Designing high performance gas separation by interfacial diffusion membrane. This project aims to develop a new generation of interfacial diffusion membranes for industrial gas separations including carbon dioxide removal, nitrogen gas enrichment, methane purification and air separation. The project focuses on advancing separation technologies for the petrochemical, natural gas, and clean energy industries in the mining sector. The project is expected to reveal new separation properties and perf ....Designing high performance gas separation by interfacial diffusion membrane. This project aims to develop a new generation of interfacial diffusion membranes for industrial gas separations including carbon dioxide removal, nitrogen gas enrichment, methane purification and air separation. The project focuses on advancing separation technologies for the petrochemical, natural gas, and clean energy industries in the mining sector. The project is expected to reveal new separation properties and performance based on highly selective interfacial diffusion membranes. The project will also create new scientific knowledge about the role of functional surfaces and nanostructures that will not only facilitate new membrane designs but also offer new, more cost-effective devices for solar conversion, energy storage and harvesting, biomedical applications, sensing and information technology.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100109
Funder
Australian Research Council
Funding Amount
$370,000.00
Summary
A facility for non-destructive quantification of coal structures, composition and percolation fluid flows in energy and environmental applications. The facility will advance our scientific understanding of 3D micro- and nanostructures of coal under various mechanical and chemical conditions. It will help develop process innovation and breakthrough technologies for energy and environmental applications. It will also enhance the research capabilities of the collaborating institutions.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100095
Funder
Australian Research Council
Funding Amount
$620,000.00
Summary
High-resolution X-ray micro computed tomography supporting West Australian geo-, physical and biological science. An X-ray micro computed tomography facility will provide West Australian researchers with much needed access to cutting-edge instrumentation for high-resolution three-dimensional imaging. This facility will support major research programs in key disciplines, including minerals and mining, energy, medical and biological sciences.
Novel conversion process for carbon dioxide to chemicals. This project aims to develop a novel sorption enhanced material and system to convert atmospheric carbon dioxide (CO2) to methanol. Climate change is one of the primary long-term problems confronting humankind today. Since the production of CO2 through burning fossil fuel is far greater than the current usage of CO2, there is currently little alternative to storage. As a result, there is concerted effort globally to develop alternate use ....Novel conversion process for carbon dioxide to chemicals. This project aims to develop a novel sorption enhanced material and system to convert atmospheric carbon dioxide (CO2) to methanol. Climate change is one of the primary long-term problems confronting humankind today. Since the production of CO2 through burning fossil fuel is far greater than the current usage of CO2, there is currently little alternative to storage. As a result, there is concerted effort globally to develop alternate uses and conversion technologies for CO2. This project will help further this goal.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100141
Funder
Australian Research Council
Funding Amount
$300,000.00
Summary
Testing facilities for clean energy transformation technologies. As the world approaches peak oil production, the use of gasification to convert solid fuels to hydrogen and liquid fuels provides a low carbon footprint approach to the cleaner transformation of energy. This testing facility for clean energy transformation technologies will enhance the competitiveness of Australian science and engineering, contributing to the development of new technologies.
Electrochemical conversion of carbon dioxide to formic acid. This project aims to develop economical and scalable carbon dioxide electrochemical technologies to convert carbon dioxide in blast furnace flue gas to formic acid as a value-added product in steel-making plants. The project expects to develop new electrochemical catalysts, to optimise the structure of electrodes and ultimately improve carbon dioxide conversion efficiency and reaction selectivity towards formic acid. The expected outco ....Electrochemical conversion of carbon dioxide to formic acid. This project aims to develop economical and scalable carbon dioxide electrochemical technologies to convert carbon dioxide in blast furnace flue gas to formic acid as a value-added product in steel-making plants. The project expects to develop new electrochemical catalysts, to optimise the structure of electrodes and ultimately improve carbon dioxide conversion efficiency and reaction selectivity towards formic acid. The expected outcomes of this project will provide an efficient and economically viable electrochemical technology to convert carbon dioxide to a valuable product such as formic acid or syngas, with the potential to significantly reduce the emission of carbon dioxide from steel-making processes and coal-fired power plants.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE190100803
Funder
Australian Research Council
Funding Amount
$418,956.00
Summary
Single-enzyme membrane biofuel cells for wastewater and flue gas treatment. This project aims to mitigate energy and environmental problems by fusing the fields of membrane separation, biocatalysis and electrochemistry. The novel single-enzyme biofuel cells can generate electrical power from processes like wastewater micropollutant degradation and flue gas carbon dioxide conversion. However, the bottleneck is the lifetime of enzymes and the lack of efficient reactor design. This project expects ....Single-enzyme membrane biofuel cells for wastewater and flue gas treatment. This project aims to mitigate energy and environmental problems by fusing the fields of membrane separation, biocatalysis and electrochemistry. The novel single-enzyme biofuel cells can generate electrical power from processes like wastewater micropollutant degradation and flue gas carbon dioxide conversion. However, the bottleneck is the lifetime of enzymes and the lack of efficient reactor design. This project expects to overcome these challenges by developing metal-organic framework-based bioelectrode materials, and integrating them with separation membranes and single-enzyme fuel cells for energy generation. This project is expected to transform the current biocatalytic process for wastewater treatment and gas separation.Read moreRead less
Regulating guest transport in microporous materials by electric field. This project aims to address the fundamentals and applications of regulating micropore accessibility. It has long been known that some highly adsorbing molecular sieves suddenly become inaccessible to gases below certain temperatures. Following a recent breakthrough in elucidating the mechanism of such temperature-regulated guest admission, this project will explore electrical regulation of micropore accessibility in conjunct ....Regulating guest transport in microporous materials by electric field. This project aims to address the fundamentals and applications of regulating micropore accessibility. It has long been known that some highly adsorbing molecular sieves suddenly become inaccessible to gases below certain temperatures. Following a recent breakthrough in elucidating the mechanism of such temperature-regulated guest admission, this project will explore electrical regulation of micropore accessibility in conjunction with developing new mechanisms, materials, and control tools for applications, including tunable molecular sieves, valves and gas encapsulation devices. The outcomes of this project will generate new knowledge in the active manipulation of the admission and release of guest molecules in/out of microporous materials, and establish new expertise and capabilities that can advance gas separation, storage and sensing technologies. It is expected that this project will contribute to the long term benefit in low emission energy supplies and Australia's natural gas industry, improve the separation efficiency of our chemical industry, and boost the development of the hydrogen economy.Read moreRead less
Structural modelling of silicon carbide-derived microporous carbon and its application in carbon dioxide capture from moist gases. The project will deliver a powerful new tool for determining the nanostructure of carbons, and will advance the modelling of fluid equilibrium, accessibility and transport within this structure. The outcomes will be crucial to the development of emerging technologies in nanofluidics, gas and electrochemical energy storage, and gas separation.
Discovery Early Career Researcher Award - Grant ID: DE200100326
Funder
Australian Research Council
Funding Amount
$425,231.00
Summary
Mass transfer enhancement for hydrate based carbon capture and cold storage. This project aims to generate the knowledge and techniques required to increase carbon dioxide (CO2) uptake in hydrate based carbon capture from current levels of 15.4% to up to 90% of its rated capacity. This marked improvement stems from identification of the mechanism of CO2-water mass transfer in CO2 hydrate formation and engineering of structurally modified porous hydrogels as the substrate of CO2 hydrates. Encapsu ....Mass transfer enhancement for hydrate based carbon capture and cold storage. This project aims to generate the knowledge and techniques required to increase carbon dioxide (CO2) uptake in hydrate based carbon capture from current levels of 15.4% to up to 90% of its rated capacity. This marked improvement stems from identification of the mechanism of CO2-water mass transfer in CO2 hydrate formation and engineering of structurally modified porous hydrogels as the substrate of CO2 hydrates. Encapsulation will be developed in a way that CO2 may be transported by CO2 hydrates in a concentrated form. Successful completion of the project will offer technical evaluation of a novel CO2 capture and transport solution with lower operational energy consumption and capital cost than incumbent carbon capture technologies.Read moreRead less