Gas-enriched slippery surfaces. This project will exploit novel experimental and simulations approaches to investigate gas enrichment at liquid-liquid interfaces, and its effect on interfacial slip. The outcomes of the project will be a deeper understanding of oil-water interfaces capturing the presence of interfacial gas layers, slippery surfaces with superior drag reducing and fouling reducing properties, and control over nanobubble formation under flow. The new surfaces will have potential ap ....Gas-enriched slippery surfaces. This project will exploit novel experimental and simulations approaches to investigate gas enrichment at liquid-liquid interfaces, and its effect on interfacial slip. The outcomes of the project will be a deeper understanding of oil-water interfaces capturing the presence of interfacial gas layers, slippery surfaces with superior drag reducing and fouling reducing properties, and control over nanobubble formation under flow. The new surfaces will have potential application in improving the energy efficiency of microfluidic and multiphase flow. Benefits are expected in terms of reduced emissions, fuel cost and pollution related to transport of goods by sea, and extraction of oil from rocks.Read moreRead less
Interface/Boundary Engineering Towards Better Solid-State Lithium Batteries. This project aims to develop high-performance solid-state lithium batteries by engineering the design of grain boundaries within the oxide electrolyte and interfaces between the electrolyte and both anode and cathode. This project expects to propose a novel cation exsolution strategy for comprehensively engineering the interfaces and boundaries. This project should provide significant benefits on energy safety and susta ....Interface/Boundary Engineering Towards Better Solid-State Lithium Batteries. This project aims to develop high-performance solid-state lithium batteries by engineering the design of grain boundaries within the oxide electrolyte and interfaces between the electrolyte and both anode and cathode. This project expects to propose a novel cation exsolution strategy for comprehensively engineering the interfaces and boundaries. This project should provide significant benefits on energy safety and sustainable development of Australia. The successful completion of this project can lead to the development of battery technologies that may lift Australia to a better position in the international market and may also help boost the prosperity of Australia’s world-leading lithium mining industry.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240101045
Funder
Australian Research Council
Funding Amount
$448,407.00
Summary
Bioinspired 2D nanocatalysts for inorganic nitrogen cycle. This project aims to develop novel catalysts for high-efficient nitrogen fixation by learning from the natural enzymes, which can convert nitrogen or nitrate into reactive ammonia at very mild conditions. It is expected that the enzyme-mimicking catalysts possessing the nitrogen active sites similar with the natural enzymes will allow the effective fixation of nitrogen from both the atmosphere and the nitrogen excessively fertilized envi ....Bioinspired 2D nanocatalysts for inorganic nitrogen cycle. This project aims to develop novel catalysts for high-efficient nitrogen fixation by learning from the natural enzymes, which can convert nitrogen or nitrate into reactive ammonia at very mild conditions. It is expected that the enzyme-mimicking catalysts possessing the nitrogen active sites similar with the natural enzymes will allow the effective fixation of nitrogen from both the atmosphere and the nitrogen excessively fertilized environment into reusable ammonia. The outcomes of this project will provide a sustainable approach to solve the issues in current unbalanced inorganic nitrogen cycle in the world and contribute to a green artificial nitrogen cycle while with minimized environmental impact.Read moreRead less
Biomimetic surface coatings for drag and fouling reduction. This project aims to provide new insights into liquid flow and adsorption at liquid/solid and liquid/liquid interfaces, by using a combination of theoretical predictions, nanoscale techniques and nanofabrication approaches. Expected outcomes are the development of liquid-repellent slippery surface coatings that reduce hydrodynamic drag and inhibit marine fouling. This will benefit the fields of advanced manufacturing and smart coatings, ....Biomimetic surface coatings for drag and fouling reduction. This project aims to provide new insights into liquid flow and adsorption at liquid/solid and liquid/liquid interfaces, by using a combination of theoretical predictions, nanoscale techniques and nanofabrication approaches. Expected outcomes are the development of liquid-repellent slippery surface coatings that reduce hydrodynamic drag and inhibit marine fouling. This will benefit the fields of advanced manufacturing and smart coatings, and will underpin a wide range of energy efficient processes and products. Slippery coatings will solve urgent environmental problems of social value by improving the energy and chemical efficiency in fluid flow, heat transfer, secondary oil recovery, microfluidics, and anti-fouling.Read moreRead less
Engineering two dimensional polymers for membrane-based chemical separation. This project aims to develop novel two-dimensional polymers with precisely controlled pore-sizes for preparing membrane materials which can efficiently separate these gaseous chemicals at ambient temperatures. Key industrial chemical mixtures with similar size and boiling points are difficult to separate by conventional distillation methods. Currently, purification of olefins alone accounts for 0.3% of global energy use ....Engineering two dimensional polymers for membrane-based chemical separation. This project aims to develop novel two-dimensional polymers with precisely controlled pore-sizes for preparing membrane materials which can efficiently separate these gaseous chemicals at ambient temperatures. Key industrial chemical mixtures with similar size and boiling points are difficult to separate by conventional distillation methods. Currently, purification of olefins alone accounts for 0.3% of global energy use. The expected outcomes of the project will have a huge impact on industrial purification processing by providing a disruptive membrane technology, and will significantly reduce energy consumption and open up new routes for resources.Read moreRead less
Tailoring metal-organic framework catalysts for carbon dioxide conversion. Reducing the greenhouse gas, CO2, into valuable fuels would be beneficial for relieving energy shortage and improving global sustainability. This project aims to synthesise high-performance heterogeneous catalysts for CO2 conversion by periodic ordering photo-redox metalloligand and thermal-catalytically active metal oxide clusters in metal-organic frameworks (MOFs). This approach is expected to deliver a unique single-si ....Tailoring metal-organic framework catalysts for carbon dioxide conversion. Reducing the greenhouse gas, CO2, into valuable fuels would be beneficial for relieving energy shortage and improving global sustainability. This project aims to synthesise high-performance heterogeneous catalysts for CO2 conversion by periodic ordering photo-redox metalloligand and thermal-catalytically active metal oxide clusters in metal-organic frameworks (MOFs). This approach is expected to deliver a unique single-site metal-organic framework catalyst with high reaction-activity and chemo-selectivity in converting CO2 into valuable chemicals. This advancement will provide significant benefits for Australia’s emerging chemical manufacturing industry, and ultimately leading to a carbon-neutral energy economy and environment.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE190101514
Funder
Australian Research Council
Funding Amount
$352,473.00
Summary
Nanodroplet platforms for engineering novel nanocarbon structures. This project aims to exploit surface nanodroplet array platforms to construct multi-scale level assembly of nanometer-scale carbon materials. The project expects to advance knowledge on the interactions between droplets and carbon nanomaterials to enable controlled construction of nanocarbon based optoelectric devices. Successful adoption of nanocarbon material-based optoelectronic devices by the energy conversion industry has th ....Nanodroplet platforms for engineering novel nanocarbon structures. This project aims to exploit surface nanodroplet array platforms to construct multi-scale level assembly of nanometer-scale carbon materials. The project expects to advance knowledge on the interactions between droplets and carbon nanomaterials to enable controlled construction of nanocarbon based optoelectric devices. Successful adoption of nanocarbon material-based optoelectronic devices by the energy conversion industry has the potential to increase efficiency of conversion and reduce the cost of manufacture. The expected outcomes are large scale and well-ordered nanocarbon structures with excellent electronic and optical properties.Read moreRead less
Boosting Carbon Dioxide Reduction via Surface and Interface Engineering . This project will develop innovative catalysts for the reduction of CO2 into carbon fuels via cost effective computational design. The approach aims at engineering catalytic surface and interface to modulate the coordination environment around catalytic active copper atom. The expected outcomes will be high performance catalyst materials that can significantly boost the conversion of CO2 into valuable fuels. The new knowle ....Boosting Carbon Dioxide Reduction via Surface and Interface Engineering . This project will develop innovative catalysts for the reduction of CO2 into carbon fuels via cost effective computational design. The approach aims at engineering catalytic surface and interface to modulate the coordination environment around catalytic active copper atom. The expected outcomes will be high performance catalyst materials that can significantly boost the conversion of CO2 into valuable fuels. The new knowledge achieved in this project will dramatically advance the development of sustainable carbon cycle, providing solutions to the global energy supply and environmental issues. The smarter energy and environmental technologies will potentially result in the enhancements to the quality of the everyday lives of Australian.Read moreRead less