Advanced Proton-Conducting Ceramic FCs for Power Generation from Ammonia . The project aims to design an innovative ammonia fuel cell using a new perovskite substrate decorated with metal nanoparticles, which demonstrates multi-functionalities and tackles most challenges of conventional fuel cells (FCs). The key concept of this project is the designing of the novel architected smart perovskite as both anode and electrolyte of the fuel cell by systematic modelling and experimental development. T ....Advanced Proton-Conducting Ceramic FCs for Power Generation from Ammonia . The project aims to design an innovative ammonia fuel cell using a new perovskite substrate decorated with metal nanoparticles, which demonstrates multi-functionalities and tackles most challenges of conventional fuel cells (FCs). The key concept of this project is the designing of the novel architected smart perovskite as both anode and electrolyte of the fuel cell by systematic modelling and experimental development. The versatile cell components developed in this project will improve the operational stability and efficiency of the fuel cell, thereby providing a promising pathway for ammonia fuel cells to replace hydrogen fuel cells. This study will reinforce the development of the future supply of reliable, low cost and clean energy. Read moreRead less
Hybrid cathode for low temperature solid oxide fuel cells. This project aims to develop molten carbonate-perovskite hybrid cathode materials for low temperature solid oxide fuel cells (LT-SOFCs) possessing both high catalytic activity towards oxygen reduction reaction (ORR) and high tolerance to carbon dioxide poisoning. Carbon dioxide in air can poison nearly all the perovskite cathode materials developed for LT-SOFCs (below 600 degrees C) so far. These materials will not be practically useful ....Hybrid cathode for low temperature solid oxide fuel cells. This project aims to develop molten carbonate-perovskite hybrid cathode materials for low temperature solid oxide fuel cells (LT-SOFCs) possessing both high catalytic activity towards oxygen reduction reaction (ORR) and high tolerance to carbon dioxide poisoning. Carbon dioxide in air can poison nearly all the perovskite cathode materials developed for LT-SOFCs (below 600 degrees C) so far. These materials will not be practically useful until carbon dioxide poisoning can be prevented. This project expects to make these LT-SOFC cathode materials commercially viable, solving a problem for the widespread use of low temperature solid oxide fuel cells.Read moreRead less
Innovative High Temperature Carbon–Air Batteries for High Power Generation. The project intends to develop carbon-air batteries which are expected to have energy density 10 times that of lithium-ion batteries. The battery is designed to use naturally-rich carbon as fuel, highly energy-efficient solid oxide fuel cells as electrochemical reactors, and an integrated mixed conducting ceramic membrane for in situ carbon dioxide separation. The success of this project would provide us with a low-carbo ....Innovative High Temperature Carbon–Air Batteries for High Power Generation. The project intends to develop carbon-air batteries which are expected to have energy density 10 times that of lithium-ion batteries. The battery is designed to use naturally-rich carbon as fuel, highly energy-efficient solid oxide fuel cells as electrochemical reactors, and an integrated mixed conducting ceramic membrane for in situ carbon dioxide separation. The success of this project would provide us with a low-carbon energy system based on Australia’s rich coal resources. New knowledge about carbon dioxide separation may also facilitate carbon dioxide sequestration in other fields.Read moreRead less
All-Metal Nanoporous Materials as Highly Active Electrocatalysts. This project aims to create new avenues for well-controlled large-scale synthesis of hierarchical nanoporous platinum-based architectures, and develop applications for the resultant new electrocatalysts. Developing novel high-performance, low-cost, and long-life electrode catalysts can improve the efficiency, cost, and durability of energy conversion technology. The project plans to use the unique properties of well-defined nanoar ....All-Metal Nanoporous Materials as Highly Active Electrocatalysts. This project aims to create new avenues for well-controlled large-scale synthesis of hierarchical nanoporous platinum-based architectures, and develop applications for the resultant new electrocatalysts. Developing novel high-performance, low-cost, and long-life electrode catalysts can improve the efficiency, cost, and durability of energy conversion technology. The project plans to use the unique properties of well-defined nanoarchitectures to reduce platinum content and to improve electrocatalytic performance. Nanoporous systems in electrocatalysts can provide more active sites and effective surface permeability, which should enhance catalytic activity. Project outcomes may also contribute to our understanding of the relationships among morphologies, pore structures, surface atomic structures and catalytic activities to guide the development of other kinds of high performance nanoporous catalysts.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100026
Funder
Australian Research Council
Funding Amount
$480,000.00
Summary
A surface characterisation facility. This surface characterisation facility will provide scientists with an understanding of material's surfaces and interfaces. This will lead to a range of new technologies and innovative solutions required to address the many resource and environmental challenges facing our planet now and in the future.
Highly efficient electric power and value-added synthesis gas co-generation from methane with zero greenhouse gas emission. This project addresses a novel sealing-free solid oxide fuel cell system producing simultaneously synthesis gas and electricity from methane with zero greenhouse gas emission. The project aims to deliver economic benefits and contribute to environmental protection and increased employment opportunities.
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
Doped metal perovskites for electrocatalysis. This project aims to discover and design perovskite metal-oxide electrocatalyst materials and develop electrocatalytic methods for efficiently driving the oxygen evolution reaction and the oxygen reduction reaction. These are the two most crucial reactions in sustainable energy cycles involving water, hydrogen and oxygen. The project’s anticipated advances in electrocatalysis efficiency for these two reactions will benefit sustainable energy technolo ....Doped metal perovskites for electrocatalysis. This project aims to discover and design perovskite metal-oxide electrocatalyst materials and develop electrocatalytic methods for efficiently driving the oxygen evolution reaction and the oxygen reduction reaction. These are the two most crucial reactions in sustainable energy cycles involving water, hydrogen and oxygen. The project’s anticipated advances in electrocatalysis efficiency for these two reactions will benefit sustainable energy technologies such as fuel cells, metal air batteries and water splitting.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
Optimising experimental design for robust product development: a case study for high-efficiency energy generation. This project tackles key mathematical challenges to provide a powerful new methodology and tool for optimal product design, making smarter use of limited information, minimising costly trials, shortening the product cycle, and boosting the competitiveness of both the Australian manufacturing and alternative energy production industries.