Photonic Crystals and Microstructured Optical Fibres for Device Applications. Photonic crystals and microstructured optical fibres, which are amongst the most exciting fields of modern optics and photonics, are set to underpin developments in the next generation of ultrahigh-bandwidth communications systems, the functionalities of which will be truly all-optical. This project will bring together of two leading research groups in these areas, enhancing their collaboration, complementing their ex ....Photonic Crystals and Microstructured Optical Fibres for Device Applications. Photonic crystals and microstructured optical fibres, which are amongst the most exciting fields of modern optics and photonics, are set to underpin developments in the next generation of ultrahigh-bandwidth communications systems, the functionalities of which will be truly all-optical. This project will bring together of two leading research groups in these areas, enhancing their collaboration, complementing their expertise, and enabling them to develop new theoretical and computational tools to facilitate device applications. The program will coordinate research over a broad front and bring real benefits to young researchers in both France and Australia.Read moreRead less
Light-matter interactions in microstructured optical waveguides for nonlinear optical signal processing. The challenge of conceiving and constructing the necessary components and devices for the next generation of lightwave telecommunications systems is a profound one. This issue is urgent as the current operating principles of switches, filters and sources and other devices simply do not allow for the upgrade to the extremely high data transmission speeds that will be required. Using glass opti ....Light-matter interactions in microstructured optical waveguides for nonlinear optical signal processing. The challenge of conceiving and constructing the necessary components and devices for the next generation of lightwave telecommunications systems is a profound one. This issue is urgent as the current operating principles of switches, filters and sources and other devices simply do not allow for the upgrade to the extremely high data transmission speeds that will be required. Using glass optical fibres as the starting point, we will devise, demonstrate and analyze these novel components, leveraging microstructured optical fibre technology and novel fabrication techniques, which are among the most recent developments in optical fibre research.
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Mechanical stresses in holey fibres. The development of holey fibres constitutes arguably the most exciting development in fibre optics in recent years. We will analyze the mechanical stresses in these fibres, which, together with the optical calculations and associated experiments, will allow us to design novel fibre-based devices. This will allow Nufern to develop new products based on holey fibres.
Centre for Ultrahigh-bandwidth Devices for Optical Systems. The Centre, through a ground-breaking research program, will in the next five years invent and develop a set of revolutionary optical devices and will integrate these devices onto a photonic chip, for the use in the next generation of ultra-high bandwidth optical telecommunications systems. These systems will dramatically improve online services to the Australian community in key areas such as health, education and business connectivity ....Centre for Ultrahigh-bandwidth Devices for Optical Systems. The Centre, through a ground-breaking research program, will in the next five years invent and develop a set of revolutionary optical devices and will integrate these devices onto a photonic chip, for the use in the next generation of ultra-high bandwidth optical telecommunications systems. These systems will dramatically improve online services to the Australian community in key areas such as health, education and business connectivity. Australia's high tech industry will benefit from the commercialisation opportunities arising from the Centre's research, and also from the creation of a pool of highly skilled ICT professionals.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0347499
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Development of a High Performance Computing Cluster for ac3 Research. This application proposes the development of a 350 Gflop Beowulf parallel computing cluster that will support high profile research of international significance, spanning the science and technology spectrum, and according with national priority areas identified by Government and the ARC. The facility will provide an urgently needed boost in both aggregate and peak HPC capacity in NSW, thereby facilitating the solution of the ....Development of a High Performance Computing Cluster for ac3 Research. This application proposes the development of a 350 Gflop Beowulf parallel computing cluster that will support high profile research of international significance, spanning the science and technology spectrum, and according with national priority areas identified by Government and the ARC. The facility will provide an urgently needed boost in both aggregate and peak HPC capacity in NSW, thereby facilitating the solution of the next generation of computational research problems. In doing so, it will underpin innovation by world ranking groups in diverse fields such as photonics, complex/intelligent systems, nanotechnology, bioinformatics, quantum physics and chemistry, engineering, and environmental modelling.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0347462
Funder
Australian Research Council
Funding Amount
$500,000.00
Summary
Femtosecond laser micromachining facility. The proposed establishment of a femtosecond laser micromachining facility, with microdiagnostic capabilities, will facilitate a range of projects involving fabrication of submicron structures in metals, polymers, glasses, ceramics and crystalline materials. This facility, unique in Australia , will be comparable to the best such facilities in the world, enabling researchers to apply new microfabrication techniques to a range of photonic and optoelectro ....Femtosecond laser micromachining facility. The proposed establishment of a femtosecond laser micromachining facility, with microdiagnostic capabilities, will facilitate a range of projects involving fabrication of submicron structures in metals, polymers, glasses, ceramics and crystalline materials. This facility, unique in Australia , will be comparable to the best such facilities in the world, enabling researchers to apply new microfabrication techniques to a range of photonic and optoelectronic devices, including laser-written optical planar waveguides, nonlinear components and photonic bandgap structures , and various biomedical microstructures. Outcomes will include demonstration and development of novel photonic/optoelectronic devices and of new techniques, crucial to cost-effective manufacture of photonic components.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
Hollow-core microstructured polymer fibres for optical sensing applications. A range of remarkable new optical fibres will be fabricated utilising the capabilities of a unique polymer fibre fabrication facility and focussing on the highly demanding class of microstructured fibres in which guidance in a hollow core is achieved through photonic band gap or Bragg guidance. Long lengths of low-loss fibres of this type will be developed, and applications in optical gas sensing, spectroscopy, voltage ....Hollow-core microstructured polymer fibres for optical sensing applications. A range of remarkable new optical fibres will be fabricated utilising the capabilities of a unique polymer fibre fabrication facility and focussing on the highly demanding class of microstructured fibres in which guidance in a hollow core is achieved through photonic band gap or Bragg guidance. Long lengths of low-loss fibres of this type will be developed, and applications in optical gas sensing, spectroscopy, voltage sensing and telecommunications will be explored.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
Ultrafast photonic integrated circuits: Unlocking the bandwidth. Australia's prosperity increasingly depends on its communications infrastructure and supporting technologies. We will develop optical technologies to deliver vast increases in bandwidth at low cost. This will be achieved by building a photonic integrated circuit from a breakthrough material that offers ultrafast all-optical switching capability. This infrastructure will be critical to almost all areas of Australian society: commerc ....Ultrafast photonic integrated circuits: Unlocking the bandwidth. Australia's prosperity increasingly depends on its communications infrastructure and supporting technologies. We will develop optical technologies to deliver vast increases in bandwidth at low cost. This will be achieved by building a photonic integrated circuit from a breakthrough material that offers ultrafast all-optical switching capability. This infrastructure will be critical to almost all areas of Australian society: commerce, personal communications, e-health and entertainment, and will improve the quality of life and the economic competitiveness of urban, rural and regional Australia. The outcomes will include the creation of spin-off companies to commercialise the optical technologies.Read moreRead less