Optical parametric processes in randomized nonlinear photonic structures. This project will have an impact on understanding of the nonlinear optical effects in micron and sub-micron structures providing knowledge for potential practical applications. Innovative ideas emanating from this program will increase the national and international standing of the ANU and strengthen the reputation of Australia in the field of nonlinear photonics. The project will expand existing and create new collaborati ....Optical parametric processes in randomized nonlinear photonic structures. This project will have an impact on understanding of the nonlinear optical effects in micron and sub-micron structures providing knowledge for potential practical applications. Innovative ideas emanating from this program will increase the national and international standing of the ANU and strengthen the reputation of Australia in the field of nonlinear photonics. The project will expand existing and create new collaborative links with high profile international partners. It will also provide training and experience in the cutting edge research for graduate and undergraduate students.Read moreRead less
Special Research Initiatives - Grant ID: SR0354519
Funder
Australian Research Council
Funding Amount
$30,000.00
Summary
Network for Optical and Quantum Science and Technology. This Network links world-class researchers involved with the investigation and application of light and atoms, particularly at the quantum level. Three ARC Centres of Excellence* will be linked and networked with other successful research groups in optics, including atom optics and Bose-Einstein condensation (BEC), quantum computing, optical switching, imaging, and interferometry. The Network-facilitated interactions will foster multidisci ....Network for Optical and Quantum Science and Technology. This Network links world-class researchers involved with the investigation and application of light and atoms, particularly at the quantum level. Three ARC Centres of Excellence* will be linked and networked with other successful research groups in optics, including atom optics and Bose-Einstein condensation (BEC), quantum computing, optical switching, imaging, and interferometry. The Network-facilitated interactions will foster multidisciplinary approaches linking the majority of the Australian optics community, and harnessing Australia's existing research excellence in optics to address major questions in optical and quantum science and technology.
* Quantum-Atom Optics (ACQAO), Quantum Computing Technology (CQCT), Ultrahigh Bandwidth Devices and Optical Systems (CUDOS).
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Fabrication of complete photonic band gap structures by two-photon polymerization and subsequent infiltration with high refractive index materials. The ability to shrink photonic circuits by orders of magnitudes by the integration of photonic crystals offers many stimulating possibilities for novel device designs. A speculative view is that this miniaturisation can have a similar impact to that experienced in electronic components in the 1960s. However, the fabrication of 3D photonic crystals re ....Fabrication of complete photonic band gap structures by two-photon polymerization and subsequent infiltration with high refractive index materials. The ability to shrink photonic circuits by orders of magnitudes by the integration of photonic crystals offers many stimulating possibilities for novel device designs. A speculative view is that this miniaturisation can have a similar impact to that experienced in electronic components in the 1960s. However, the fabrication of 3D photonic crystals remains a major challenge and the development of new, flexible, and fast nano-fabrication techniques is vital. The realization of an innovative technique for the fabrication of 3D complete photonic band gap structures as it is suggested will make an essential contribution to the emerging field of all-optical tele- and data-communications and will deliver major economic benefit to Australia. Read moreRead less
A Laser Guide Star using a High Power, Synchronously Pumped Optical Parametric Oscillators. We will develop a novel high power source of 589nm coherent (laser) light to be used to create a laser guide star by exciting sodium atoms in the earth's upper atmosphere (the mesosphere). This is needed to determine the distortion caused by the atmosphere on an optical beam propagating through it and generate the information needed to correct those distortions using an adaptive optics telescope. This pr ....A Laser Guide Star using a High Power, Synchronously Pumped Optical Parametric Oscillators. We will develop a novel high power source of 589nm coherent (laser) light to be used to create a laser guide star by exciting sodium atoms in the earth's upper atmosphere (the mesosphere). This is needed to determine the distortion caused by the atmosphere on an optical beam propagating through it and generate the information needed to correct those distortions using an adaptive optics telescope. This project focuses on the development of a novel high power 589nm source based on a synchronously pumped optical parametric oscillator.Read moreRead less
Thulium doped silica-based optical fibres - towards the realisation of an optical amplifier. In the last decade the data capacity of a single optical fibre has grown way beyond all expectations. However, our ability to utilise the available capacity continues to keep pace with any advance. This project has the potential to add substantially to the transmission capacity by developing an optical amplifier at wavelengths which, although available within the fibre, can not currently be utilised. The ....Thulium doped silica-based optical fibres - towards the realisation of an optical amplifier. In the last decade the data capacity of a single optical fibre has grown way beyond all expectations. However, our ability to utilise the available capacity continues to keep pace with any advance. This project has the potential to add substantially to the transmission capacity by developing an optical amplifier at wavelengths which, although available within the fibre, can not currently be utilised. The focus of the project is the study of thulium doped silica-based fibres for amplification in the 1460 to 1530 nm wavelength region. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0347140
Funder
Australian Research Council
Funding Amount
$208,000.00
Summary
Picosecond optical probing and characterization of infrared and visible devices. The facility consists of a laser to generate short infrared pulses, and an oscilloscope and detectors to measure such pulses. It will be used to characterize and investigate a new generation of novel optical fibre devices and microstructures, which are to form the basis of the next generation of telecommunications systems, and also novel and unique laser types. The research and development of all of these devices ar ....Picosecond optical probing and characterization of infrared and visible devices. The facility consists of a laser to generate short infrared pulses, and an oscilloscope and detectors to measure such pulses. It will be used to characterize and investigate a new generation of novel optical fibre devices and microstructures, which are to form the basis of the next generation of telecommunications systems, and also novel and unique laser types. The research and development of all of these devices are receiving external funding (or are in negotiations therefore). The facility allows for high-speed and high-accuracy data acquisition, which makes it unique in Australia.Read moreRead less
Novel multi-channel and nonlinear Bragg grating devices. High capacity and reliable telecommunications links are essential for many aspects of modern life and work. Optical fibres offer essentially unlimited capacity, but their optimal use requires the transmission of multiple wavelength channels simultaneously. This, in turn, requires the development of special-purpose fibre devices for multiplexing and de-multiplexing these channels, as well as for other optical filtering and switching tasks. ....Novel multi-channel and nonlinear Bragg grating devices. High capacity and reliable telecommunications links are essential for many aspects of modern life and work. Optical fibres offer essentially unlimited capacity, but their optimal use requires the transmission of multiple wavelength channels simultaneously. This, in turn, requires the development of special-purpose fibre devices for multiplexing and de-multiplexing these channels, as well as for other optical filtering and switching tasks. Fibre Bragg gratings are central to many of these devices, and the aim of this project is to develop novel designs for linear and nonlinear Bragg grating devices which may significantly widen the current range of their applications.Read moreRead less
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
Innovation in photonic device imaging: The keystone for future technologies. Advances in the use of photonic technology in telecommunications and a range of industrial applications depend critically on a precise knowledge of the physical structure of the optical fibre or device. This project involves the development of a suite of precision imaging techniques for determining the structure of optical fibres and in-fibre devices such as gratings and its application to a range of important problems ....Innovation in photonic device imaging: The keystone for future technologies. Advances in the use of photonic technology in telecommunications and a range of industrial applications depend critically on a precise knowledge of the physical structure of the optical fibre or device. This project involves the development of a suite of precision imaging techniques for determining the structure of optical fibres and in-fibre devices such as gratings and its application to a range of important problems in optical fibre technology. This knowledge is central to the ability to optimise and improve fibre and device fabrication methods, laying the foundations for higher speed telecommunications and the production of novel photonic devices.Read moreRead less
Tailoring ultrafast pulses for Tb/s transmission with advanced modulation formats. Ultrahigh bandwidth communications technologies will play an increasingly important role in the social and economic development of Australia. The potential benefit is emphasised by the recent decision to build a broadband network valued at $8 B that will link the vast majority of Australian homes and businesses by high speed optical fibre. In this project we will investigate innovative approaches for optical trans ....Tailoring ultrafast pulses for Tb/s transmission with advanced modulation formats. Ultrahigh bandwidth communications technologies will play an increasingly important role in the social and economic development of Australia. The potential benefit is emphasised by the recent decision to build a broadband network valued at $8 B that will link the vast majority of Australian homes and businesses by high speed optical fibre. In this project we will investigate innovative approaches for optical transmission of data at the ultrahigh bit rates required by these next generation networks. These approaches will be based on technology developed in Australia by the Partner Organisation Optium Corporation, leading to further growth opportunities within the Australian manufacturing operation of this company.Read moreRead less