Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0775612
Funder
Australian Research Council
Funding Amount
$700,000.00
Summary
Nanomaterials Optical Characterisation Facility. Nanotechnology is expected to revolutionize a wide variety of fields, from medicine to agriculture, communications and electronics. However, the small length scales involved present significant challenges with regard to characterising the nanomaterials produced. The Nanomaterials Optical Characterisation facility will provide state-of-the-art equipment for examining the properties of nanomaterials. The equipment will be pivotal in assisting the de ....Nanomaterials Optical Characterisation Facility. Nanotechnology is expected to revolutionize a wide variety of fields, from medicine to agriculture, communications and electronics. However, the small length scales involved present significant challenges with regard to characterising the nanomaterials produced. The Nanomaterials Optical Characterisation facility will provide state-of-the-art equipment for examining the properties of nanomaterials. The equipment will be pivotal in assisting the development of next-generation medicines, implants, optical devices and surface coatings, further strengthening Australia's formidable reputation in these areas.Read moreRead less
Self-assembled surface arrays of mesoscale plasmonic devices for switchable control of coloured surfaces. This project has a well-defined outcome with potentially significant commercial interest. The proposed device is novel and the development of it will enhance the science and technology infrastructure within Australia, taking it into original and exciting directions. A successful demonstration of it will enhance Australia's competitive position in the field of nanotechnology and could conceiv ....Self-assembled surface arrays of mesoscale plasmonic devices for switchable control of coloured surfaces. This project has a well-defined outcome with potentially significant commercial interest. The proposed device is novel and the development of it will enhance the science and technology infrastructure within Australia, taking it into original and exciting directions. A successful demonstration of it will enhance Australia's competitive position in the field of nanotechnology and could conceivably lead to a manufacturing activity either located in Australia or in which Australian entities have an interest. Envisaged applications include optical circuitry, 'smart' windows and display surfaces on consumer devices.Read moreRead less
A Method to Characterise an Aberration-Corrected Electron Wave Field - a step towards quantitative electron microscopy. Australia has recently invested in a powerful, new electron microscope, one of the first in the world, which can image features at the atomic scale that could not be seen before. This project will forge a strategic partnership with the designer and the distributor of this microscope, to develop special new methods that will further increase the microscope's imaging power. This ....A Method to Characterise an Aberration-Corrected Electron Wave Field - a step towards quantitative electron microscopy. Australia has recently invested in a powerful, new electron microscope, one of the first in the world, which can image features at the atomic scale that could not be seen before. This project will forge a strategic partnership with the designer and the distributor of this microscope, to develop special new methods that will further increase the microscope's imaging power. This will give Australian scientists unique capabilities with which to investigate and engineer new materials for advanced technological applications and it will train young Australian scientists in these cutting-edge techniques.Read moreRead less
Preparation of silica-based thin film materials with large optical nonlinearity. There is currently a lack of advanced thin film materials suitable for fabricating integrated electro-optic devices to use in optical telecommunication. Such materials will be produced, and their application will be developed through this project. The physical mechanism of the marvelous optical nonlinearities of the materials will also be investigated. Thus the achievement of this project will bring great advancemen ....Preparation of silica-based thin film materials with large optical nonlinearity. There is currently a lack of advanced thin film materials suitable for fabricating integrated electro-optic devices to use in optical telecommunication. Such materials will be produced, and their application will be developed through this project. The physical mechanism of the marvelous optical nonlinearities of the materials will also be investigated. Thus the achievement of this project will bring great advancement in both scientific knowledge and technologies for Australia, and provide huge opportunities to boost Australian telecommunication industries, which are developing quickly in recent years.Read moreRead less
Evaluating modern printing inks: the behaviour of charged particles in concentrated nonaqueous colloidal dispersions. The Partner Organisation in this proposal, Research Laboratories of Australia (RLA) is a small Adelaide-based company which is at the forefront of modern colour printing technology. RLA provides liquid toners to several major international manufacturers of colour printers for use in liquid immersion development processes. This proposal will develop an instrument for characterisin ....Evaluating modern printing inks: the behaviour of charged particles in concentrated nonaqueous colloidal dispersions. The Partner Organisation in this proposal, Research Laboratories of Australia (RLA) is a small Adelaide-based company which is at the forefront of modern colour printing technology. RLA provides liquid toners to several major international manufacturers of colour printers for use in liquid immersion development processes. This proposal will develop an instrument for characterising the properties of liquid inks, enabling continual R&D improvement of RLA's products. Furthermore, the instrument can be commercialised and marketed worldwide to companies dealing with concentrated colloidal dispersions in a wide range of industries including foods, pharmaceuticals, cosmetics and surface coatings.Read moreRead less
Integrated magneto-optic waveguide materials and devices. We aim to develop chalcogenide glass films for fabricating integrated waveguide magneto-optic (MO) devices as a radical alternative to the use of crystalline MO materials that have proven difficult to manufacture in integrated form. Using our ultra-fast pulsed laser deposition (UFPLD) technique we will produce a wide range of chalcogenide glass compositions through combinatorial materials synthesis and assess them for magneto-optic activ ....Integrated magneto-optic waveguide materials and devices. We aim to develop chalcogenide glass films for fabricating integrated waveguide magneto-optic (MO) devices as a radical alternative to the use of crystalline MO materials that have proven difficult to manufacture in integrated form. Using our ultra-fast pulsed laser deposition (UFPLD) technique we will produce a wide range of chalcogenide glass compositions through combinatorial materials synthesis and assess them for magneto-optic activity. UFPLD will also be used to deposit high optical quality films for device prototyping. We will design and fabricate prototype MO components which are essential, but currently unavailable, for use as optical isolators in integrated optics.Read moreRead less
Intermolecular interactions revisited-Flaws in the fabric and applications to lower-dimensional structures. This project aims to capitalise on recent developments, that have shown that previously accepted theories are deeply flawed, in various applications in fundamental physics and in unsolved problems in biology that involve electromagnetic fields. Interactions driven
by electromagnetic fluctuation forces, and real photon exchange, between molecules will be investigated. The project will inv ....Intermolecular interactions revisited-Flaws in the fabric and applications to lower-dimensional structures. This project aims to capitalise on recent developments, that have shown that previously accepted theories are deeply flawed, in various applications in fundamental physics and in unsolved problems in biology that involve electromagnetic fields. Interactions driven
by electromagnetic fluctuation forces, and real photon exchange, between molecules will be investigated. The project will investigate how dispersion interactions change in mesoscopic pores, in electrolytes, and at finite temperatures. Applications involve
catalysis, molecular formation, and quantum logic. The project also aims to develop a unified theory for energy and charge transfer, relevant for photosynthesis and the way biological molecules transfer information.Read moreRead less
The first critical tests of many-body and correlated Quantum Electro-Dynamics (QED) in medium-Z atomic systems. Major difficulties are being encountered in the computation of high-order and correlated terms of Quantum Electro-Dynamical effects in atoms. We will make the first measurements for medium-Z atoms critically sensitive to two-electron QED, and the first tests of QED in this region accurate to 1%. This accuracy will allow new insight into two-electron systems, theoretical approaches, and ....The first critical tests of many-body and correlated Quantum Electro-Dynamics (QED) in medium-Z atomic systems. Major difficulties are being encountered in the computation of high-order and correlated terms of Quantum Electro-Dynamical effects in atoms. We will make the first measurements for medium-Z atoms critically sensitive to two-electron QED, and the first tests of QED in this region accurate to 1%. This accuracy will allow new insight into two-electron systems, theoretical approaches, and recent observed discrepancies between QED theory and experiment. This proposal follows recent successful experimental work using new capabilities of Electron-Beam Ion Traps (EBITs). Our recent publications have proven that this novel approach can yield new insight into the interaction of light with matter.Read moreRead less
Advanced Siloxane Waveguide Devices for Telecommunications. This project will develop new methods for fabricating compact, high performance photonic integrated circuits (PICs) for use in future telecommunications networks in films of proprietary Inorganic Polymer Glasses (IPGs) commercialised by RPO Pty Ltd. New fabrication methods are required to overcome limitations of the current approach to patterning IPGs used by RPO Pty Ltd. Research will concentrate on hard contact lithography in conjunct ....Advanced Siloxane Waveguide Devices for Telecommunications. This project will develop new methods for fabricating compact, high performance photonic integrated circuits (PICs) for use in future telecommunications networks in films of proprietary Inorganic Polymer Glasses (IPGs) commercialised by RPO Pty Ltd. New fabrication methods are required to overcome limitations of the current approach to patterning IPGs used by RPO Pty Ltd. Research will concentrate on hard contact lithography in conjunction with dry (plasma) etching as well as ion beam milling; laser machining or UV writing for grating production. IPGs present special challenges for these technologies. The project outcomes will include new approaches to processing and the demonstration of the fabrication of innovative PICs in IPGs.Read moreRead less
Photonic routing with liquid crystals. Liquid crystals became a household item but their unequaled nonlocal optical properties are much less known and studied, although the breathtaking prospects of their future applications in photonics inspire many experts around the world. We will bring to Australia the state of the art research approach, theoretical and experimental, aiming to uncover and realize the potential of long range interaction between laser light and nonlocal liquid crystals for fut ....Photonic routing with liquid crystals. Liquid crystals became a household item but their unequaled nonlocal optical properties are much less known and studied, although the breathtaking prospects of their future applications in photonics inspire many experts around the world. We will bring to Australia the state of the art research approach, theoretical and experimental, aiming to uncover and realize the potential of long range interaction between laser light and nonlocal liquid crystals for futuristic all-optical devices. This project will promote and enhance the rapid development of photonics in Australia, as well as deliver foremost practical expertise and outstanding training of young researchers.Read moreRead less