Microfibre photonics: function densification on a wavelength scale. The project will contribute to Australia's nanoscale device research and nanomanufacturing development. The project will create microfibre fabrication technologies for the creation of new optical systems of miniature proportions that will be used for cell illumination, for the creation of sensors for detection in small environments and as light tools for fundamental experiments in physics. Specialist fabrication methods will be ....Microfibre photonics: function densification on a wavelength scale. The project will contribute to Australia's nanoscale device research and nanomanufacturing development. The project will create microfibre fabrication technologies for the creation of new optical systems of miniature proportions that will be used for cell illumination, for the creation of sensors for detection in small environments and as light tools for fundamental experiments in physics. Specialist fabrication methods will be developed that will add to the nation's skill base. The outcomes of the project will enhance Australia's knowledge capacity, research capability and will contribute significantly to each of the National Research Priorities.Read moreRead less
Devices that use Ion Channels. The proposed device would supply the community of researchers in Australia and internationally with new techniques to enable them to quickly and conveniently investigate properties of ion channels and to speed the screening of potential ion channel targets for pharmaceutical hits and leads. In addition, the tethered membrane technology will be developed to fill an unmet need for a quick and biologically relevant test of EMC hazards. This will enhance the science an ....Devices that use Ion Channels. The proposed device would supply the community of researchers in Australia and internationally with new techniques to enable them to quickly and conveniently investigate properties of ion channels and to speed the screening of potential ion channel targets for pharmaceutical hits and leads. In addition, the tethered membrane technology will be developed to fill an unmet need for a quick and biologically relevant test of EMC hazards. This will enhance the science and technology infrastructure within Australia, taking it into original and exciting directions, contribute to training young Australian scientists and students, as well as enhance Australia's competitive position in the field of nanobiotechnology.Read moreRead less
Effects of grain size on the deformation mechanisms and mechanical properties of Gum Metals (Ti alloys). The project aims to understand the relationships among grain size, mechanical properties and deformation mechanisms using in-situ deformation transmission electron microscopy techniques. This will provide the fundamental science for designing Gum Metals with superior properties for a range of engineered and biomedical applications.
Microscopy characterisation for the designing of Li-based batteries. This project aims to optimise the design of all-solid-state batteries by employing state-of-the-art microscopy and atomic tomography techniques. Demand for safer rechargeable batteries with higher energy densities has been rapidly increasing. The safety issues associated with current lithium batteries become more serious with the size change (small for portable electronics and large for vehicles) because of the difficulty in ha ....Microscopy characterisation for the designing of Li-based batteries. This project aims to optimise the design of all-solid-state batteries by employing state-of-the-art microscopy and atomic tomography techniques. Demand for safer rechargeable batteries with higher energy densities has been rapidly increasing. The safety issues associated with current lithium batteries become more serious with the size change (small for portable electronics and large for vehicles) because of the difficulty in handling of flammable organic liquid electrolytes. The scientific knowledge and engineering understanding acquired through this project will enable the battery industry to produce higher performance solid state batteries.Read moreRead less
Energy Transfer Across Organic-Inorganic Interfaces. This project seeks to advance our basic understanding of the energy transfer processes which are crucial to the operation of organic optoelectronic devices. Controlling energy transfer is central to the operation of electronic devices. As devices become smaller and more complex, the transfer of energy across interfaces between different materials begins to dominate their operation and characteristics. This project plans to use a range of compl ....Energy Transfer Across Organic-Inorganic Interfaces. This project seeks to advance our basic understanding of the energy transfer processes which are crucial to the operation of organic optoelectronic devices. Controlling energy transfer is central to the operation of electronic devices. As devices become smaller and more complex, the transfer of energy across interfaces between different materials begins to dominate their operation and characteristics. This project plans to use a range of complementary experimental approaches to study energy generation, transfer and diffusion across the nanoscale interface between organic and inorganic materials. Knowledge gained would provide a roadmap for bottom-up improvements to the efficiency of energy transfer across hybrid organic–inorganic interfaces, with a range of applications in optoelectronic devices, including photovoltaics.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180100736
Funder
Australian Research Council
Funding Amount
$362,446.00
Summary
High performing multifunctional silicon nanomaterials for bio-applications. This project aims to develop high-performance, multifunctional silicon nanomaterials, and to understand their physicochemical properties for bio-imaging. A range of high-quality multifunctional silicon-based bio-probes with novel fluorescent and magnetic properties will be developed for enhancing bio-imaging. The outcomes of the project will further strengthen Australia’s leading position in the targeted areas of Advance ....High performing multifunctional silicon nanomaterials for bio-applications. This project aims to develop high-performance, multifunctional silicon nanomaterials, and to understand their physicochemical properties for bio-imaging. A range of high-quality multifunctional silicon-based bio-probes with novel fluorescent and magnetic properties will be developed for enhancing bio-imaging. The outcomes of the project will further strengthen Australia’s leading position in the targeted areas of Advanced Materials and Nanotechnology.Read moreRead less
Nanostructured Carbon Electrodes. The development of higher capacity energy storage devices is critical to the efficient use of energy. The fundamental knowledge gained in this project will enable the production of the next generation advanced electrode materials for this purpose and hence provide many new commercial opportunities for Australian industry. The project brings together world leaders in their own fields to address a highly multidisciplinary area of research and will provide an excel ....Nanostructured Carbon Electrodes. The development of higher capacity energy storage devices is critical to the efficient use of energy. The fundamental knowledge gained in this project will enable the production of the next generation advanced electrode materials for this purpose and hence provide many new commercial opportunities for Australian industry. The project brings together world leaders in their own fields to address a highly multidisciplinary area of research and will provide an excellent training for PhD students and post doctoral Research Fellows, enabling them to work in and contribute to the development of new nanotechnology industries in Australia.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989068
Funder
Australian Research Council
Funding Amount
$637,120.00
Summary
Equipment for Metastable Induced Electron Spectroscopy: surface analysis with excellent surface sensitivity. One of the major research strengths of Australia is surface science as it is important for both fundamental and industry related research. In many cases it is crucial to investigate the outermost layer of a material or mineral. Metastable Induced Electron Spectroscopy is an ideal technique as it is sensitive exclusively to the outermost layer of a broad range of samples. The information g ....Equipment for Metastable Induced Electron Spectroscopy: surface analysis with excellent surface sensitivity. One of the major research strengths of Australia is surface science as it is important for both fundamental and industry related research. In many cases it is crucial to investigate the outermost layer of a material or mineral. Metastable Induced Electron Spectroscopy is an ideal technique as it is sensitive exclusively to the outermost layer of a broad range of samples. The information gained is not accessible by any other method. The proposed equipment will be the first of this type in Australia and will complement existing surface science facilities. The project will enhance Australia's position in surface science internationally and a large number of projects will benefit from access to the equipment.Read moreRead less
Development of planar patch-clamp electrophysiology to investigate liposome-based artificial nanosensor devices. This project aims to characterise the interaction of transport proteins with unsupported lipid bilayer membranes. This will provide the basis for a novel biosensor utilising mechanosensitive ion channels incorporated into an artificial lipid bilayer membrane. To support this outcome, the project will develop the planar patch-clamp electrophysiology recording techniques suitable for l ....Development of planar patch-clamp electrophysiology to investigate liposome-based artificial nanosensor devices. This project aims to characterise the interaction of transport proteins with unsupported lipid bilayer membranes. This will provide the basis for a novel biosensor utilising mechanosensitive ion channels incorporated into an artificial lipid bilayer membrane. To support this outcome, the project will develop the planar patch-clamp electrophysiology recording techniques suitable for liposomes. This provides a significant PhD training opportunity and brings an international focus to the development of planar patch-clamp electrophysiology in Australia. The project has significant commercial potential by developing both the planar patch-clamp electrophysiology techniques for liposomes and producing a novel biomimetic mechanosensitive biosensor.Read moreRead less
Nanotribology and Nanorheometry: A Fundamental Study of the Dynamic Interactions of Particles and Surfaces at the Molecular Level. Friction and deformation occur from the mutual motion and interaction of microscopic particles and surfaces. This research aims to develop new theories and measurement techniques for these non-equilibrium phenomena by combining mathematical analysis and numerical computations with dynamic force measurement, surface modification, and surface characterisation on nanom ....Nanotribology and Nanorheometry: A Fundamental Study of the Dynamic Interactions of Particles and Surfaces at the Molecular Level. Friction and deformation occur from the mutual motion and interaction of microscopic particles and surfaces. This research aims to develop new theories and measurement techniques for these non-equilibrium phenomena by combining mathematical analysis and numerical computations with dynamic force measurement, surface modification, and surface characterisation on nanometre and molecular length scales. These insights and data will be critically important in designing low-friction surfaces that save energy and wear, in developing nanoscopic probes for the mechanical and structural properties of soft polymeric and bio-materials, and in making high performance coatings that control adhesion and particle aggregation in technologically advanced applications.Read moreRead less