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Australian Laureate Fellowships - Grant ID: FL160100089
Funder
Australian Research Council
Funding Amount
$2,600,796.00
Summary
In situ electron microscopy toward new materials and applications. In situ electron microscopy toward new materials and applications. This project aims to develop materials for structural and green energy applications, using spatially-resolved, dynamic in situ transmission electron microscopy to research fundamental mechanical, electrical, thermal, optical, optoelectronic and photovoltaic properties of diverse nanostructures. These techniques measure nanomaterial (one-dimensional nanotubes and n ....In situ electron microscopy toward new materials and applications. In situ electron microscopy toward new materials and applications. This project aims to develop materials for structural and green energy applications, using spatially-resolved, dynamic in situ transmission electron microscopy to research fundamental mechanical, electrical, thermal, optical, optoelectronic and photovoltaic properties of diverse nanostructures. These techniques measure nanomaterial (one-dimensional nanotubes and nanowires and two-dimensional graphene-like nanosheets) response to external stimuli, including mechanical, electrical, optical and thermal stimuli. Anticipated outcomes are new ultralight and superstrong structural composites and ‘green-energy’ nanomaterials, such as solar cells, touch panels, batteries, supercapacitors, field-effect transistors, light sensors and displays.Read moreRead less
Polymer nanodiscs. This project aims to produce disc-shaped polymer nanomaterials by utilising a new self-assembly concept based on oppositely charged polymers. This project expects to generate a modular technology that allows synthesis and control over the geometry and functionality of polymer nanoparticles. This level of control will permit a precise investigation of polymer nanodisc properties for nanomedicine applications. Expected outcomes of this project will be the fundamental understandi ....Polymer nanodiscs. This project aims to produce disc-shaped polymer nanomaterials by utilising a new self-assembly concept based on oppositely charged polymers. This project expects to generate a modular technology that allows synthesis and control over the geometry and functionality of polymer nanoparticles. This level of control will permit a precise investigation of polymer nanodisc properties for nanomedicine applications. Expected outcomes of this project will be the fundamental understanding of how nanoparticle geometry affects particle-cell interaction and how nanoscale polymer discs can be used to mimic biological nanoparticles in shape and function.Read moreRead less
Enabling Next-generation Rechargeable Aluminium-ion Batteries. This project aims to develop a new generation of high performance and low-cost cathode materials for rechargeable aluminium ion batteries. To address the low capacity issue of current cathodes, this project anticipates to generate new knowledge in the material design of novel graphene materials. By developing an innovative surface perforation technique coupled in a continuous production process, this project expects to produce scalab ....Enabling Next-generation Rechargeable Aluminium-ion Batteries. This project aims to develop a new generation of high performance and low-cost cathode materials for rechargeable aluminium ion batteries. To address the low capacity issue of current cathodes, this project anticipates to generate new knowledge in the material design of novel graphene materials. By developing an innovative surface perforation technique coupled in a continuous production process, this project expects to produce scalable and cost-effective graphene cathodes with a record-high capacity. Expected outcomes of this project include industrial adaptable manufacturing processing and advanced materials for aluminium ion batteries, thus increasing the competitiveness of the partner organisation in the rapid growing graphene market.
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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
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
Discovery Early Career Researcher Award - Grant ID: DE240100839
Funder
Australian Research Council
Funding Amount
$442,162.00
Summary
Nanoarchitectured platform technology for molecular profiling of exosomes. The aim of this project is to develop a set of cutting-edge nanotechnologies and a nanofabrication strategy to create a highly sensitive platform technology for exosome and exosomal miRNA analysis. This project aims to generate new knowledge in mesoporus nanomaterials and transudcer as well as exosome chemistry by developing nanostructure-based platform technology (device) for automated and rapid analysis. This project's ....Nanoarchitectured platform technology for molecular profiling of exosomes. The aim of this project is to develop a set of cutting-edge nanotechnologies and a nanofabrication strategy to create a highly sensitive platform technology for exosome and exosomal miRNA analysis. This project aims to generate new knowledge in mesoporus nanomaterials and transudcer as well as exosome chemistry by developing nanostructure-based platform technology (device) for automated and rapid analysis. This project's findings are expected to provide Australia with cutting-edge expertise for developing a next-generation platform technology for analysing exosomes and other relevant biomolecules, with the potential to deliver valuable intellectual property of commercial interest and economic benefit through technological advancements.Read moreRead less
Ultrathin Gold Nanocrystal Conductors for Wearable Epidermal Biofuel Cells. This project aims to fabricate ultrathin, soft yet stretchable gold nanocrystal conductors to push the thickness limit of next-generation soft bioelectrodes for fabrication of wearable epidermal biofuel cells. This will generate new knowledge and patentable technologies related to design/fabrication of soft nanocrystal conductors, bioanode and biocathode, which require to be thin, soft, conductive and biocompatible. Expe ....Ultrathin Gold Nanocrystal Conductors for Wearable Epidermal Biofuel Cells. This project aims to fabricate ultrathin, soft yet stretchable gold nanocrystal conductors to push the thickness limit of next-generation soft bioelectrodes for fabrication of wearable epidermal biofuel cells. This will generate new knowledge and patentable technologies related to design/fabrication of soft nanocrystal conductors, bioanode and biocathode, which require to be thin, soft, conductive and biocompatible. Expected outcomes of this project include enhanced national capacity in disruptive wearable bioelectronics, strengthening international collaborations, unskilled workforce training, as well as advancement of Australian knowledge base in the fields of nanotechnology, materials science, energy, biosensors and bioelectronics.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
Nanoarchitectured anti-corrosion coatings for zinc-plated steel. Zinc-plated steel is widely used in buildings, households and vehicles, but the long-term performance is limited due to corrosion resulting from exposure to high humidity or alkaline conditions. Currently, available chromium coatings are toxic, while polymeric coatings lack durability. This project aims to use nanotechnology to develop highly effective, multifunctional anti-corrosive coatings in which long-term protection is achiev ....Nanoarchitectured anti-corrosion coatings for zinc-plated steel. Zinc-plated steel is widely used in buildings, households and vehicles, but the long-term performance is limited due to corrosion resulting from exposure to high humidity or alkaline conditions. Currently, available chromium coatings are toxic, while polymeric coatings lack durability. This project aims to use nanotechnology to develop highly effective, multifunctional anti-corrosive coatings in which long-term protection is achieved by controlling the wettability and self-healing properties. The project is excepted to generate new knowledge in coating materials that limit corrosion and address environmental problems. This advanced manufacturing technology should be of high-value benefit to manufacturers and consumers of zinc-plated steel.Read moreRead less