Complex Dopant Diffusivity in Photonic Crystal Fibres and Applications. The outcomes of this research in the area of doped photonic crystal fibres will enable Australia to commercialise the technology and provide an opportunity for leading commercial ventures using novel doped PCF. These opportunities will eventually become large-scale industrial activities developed from the research in fields such as sensing, biophotonics, medical and defence and will result in significant economic benefit for ....Complex Dopant Diffusivity in Photonic Crystal Fibres and Applications. The outcomes of this research in the area of doped photonic crystal fibres will enable Australia to commercialise the technology and provide an opportunity for leading commercial ventures using novel doped PCF. These opportunities will eventually become large-scale industrial activities developed from the research in fields such as sensing, biophotonics, medical and defence and will result in significant economic benefit for Australia. Fundamental research outcomes in glass and dopants that can boost devices and introduce novel devices resulting from this project will contribute to all National Research Priorities.Read moreRead less
Fibre amplifiers and lasers with enhanced and novel functionality based on novel fibre fabricated by chelate modified chemical vapour deposition. This project will explore the application of a novel technique of fibre fabrication (chelate delivery in MCVD) to rare-earth doped fibres for fibre lasers and amplifiers. The chelate technique allows much greater control of the doping than has previously been possible. Higher rare-earth concentrations and greater control over dopant placement will perm ....Fibre amplifiers and lasers with enhanced and novel functionality based on novel fibre fabricated by chelate modified chemical vapour deposition. This project will explore the application of a novel technique of fibre fabrication (chelate delivery in MCVD) to rare-earth doped fibres for fibre lasers and amplifiers. The chelate technique allows much greater control of the doping than has previously been possible. Higher rare-earth concentrations and greater control over dopant placement will permit fibre lasers and amplifiers with increased and novel functionality.Read moreRead less
Creation of novel photonic and nanostructured materials by ablation of solids with ultra-fast lasers. This project will study of the production of technologically important thin film materials and nanostructured materials using our patented ultra-fast pulsed laser deposition process. Thin film materials required for future applications in photonics will be a priority. In addition ultra-fast pulsed laser deposition can be used to create nanopartilces and mechanisms affecting the growth of these ....Creation of novel photonic and nanostructured materials by ablation of solids with ultra-fast lasers. This project will study of the production of technologically important thin film materials and nanostructured materials using our patented ultra-fast pulsed laser deposition process. Thin film materials required for future applications in photonics will be a priority. In addition ultra-fast pulsed laser deposition can be used to create nanopartilces and mechanisms affecting the growth of these materials will be studied. The project therefore falls into two priority areas: photon science and nanotechnology. Outcomes in addition to new knowledge will include materials and processes with commercial potential.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
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
Rare Earth doped chalcogenide glass films for on-chip optical amplifiers. The project will contribute to Australia's strong record of achievement in photonics technology. It has the potential to migrate photonic chip technology for all-optical processing from laboratory demonstrations to a commercially viable technology. If this is achieved commercialisation through a start-up company will become possible. All-optical processing is an advanced technology that will help increase the speed and the ....Rare Earth doped chalcogenide glass films for on-chip optical amplifiers. The project will contribute to Australia's strong record of achievement in photonics technology. It has the potential to migrate photonic chip technology for all-optical processing from laboratory demonstrations to a commercially viable technology. If this is achieved commercialisation through a start-up company will become possible. All-optical processing is an advanced technology that will help increase the speed and the bandwidth of optical communications systems and the internet.Read moreRead less
Development of deformation-failure-mechanism based parameters for design of microstructured optical fibre and photonics assembly. Australia has exceptional quality and depth in photon science research, with a demonstrated capacity to found and grow commercial ventures. However, the optimal design of interconnections in a photonic package is severely restricted by a lack of detailed knowledge of their deformation and failure mechanisms. The proposed study will use novel techniques to create a bas ....Development of deformation-failure-mechanism based parameters for design of microstructured optical fibre and photonics assembly. Australia has exceptional quality and depth in photon science research, with a demonstrated capacity to found and grow commercial ventures. However, the optimal design of interconnections in a photonic package is severely restricted by a lack of detailed knowledge of their deformation and failure mechanisms. The proposed study will use novel techniques to create a basis for mechanism-based deformation and failure models that will then be used to improve the design and lifetime of new type microstructured optical fibres and adhesive assemblies, expanding and enhancing Australia's capacity in the areas.
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