Discovery Early Career Researcher Award - Grant ID: DE240100722
Funder
Australian Research Council
Funding Amount
$362,245.00
Summary
Enabling Novel Hydrogen Storage via Combustible Ice for a Low-Carbon Future. This project aims to develop a new method for sustainable hydrogen storage. Hydrogen is vital for decarbonising Australia's economy, yet finding an efficient way for hydrogen storage is a global challenge. This project seeks to encapsulate hydrogen effectively in water to produce hydrogen-carrying combustible ice for efficient large-scale hydrogen storage, taking the advantages of water as the safest and cheapest raw ma ....Enabling Novel Hydrogen Storage via Combustible Ice for a Low-Carbon Future. This project aims to develop a new method for sustainable hydrogen storage. Hydrogen is vital for decarbonising Australia's economy, yet finding an efficient way for hydrogen storage is a global challenge. This project seeks to encapsulate hydrogen effectively in water to produce hydrogen-carrying combustible ice for efficient large-scale hydrogen storage, taking the advantages of water as the safest and cheapest raw material. Expected outcomes are cutting-edge knowledge and a new pathway of hydrogen storage. This project would contribute to turning Australia’s abundant renewable energy resources into substantial economic and environmental benefits and promote Australia's competitive edge in the global transition toward a low-carbon future.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230100147
Funder
Australian Research Council
Funding Amount
$437,154.00
Summary
Glassy metal-organic framework membranes for CO2 separation and conversion. This project aims to develop a new class of glassy metal-organic framework (MOF) membranes for CO2 separation and conversion. By constructing membrane reactors, it is expected to simultaneously separate CO2 from gas mixture and subsequently convert it into value-added chemicals in a continuous single operating unit. The expected outcomes include fabrication techniques for ultrathin MOF glass membranes, cutting-edge knowl ....Glassy metal-organic framework membranes for CO2 separation and conversion. This project aims to develop a new class of glassy metal-organic framework (MOF) membranes for CO2 separation and conversion. By constructing membrane reactors, it is expected to simultaneously separate CO2 from gas mixture and subsequently convert it into value-added chemicals in a continuous single operating unit. The expected outcomes include fabrication techniques for ultrathin MOF glass membranes, cutting-edge knowledge in advanced MOF membrane design, a new generation of MOF devices, and efficient membrane reactors for CO2 conversion with mixed gas feed. This project expects to accelerate the development of low-carbon technologies and provide significant benefits in mitigating the adverse effects of anthropogenic CO2 emissions.Read moreRead less
Novel Membranes for High-performance Zinc-Iron Redox Flow Batteries. Membrane is a critical component in zinc-iron redox flow battery (ZIRFB) which is considered a promising technology for large-scale energy storage in the future. This project aims to design and construct high performance membranes using low-cost polymers and nanostructured carbon materials through functionalization and innovative membrane structure design. The goal is to develop cost-effective membranes that possess high ion-se ....Novel Membranes for High-performance Zinc-Iron Redox Flow Batteries. Membrane is a critical component in zinc-iron redox flow battery (ZIRFB) which is considered a promising technology for large-scale energy storage in the future. This project aims to design and construct high performance membranes using low-cost polymers and nanostructured carbon materials through functionalization and innovative membrane structure design. The goal is to develop cost-effective membranes that possess high ion-selectivity and ion conductivity as well as stability that are required to fabricate high performance, long cycle lifetime ZIRFB. Successful achievement of the outcomes will enable cost-effective, reliable ZIRFB, placing Australia at the forefront of exploiting flow batteries based clean energy storage technologies. Read moreRead less
Understanding dynamic interfaces in electrochemical systems. This project aims to develop nanoscale characterisation methods to understand dynamic processes in zinc-ion batteries and high temperature electrolysis systems under real working (in operando) conditions. This project expects to reveal critical solid-liquid and solid-gas interfacial processes in these two distinctly different electrochemical systems. The expected outcomes include improved understanding of electrochemical interfaces and ....Understanding dynamic interfaces in electrochemical systems. This project aims to develop nanoscale characterisation methods to understand dynamic processes in zinc-ion batteries and high temperature electrolysis systems under real working (in operando) conditions. This project expects to reveal critical solid-liquid and solid-gas interfacial processes in these two distinctly different electrochemical systems. The expected outcomes include improved understanding of electrochemical interfaces and improved tools and methods to observe nanoscale interfacial processes. This information can be used to underpin mechanistic models, which will facilitate new materials design. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100623
Funder
Australian Research Council
Funding Amount
$412,037.00
Summary
New electrodes for green electrochemical carbon dioxide capture. This project aims to develop new electrochemical carbon capture technology. By designing and fabricating new functional electrodes and high-performance electrochemical devices based on water and driven by renewable electricity, this project will enhance the ability to capture CO2, the primary greenhouse gas that causes global climate change. Expected outcomes include new multi-dimension electrodes with unique chemistry and state-of ....New electrodes for green electrochemical carbon dioxide capture. This project aims to develop new electrochemical carbon capture technology. By designing and fabricating new functional electrodes and high-performance electrochemical devices based on water and driven by renewable electricity, this project will enhance the ability to capture CO2, the primary greenhouse gas that causes global climate change. Expected outcomes include new multi-dimension electrodes with unique chemistry and state-of-the-art CO2 capture devices plus in-depth knowledge of electrochemical CO2 capture mechanisms for optimised device design and control. Benefits include the development of circular carbon economies with capabilities to effectively capture CO2, supporting Australian industries to achieve net zero emissions by 2050.Read moreRead less
2D Multiferroics: From Materials Design to Device Conceptualization. This project aims to design new transistors with high efficiency and low energy costing for the storage applications based on two-dimensional multifunctional heterostructures. Extensive computational simulations and joint experiments will be employed to develop fundamental knowledge essential to understanding the phenomena of magnetoelectric coupling, which is used to guide rational device design and implementation. The designe ....2D Multiferroics: From Materials Design to Device Conceptualization. This project aims to design new transistors with high efficiency and low energy costing for the storage applications based on two-dimensional multifunctional heterostructures. Extensive computational simulations and joint experiments will be employed to develop fundamental knowledge essential to understanding the phenomena of magnetoelectric coupling, which is used to guide rational device design and implementation. The designed magnetoelectric heterostructures and the multiferroic devices are expected to provide strong foundations for technological innovations resulting in devices with superior functionality and efficiency. The outcome of the project will significantly benefit high-tech electronics.Read moreRead less
Novel framework for optimising battery-cooling microchannel heat exchangers. Thermal overheating can affect the capacity, safety and life expectancy of batteries for renewable energy storage and electric vehicles. Microscale heat exchangers are a potential high-efficiency, low-bulk solution. This project aims to develop a novel computational methodology to optimise the design of those heat exchangers in which viscoelastic fluids are used to control flow instabilities and enhance heat transfer at ....Novel framework for optimising battery-cooling microchannel heat exchangers. Thermal overheating can affect the capacity, safety and life expectancy of batteries for renewable energy storage and electric vehicles. Microscale heat exchangers are a potential high-efficiency, low-bulk solution. This project aims to develop a novel computational methodology to optimise the design of those heat exchangers in which viscoelastic fluids are used to control flow instabilities and enhance heat transfer at the microscale. A new microscopic fluid physics model will provide data for an innovative neural network framework to optimise the working fluid conditions and microscale design, which could contribute to increased adoption of renewable energy technologies that are supported by microscale heat exchangers.Read moreRead less
“Janus” Transition Metal Dichalcogenides: Quest for Novel Properties . Novel two-dimensional nanomaterials – so called “Janus” transition metal dichalcogenides (TMDs) - are featured by breaking out-of-plane structural symmetry that enables prolongated exciton lifetime, strong spin-orbit coupling, large vertical piezoelectric polarization, and exceptional electromechanical properties. We plan to develop reliable and efficient synthetic routes for various "Janus" TMDs and their heterostructures, ....“Janus” Transition Metal Dichalcogenides: Quest for Novel Properties . Novel two-dimensional nanomaterials – so called “Janus” transition metal dichalcogenides (TMDs) - are featured by breaking out-of-plane structural symmetry that enables prolongated exciton lifetime, strong spin-orbit coupling, large vertical piezoelectric polarization, and exceptional electromechanical properties. We plan to develop reliable and efficient synthetic routes for various "Janus" TMDs and their heterostructures, to investigate their physical properties, and find the ways of property tailoring. Deep understanding of structure-property relationships uncovered for these materials will pave the way for transferring discovered new features into cutting-edge technologies in electromechanical, optoelectronic, and catalytic fields.Read moreRead less
Advanced Gas Diffusion Electrodes For Electrochemical Manufacturing. This project aims to develop electrochemical conversion technologies to convert carbon dioxide into globally needed chemicals. It targets the bottleneck issues in managing the gas-liquid-solid reaction sites and improving the conversion efficiency of reactor, through the synthesis of advanced electrode materials, understanding of mass transfer and the engineering design of an electrochemical reactor. The expected outcomes will ....Advanced Gas Diffusion Electrodes For Electrochemical Manufacturing. This project aims to develop electrochemical conversion technologies to convert carbon dioxide into globally needed chemicals. It targets the bottleneck issues in managing the gas-liquid-solid reaction sites and improving the conversion efficiency of reactor, through the synthesis of advanced electrode materials, understanding of mass transfer and the engineering design of an electrochemical reactor. The expected outcomes will promote carbon neutral goals, bridge the renewable energy storage and sustainable chemical manufacturing gap, thus addressing key challenges faced by Australia and the world.Read moreRead less