouse and maximise the yields of crops. This is made possible by advanced spectral engineering and light management with frontier nanostr ....Tailoring smart film for energy efficient protected cropping. Cooling cost represents a major running cost for greenhouse, preventing the wide adoption of highly beneficial protected cropping technology. This project aims at solving this critical issue by developing a world-first tailored smart film that can simultaneously reject solar heat, cool down the greenhouse and maximise the yields of crops. This is made possible by advanced spectral engineering and light management with frontier nanostructures combined with a scalable and low cost manufacturing process. Deliverables of the project include game-changing energy efficient solutions for protected cropping and marketable smart films readily integratable with existing greenhouse for dramatic energy saving and immediate economic and social benefits.Read moreRead less
Highly Efficient Solar Window Technology Enabled by Quantum Dots. The transition to zero-greenhouse gas emitting buildings is hindered by the lack of efficient energy generating building components with good aesthetics. This project will develop integrated solar windows that can effectively convert the facades of urban buildings into energy generation sites, enabled by our nanomaterials having outstanding light emission efficiencies of over 90%, accompanied by our advanced light guiding strategi ....Highly Efficient Solar Window Technology Enabled by Quantum Dots. The transition to zero-greenhouse gas emitting buildings is hindered by the lack of efficient energy generating building components with good aesthetics. This project will develop integrated solar windows that can effectively convert the facades of urban buildings into energy generation sites, enabled by our nanomaterials having outstanding light emission efficiencies of over 90%, accompanied by our advanced light guiding strategies and innovative PV cell integration. This next generation technology can reduce the electricity cost and increase renewable energy adoption, placing Australia in a competitive position in the billion-dollar building integrated photovoltaic market whilst also contributing to decarbonising electricity generation.Read moreRead less
Advanced glazing systems for solar energy harvesting and radiation control. Development of advanced energy-saving glass and glazings capable of generating electricity is expected to lead towards new products of significant commercial potential. The outcomes of this project undertaken by Edith Cowan University and Tropiglas will raise the energy efficiency of commercial buildings and vehicles to levels not possible with other technologies.