Methane Coupling Using Mixed Conducting Catalytic Ceramic Hollow Fibre Membrane Reactor. The Gas product industry is one of the most important economic sectors in Australia, employing 10000 people with market value of $ 100 billion per year from power generation and LNG export. However, there are increasing concerns over issues of the green house gases emission and petroleum dwindling. This project addresses the technology needs in converting natural gas to more useful chemicals via a more effic ....Methane Coupling Using Mixed Conducting Catalytic Ceramic Hollow Fibre Membrane Reactor. The Gas product industry is one of the most important economic sectors in Australia, employing 10000 people with market value of $ 100 billion per year from power generation and LNG export. However, there are increasing concerns over issues of the green house gases emission and petroleum dwindling. This project addresses the technology needs in converting natural gas to more useful chemicals via a more efficient and cleaner means of methane utilization. The project target is to make the natural gas resources in Australia to delivery high value products with considerable economic benefits and increased employment opportunities. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE150101687
Funder
Australian Research Council
Funding Amount
$340,000.00
Summary
Nanostructure Tailoring of Inorganic Membranes by Rapid Thermal Processing. This project aims to produce inorganic membranes with desired nanostructures using a Rapid Thermal Processing (RTP) technique for gas separation applications. The key concept of the research is that the RTP will be able to achieve thin-film membrane layer with a finer microstructure and pore size control without heat stress-induced cracking. RTP aims to deliver superior membrane performance with less than 10 per cent of ....Nanostructure Tailoring of Inorganic Membranes by Rapid Thermal Processing. This project aims to produce inorganic membranes with desired nanostructures using a Rapid Thermal Processing (RTP) technique for gas separation applications. The key concept of the research is that the RTP will be able to achieve thin-film membrane layer with a finer microstructure and pore size control without heat stress-induced cracking. RTP aims to deliver superior membrane performance with less than 10 per cent of the fabrication time compared to normal slow calcination. The outcomes of this new technology aims to make inorganic membranes a commercial reality and maximize the membrane manufacturing capability and productivity of petrochemcial, chemical and clean coal/energy industries.Read moreRead less
Multifunctional trilayer separator for durable multivalent energy storage. This project aims to develop an important new family of economical, high energy, multivalent batteries based on an abundant element, sulphur. The project plans to design a new battery separator to enable long-term stability in sulphur-based rechargeable batteries. This type of separator is of critical importance in many membrane-involved energy storage technologies. The project plans to use leading-edge durable energy tec ....Multifunctional trilayer separator for durable multivalent energy storage. This project aims to develop an important new family of economical, high energy, multivalent batteries based on an abundant element, sulphur. The project plans to design a new battery separator to enable long-term stability in sulphur-based rechargeable batteries. This type of separator is of critical importance in many membrane-involved energy storage technologies. The project plans to use leading-edge durable energy technologies to strengthen the development of residential energy systems and the involvement of renewable energy sources in modern grid.Read moreRead less
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.
Novel carbon dioxide tolerant ceramic membranes for oxygen separation to improve the viability of clean energy technology. Conventional cryogenic air separation is a major economic impediment to the deployment of these low emission technologies like Callide oxyfuel combustion. This project will lead to the discovery of a new class of oxygen selective membranes for air separation with significantly reduced cost to improve the viability of these clean energy technologies.
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
A Novel Light-Weight Membrane Reactor for Converting Natural Gas to Syngas. Most of Australia’s natural gas reserves are located in the remote north-west shelf, many of which are small-scale and thus cannot be economically harnessed using conventional methods such as the pipeline transportation or gas liquefaction. In this project, novel light-weight membrane reactors will be designed for converting natural gas to syngas. By integrating advanced membrane and catalysis technologies, this projects ....A Novel Light-Weight Membrane Reactor for Converting Natural Gas to Syngas. Most of Australia’s natural gas reserves are located in the remote north-west shelf, many of which are small-scale and thus cannot be economically harnessed using conventional methods such as the pipeline transportation or gas liquefaction. In this project, novel light-weight membrane reactors will be designed for converting natural gas to syngas. By integrating advanced membrane and catalysis technologies, this projects aim to minimise reactor weight and operational costs, thus potentially making it possible to harness Australia’s remote and stranded gas reserves.Read moreRead less
Photoelectrochemical control transport across a photoactive inorganic membrane fabricated by an in situ vapour phase hydrothermal method. Serious global fresh water shortage problems force us to recycle/reuse water. In Australia, this is an urgent issue due to our limited fresh water resources. Complete removal of biohazards (e.g., waterborne pathogens) from treated water is one of the most important aspects of safeguarding water recycling and has been the biggest obstacle for public acceptance. ....Photoelectrochemical control transport across a photoactive inorganic membrane fabricated by an in situ vapour phase hydrothermal method. Serious global fresh water shortage problems force us to recycle/reuse water. In Australia, this is an urgent issue due to our limited fresh water resources. Complete removal of biohazards (e.g., waterborne pathogens) from treated water is one of the most important aspects of safeguarding water recycling and has been the biggest obstacle for public acceptance. This project aims to tackle the issue by developing a highly efficient and effective new membrane technology that is capable of not just separating the biohazards from the source water but also in situ destroying them at the same time with low energy consumption and self cleaning features.Read moreRead less
Perovskite Asymmetric Hollow Fibres for Oxygen Separation in Clean Coal Energy Delivery. The coal industry is one of the most important economic sectors in Australia, employing 30000 people, whilst black coal is Australia's largest export worth around $24.5 billion. Energy security of supply is critical to Australia's social stability and economic growth, though Australia's reliance on coal for energy delivery is under strong scrutiny due to carbon mitigation. This project addresses the technolo ....Perovskite Asymmetric Hollow Fibres for Oxygen Separation in Clean Coal Energy Delivery. The coal industry is one of the most important economic sectors in Australia, employing 30000 people, whilst black coal is Australia's largest export worth around $24.5 billion. Energy security of supply is critical to Australia's social stability and economic growth, though Australia's reliance on coal for energy delivery is under strong scrutiny due to carbon mitigation. This project addresses the technology needs in tonnage oxygen separation towards a more efficient and cleaner means of generating energy. The project's benefits target at providing Australian consumers with affordable electricity in a decarbonised economy, enabling clean coal energy delivery to underpin the international competitiveness of the entire Australian economy.Read moreRead less