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Next generation material imaging, spectrometry and fabrication techniques. This project aims to solve a common, fundamental problem limiting the performance of mass spectrometers and high resolution electron microscopes: surface modification caused by unintended chemical reactions due to electron impact. The intended project outcomes will advance current understanding of electron restructuring of surfaces and open the door to next-generation material imaging, spectrometry and fabrication techniq ....Next generation material imaging, spectrometry and fabrication techniques. This project aims to solve a common, fundamental problem limiting the performance of mass spectrometers and high resolution electron microscopes: surface modification caused by unintended chemical reactions due to electron impact. The intended project outcomes will advance current understanding of electron restructuring of surfaces and open the door to next-generation material imaging, spectrometry and fabrication techniques. It will develop a superior detector for mass spectrometry and improve the imaging and nanofabrication capabilities of state-of-the-art electron microscopes. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210101102
Funder
Australian Research Council
Funding Amount
$404,748.00
Summary
Single-Atom Catalysts on Atomically Thin Nanomaterials for H2O2 Production. Single-atomic sites supported on graphene analogs is an ideal structural mode for the design of electrocatalysts due to its ultimate small size limit, atomic thickness, and easily tuned electronic properties. This project aims to use a theory-guided approach to develop efficient electrocatalysts for the production of value-added hydrogen peroxide. The structural advantages of graphene analogs will be fully utilised to un ....Single-Atom Catalysts on Atomically Thin Nanomaterials for H2O2 Production. Single-atomic sites supported on graphene analogs is an ideal structural mode for the design of electrocatalysts due to its ultimate small size limit, atomic thickness, and easily tuned electronic properties. This project aims to use a theory-guided approach to develop efficient electrocatalysts for the production of value-added hydrogen peroxide. The structural advantages of graphene analogs will be fully utilised to unlock the catalytic power of single-atomic sites, and consequently achieve high catalytic activity and selectivity. The outcome will set a solid scientific foundation to enable economically viable technologies for eco-friendly hydrogen peroxide production and bring significant socioeconomic benefits to Australia.Read moreRead less
Atomically Thin 3d Transition Metal Electrocatalysts for Water Splitting. The current industrial-scale hydrogen productions are reliant on high temperature steam reforming fossil fuels, consuming large quantity of energy and fossil resources, and emitting huge amounts of CO2. This project aims to develop cheap and plentiful transition metal-based high performance water splitting electrocatalysts, enabling economically viable large-scale water electrolytic hydrogen production driven by renewable ....Atomically Thin 3d Transition Metal Electrocatalysts for Water Splitting. The current industrial-scale hydrogen productions are reliant on high temperature steam reforming fossil fuels, consuming large quantity of energy and fossil resources, and emitting huge amounts of CO2. This project aims to develop cheap and plentiful transition metal-based high performance water splitting electrocatalysts, enabling economically viable large-scale water electrolytic hydrogen production driven by renewable electricity. A theory-guided catalyst approach will be used to guide the efficient design and development of high performance electrocatalysts. The success of the project will lead to a suit of high performance water splitting electrocatalysts, leaping forward water electrolytic hydrogen production technology.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200100345
Funder
Australian Research Council
Funding Amount
$384,616.00
Summary
Harnessing nanotechnology to unravel extracellular vesicle heterogeneity. This project aims to develop a suite of innovative nanotechnologies to study extracellular vesicles with unprecedented depth of analysis and single particle resolution. This project expects to generate new knowledge in the emerging field of extracellular vesicle (EV) biology, as well as cell biology, using advanced nanofabrication and nanoscopic fluid flows to advance understanding of EV heterogeneity and how phenotypic va ....Harnessing nanotechnology to unravel extracellular vesicle heterogeneity. This project aims to develop a suite of innovative nanotechnologies to study extracellular vesicles with unprecedented depth of analysis and single particle resolution. This project expects to generate new knowledge in the emerging field of extracellular vesicle (EV) biology, as well as cell biology, using advanced nanofabrication and nanoscopic fluid flows to advance understanding of EV heterogeneity and how phenotypic variations affect their role in cellular processes. Expected outcomes include a universal technology platform to study extracellular vesicles and other bioparticles, with potential to deliver valuable intellectual property of commercial interest and economic benefit through technological advancements.Read moreRead less
Unravelling mechanisms in plasma growth of polymers. Surface engineering broadens the breadth of applications for many materials, and enhances the performance and value of current and emerging technologies. Surface engineering is particularly important to maintaining the competitiveness of manufacturing in developed economies such as Australia, that can not compete on a cost basis with emerging economies. Plasma coating replaces (alternative) environmentally-questionable surface treatments. This ....Unravelling mechanisms in plasma growth of polymers. Surface engineering broadens the breadth of applications for many materials, and enhances the performance and value of current and emerging technologies. Surface engineering is particularly important to maintaining the competitiveness of manufacturing in developed economies such as Australia, that can not compete on a cost basis with emerging economies. Plasma coating replaces (alternative) environmentally-questionable surface treatments. This project enhances Australian competitiveness; it cuts across industrial sectors and will deliver the new knowledge required to enhance material/technology functionality/performance. A PhD student will receive a multi-disciplinary training in a frontier technology and advanced analytical tools.Read moreRead less
Exploiting the self-assembly of hydrophobin proteins to engineer functional nanostructuring surfaces. There is an increasing world-wide demand for advanced nano-biomaterials with novel properties. We will use natural hydrophobin proteins to coat nanodevices and make them more compatible with biological systems. Hydrophobin coatings will be applicable to biosensors, medical devices, diagnostics and drug delivery systems. The research will lead to an understanding of the basic mechanisms of protei ....Exploiting the self-assembly of hydrophobin proteins to engineer functional nanostructuring surfaces. There is an increasing world-wide demand for advanced nano-biomaterials with novel properties. We will use natural hydrophobin proteins to coat nanodevices and make them more compatible with biological systems. Hydrophobin coatings will be applicable to biosensors, medical devices, diagnostics and drug delivery systems. The research will lead to an understanding of the basic mechanisms of protein self-assembly and will have application outcomes that contribute to Australia being an important player in the field of nanotechnology. This is critical for Australia's long term competitiveness and productivity in and beyond the 21st century.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100121
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
Three-dimensional super-resolution nanophotonic fabrication facility. This stimulated emission depletion microscopy nanophotonic fabrication facility will be the first nanophotonic fabrication facility that is able to achieve optical resolution far beyond the diffraction limit, which will facilitate breakthroughs in cutting-edge nanotechnology research areas.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE160100199
Funder
Australian Research Council
Funding Amount
$367,900.00
Summary
Advanced Synthesis System for Two-Dimensional Nanomaterials. Advanced synthesis system for two-dimensional nanomaterials:
This project aims to establish the first synthesis facility in Australia for growing large-area and atomically thin two-dimensional (2-D) nanomaterials including graphene, boron nitride, metal dichalcogenides, metal oxide and nitride nanosheets. Such materials are emerging and innovative materials that possess many properties desirable for energy, electronic, biological, and ....Advanced Synthesis System for Two-Dimensional Nanomaterials. Advanced synthesis system for two-dimensional nanomaterials:
This project aims to establish the first synthesis facility in Australia for growing large-area and atomically thin two-dimensional (2-D) nanomaterials including graphene, boron nitride, metal dichalcogenides, metal oxide and nitride nanosheets. Such materials are emerging and innovative materials that possess many properties desirable for energy, electronic, biological, and environmental related applications. This facility is designed to underpin breakthrough science by providing high-quality large-sized materials to researchers for both fundamental and application research. This new synthesis capability would foster advances in the fundamental understanding of 2-D nanostructures and the development of devices with broad applications in energy conversion and storage, environmental protection, and life sciences.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230101105
Funder
Australian Research Council
Funding Amount
$422,318.00
Summary
Developing Polymer Electrolytes for Operational All-Solid-State Batteries. This project aims to advance the development of safe rechargeable all-solid-state batteries (ASSBs) by innovating fluorinated block copolymers as solid-state electrolytes. ASSBs are the most promising power source for emerging energy storage goals, however, low ionic conductivity and poor long-term cycling stability are critical bottlenecks to their successful application. This project seeks to tackle these challenges by ....Developing Polymer Electrolytes for Operational All-Solid-State Batteries. This project aims to advance the development of safe rechargeable all-solid-state batteries (ASSBs) by innovating fluorinated block copolymers as solid-state electrolytes. ASSBs are the most promising power source for emerging energy storage goals, however, low ionic conductivity and poor long-term cycling stability are critical bottlenecks to their successful application. This project seeks to tackle these challenges by fabricating unique ionic conduction channels and stabilising electrode-electrolyte interfaces using fluorinated block copolymer electrolytes. The expected outcomes are new knowledge in polymer electrolytes and advancement in the commercialisation of ASSBs toward more efficient, safe and reliable energy storage technologies.Read moreRead less
The Nanotechnology Desalination Research Project - Low Energy Desalination Membranes. Population growth and global warming is rapidly increasing the strain placed on fresh water supplies. Environmentally sustainable solutions to this water shortage need to be found urgently. This project will develop new, low energy desalination technologies which can be powered by renewable energy sources, to enable desalination to be widely applied with low environmental impacts. It addresses several national ....The Nanotechnology Desalination Research Project - Low Energy Desalination Membranes. Population growth and global warming is rapidly increasing the strain placed on fresh water supplies. Environmentally sustainable solutions to this water shortage need to be found urgently. This project will develop new, low energy desalination technologies which can be powered by renewable energy sources, to enable desalination to be widely applied with low environmental impacts. It addresses several national priorities: Water - a critical resource; Transforming existing industries; Overcoming soil loss, salinity and acidity; Responding to climate change and variability; Frontier technologies and Advanced materials.Read moreRead less