Polymer optical fibres with controlled molecular orientation for photonic applications. The objective of the proposed research is to boost the advantage of Australian scientists and engineers working in the field of photonics by investigating new physical principles and new ways of fabricating specialty plastic optical fibres. Such fibres can be used in optical devices, to improve transmission and processing of signals in data communications, for improving efficient operation of power industry, ....Polymer optical fibres with controlled molecular orientation for photonic applications. The objective of the proposed research is to boost the advantage of Australian scientists and engineers working in the field of photonics by investigating new physical principles and new ways of fabricating specialty plastic optical fibres. Such fibres can be used in optical devices, to improve transmission and processing of signals in data communications, for improving efficient operation of power industry, in biophotonics.
Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0346822
Funder
Australian Research Council
Funding Amount
$538,000.00
Summary
Polymer Optical Fibre Drawing Facility. A revolutionary new technology is emerging in polymer optical fibres, sparked by an important breakthrough in polymer optical fibres that was achieved last year by researchers at the University of Sydney. Therefore, Australia currently has a unique and short-lived opportunity to firmly establish themselves as the world leaders of this technology, provided the infrastructure to realise the novel concepts is available. We request funding for a high-quality p ....Polymer Optical Fibre Drawing Facility. A revolutionary new technology is emerging in polymer optical fibres, sparked by an important breakthrough in polymer optical fibres that was achieved last year by researchers at the University of Sydney. Therefore, Australia currently has a unique and short-lived opportunity to firmly establish themselves as the world leaders of this technology, provided the infrastructure to realise the novel concepts is available. We request funding for a high-quality polymer optical fibre draw tower to enable this. The collaborating institutions will be fabricating a range of different polymer optical fibres, targeting specific applications in optical sensing and telecommunications.Read moreRead less
Microstructured polymer interconnects for photonic devices. Efficient interconnection of photonic components is the most critical research problem facing the photonics industry in its efforts for integration. In this project, interconnects for photonic systems will be developed, utilising a recently developed new class of fibres - microstructured optical fibres, which have been called 'the next generation' of optical fibres because of their ability to produce a variety of tailorisable optical ef ....Microstructured polymer interconnects for photonic devices. Efficient interconnection of photonic components is the most critical research problem facing the photonics industry in its efforts for integration. In this project, interconnects for photonic systems will be developed, utilising a recently developed new class of fibres - microstructured optical fibres, which have been called 'the next generation' of optical fibres because of their ability to produce a variety of tailorisable optical effects. Specially designed and modified microstructured fibres will be developed to achieve efficient coupling from fibre to planar waveguide circuits, and to a range of photonic band gap devices that are currently being developed by the industry partner.Read moreRead less
Numerically Robust Extruder Die Design for Fabricating High-Quality Preforms for Microstructured Polymer Optical Fibres. Microstructural polymer optical fibres (mPOFs) were pioneered in Australia, are now comparable in performance (but much more versatile) than conventional polymer fibre, and are a highly attractive commercial option. Potential industrial applications envisage cost-effective preform fabrication as a key issue, with extrusion as the favoured route. This interdisciplinary project ....Numerically Robust Extruder Die Design for Fabricating High-Quality Preforms for Microstructured Polymer Optical Fibres. Microstructural polymer optical fibres (mPOFs) were pioneered in Australia, are now comparable in performance (but much more versatile) than conventional polymer fibre, and are a highly attractive commercial option. Potential industrial applications envisage cost-effective preform fabrication as a key issue, with extrusion as the favoured route. This interdisciplinary project benefits Australia by (i) extending and exploiting our research advantages in advanced photonics and computational rheology, (ii) providing the 'missing link' for large-scale mPOF production and positioning us to reap the economic benefits of this innovative technology, and (iii) providing computational techniques for rheological modelling that are applicable in diverse Australian industry sectors.Read moreRead less
One Step Pre-forms for Microstructured Polymer Optical Fibre. The pre-form rods this project yields will enable polymer optical fibre technology, just as suitable glass pre-forms enabled today's optical fibre. One-step casting techniques will yield PMMA rods with arrays of internal channels which can be empty, or filled with different clear polymer. Polymer microstructured optical fibre (PMOF) suitable for high bandwidth communications is then produced by drawing. It is urgently needed for local ....One Step Pre-forms for Microstructured Polymer Optical Fibre. The pre-form rods this project yields will enable polymer optical fibre technology, just as suitable glass pre-forms enabled today's optical fibre. One-step casting techniques will yield PMMA rods with arrays of internal channels which can be empty, or filled with different clear polymer. Polymer microstructured optical fibre (PMOF) suitable for high bandwidth communications is then produced by drawing. It is urgently needed for local communication networks in cars and buildings. Solid PMOF channels are new to this project, and should make PMOF easier to deploy. Nanoscale mapping of light transport modes and polymer defects will help validate channel designs.Read moreRead less