Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0346888
Funder
Australian Research Council
Funding Amount
$288,000.00
Summary
3-D Optical Surface Profiler. Establishing a state-of-the-science 3-D optical surface profiler will enable macroscopic, microscopic and nanoscopic profiling of surfaces over a very broad range of research programs including, laser cleaning and surface modification, laser precision microfabrication, surface, materials and device characterisation and optical physics applications. The importance and significance of these projects has already been established by the projects having competitive fundi ....3-D Optical Surface Profiler. Establishing a state-of-the-science 3-D optical surface profiler will enable macroscopic, microscopic and nanoscopic profiling of surfaces over a very broad range of research programs including, laser cleaning and surface modification, laser precision microfabrication, surface, materials and device characterisation and optical physics applications. The importance and significance of these projects has already been established by the projects having competitive funding. The instrument will undoubtedly support many additional research programs. It is similar to an Atomic-Force-Microscope or stylus profilometer but has significant additional capabilites. These include profiling much larger areas at sub-nanometre resolution and the non-contact nature of the technique. These features will enable surface characterisation that can not be achieved by other means.Read moreRead less
Tailoring the optical properties of matter with Sol-Gel: innovative optical materials for 3D photonic crystals with complete photonic band-gap. The success of this project will allow for improvement of existing technologies in diverse fields, from optics to green energy production. Realization of 3D complete Photonic Band-Gap (PBG) structures is the first step toward full optic-based data processing systems, which will be one of the most revolutionary achievements in technology after introductio ....Tailoring the optical properties of matter with Sol-Gel: innovative optical materials for 3D photonic crystals with complete photonic band-gap. The success of this project will allow for improvement of existing technologies in diverse fields, from optics to green energy production. Realization of 3D complete Photonic Band-Gap (PBG) structures is the first step toward full optic-based data processing systems, which will be one of the most revolutionary achievements in technology after introduction of electronic-based processors. Improvement of energy conversion efficiency of existing solar cells and polymer-based solar cells will be achievable thanks to implementation of PhCs as high-reflective layers. The establishment of scaleable protocols for production of high quality materials for photonics will put Australia among the leading countries in the future photonic-devices market.Read moreRead less
NOVEL STUCTURES AND MATERIALS IN MICROSTRUCTURED POLYMER OPTICAL FIBRES. Last year we succeeded in fabricating the microstructured polymer optical fibres (MPOF). This work means that the fabrication constraints applying to similar glass fibres can be overcome, and entirely new types of structures can be investigated. As polymers can contain a much larger variety of dopants than glass the material properties of MPOF can also be fully exploited to develop new fibre functionalities. The combination ....NOVEL STUCTURES AND MATERIALS IN MICROSTRUCTURED POLYMER OPTICAL FIBRES. Last year we succeeded in fabricating the microstructured polymer optical fibres (MPOF). This work means that the fabrication constraints applying to similar glass fibres can be overcome, and entirely new types of structures can be investigated. As polymers can contain a much larger variety of dopants than glass the material properties of MPOF can also be fully exploited to develop new fibre functionalities. The combination of structural and material flexibility possible in MPOF offer the opportunity to radically redefine what is possible in microstructured fibres. It is these possibilities that we aim to explore in this project.Read moreRead less
Tailoring the functionality of microstructured polymer optical fibres. Australia leads the world in microstructured polymer optical fibre (mPOF) research that has attracted serious commercial interest from multinational companies. A series of ATSE funded workshops in Europe during 2004 strongly indicated that the incorporation of a range of additional functionalities within novel fibres is the right path to follow to maintain research momentum and leadership. This interdisciplinary project offer ....Tailoring the functionality of microstructured polymer optical fibres. Australia leads the world in microstructured polymer optical fibre (mPOF) research that has attracted serious commercial interest from multinational companies. A series of ATSE funded workshops in Europe during 2004 strongly indicated that the incorporation of a range of additional functionalities within novel fibres is the right path to follow to maintain research momentum and leadership. This interdisciplinary project offers a clear route to expanded collaboration in both Australia and overseas thus ensuring that the OFTC retains its research and technological edge into the future whilst helping to satisfy the demand for students trained in leading-edge photonics.Read moreRead less
Optical Nano-plasmonics. There is much current interest and excitement in nano-optics, where light interacts with features on its own scale or finer than it. One way of achieving strong interactions between light and finely structured systems is to incorporate metallic elements, and use the resonances called surface plasmons which arise due to electric currents flowing on the metal. We will develop accurate ways of calculating the properties of these plasmons for a range of metal-dielectric syst ....Optical Nano-plasmonics. There is much current interest and excitement in nano-optics, where light interacts with features on its own scale or finer than it. One way of achieving strong interactions between light and finely structured systems is to incorporate metallic elements, and use the resonances called surface plasmons which arise due to electric currents flowing on the metal. We will develop accurate ways of calculating the properties of these plasmons for a range of metal-dielectric systems, in order to design highly miniaturized structures which can manipulate light for applications in optical sensors and related devices.Read moreRead less