Quantum Photonics with continuous laser beams - travel award. Quantum information and communication is a new paradigm in information technology which utilises quantum physics to improve current limitations in speed, security and fidelity of information transmission and processing, extending the present Electronics and Photonics devices. Future applications will include teleportation, cryptography and ultimately quantum computation. We propose to investigate these applications using continuous (C ....Quantum Photonics with continuous laser beams - travel award. Quantum information and communication is a new paradigm in information technology which utilises quantum physics to improve current limitations in speed, security and fidelity of information transmission and processing, extending the present Electronics and Photonics devices. Future applications will include teleportation, cryptography and ultimately quantum computation. We propose to investigate these applications using continuous (CW) laser beams and the Einstein-Podolsky-Rosen (EPR) quantum entanglement, which is generated via a pair of optical parametric oscillators. The advantage of CW over the established single photon technology is better detection efficiency, wider data bandwidth and a compatibility with existing photonics technology.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0775668
Funder
Australian Research Council
Funding Amount
$210,000.00
Summary
Direct write - microphotonics fabrication facility. Direct write-microfabrication, where an ultrafast laser is focussed to a small, intense spot and translated under computer control with respect to a target sample, has emerged as a significant enabling technology creating new opportunities in microphotonics. The proposed facility will enable researchers to modify the internal properties of glass blocks and write 'optical wires' (or waveguides). By combining waveguides with other laser written f ....Direct write - microphotonics fabrication facility. Direct write-microfabrication, where an ultrafast laser is focussed to a small, intense spot and translated under computer control with respect to a target sample, has emerged as a significant enabling technology creating new opportunities in microphotonics. The proposed facility will enable researchers to modify the internal properties of glass blocks and write 'optical wires' (or waveguides). By combining waveguides with other laser written functional components researchers will develop devices capable of processing optical information. Outcomes will include demonstrations of compact lasers and slow light generation.Read moreRead less
Multi-Soliton Complexes. This project aims to investigate phenomena related to multi-soliton complexes in optics. Solitons have the potential of high speed data transmission across the world. Their use in telecommunications requires various component and extensive knowledge of their properties. Multisoliton complexes are essential in future devices for high speed information processing and transmission. We expect that our proposed study would provide essential information regarding the propertie ....Multi-Soliton Complexes. This project aims to investigate phenomena related to multi-soliton complexes in optics. Solitons have the potential of high speed data transmission across the world. Their use in telecommunications requires various component and extensive knowledge of their properties. Multisoliton complexes are essential in future devices for high speed information processing and transmission. We expect that our proposed study would provide essential information regarding the properties of multisoliton complexes and their application in practice.Read moreRead less
Optical and matter-wave vortices in nonlinear and inhomogeneous media. Wave phenomena of diverse nature have a strikingly similar feature of vorticity, with the energy or matter spiralling around isolated phase singularities. This project targets the fundamental theoretical research in an interdisciplinary field of singular waves transporting vortices in nonlinear and inhomogeneous media. Our project will contribute to the designated priority area "Frontier Technologies for Building and Transfor ....Optical and matter-wave vortices in nonlinear and inhomogeneous media. Wave phenomena of diverse nature have a strikingly similar feature of vorticity, with the energy or matter spiralling around isolated phase singularities. This project targets the fundamental theoretical research in an interdisciplinary field of singular waves transporting vortices in nonlinear and inhomogeneous media. Our project will contribute to the designated priority area "Frontier Technologies for Building and Transforming Australian Industries" by providing fundamental understanding of novel physical phenomena and underpinning technological advances in the fields of photonics, atom, and electron optics, where Australia has built strong expertise and plays a significant role in the international development.Read moreRead less
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
System Theoretical Aspects of Spatial Signal Processing. The aims of the project is to gain better understanding of spatial characteristics of wireless communication channels; and to apply spatial signal processing theory to design receivers for wireless systems. The expected outcomes of the projects are new system theory for spatial signal processing, a new spatial model to characterize wireless communication channels, categorize a relationship between scattering environment antenna spacing and ....System Theoretical Aspects of Spatial Signal Processing. The aims of the project is to gain better understanding of spatial characteristics of wireless communication channels; and to apply spatial signal processing theory to design receivers for wireless systems. The expected outcomes of the projects are new system theory for spatial signal processing, a new spatial model to characterize wireless communication channels, categorize a relationship between scattering environment antenna spacing and multi-element antenna system capacity, and novel use of multiple antennas to improve the performance of wireless systems. Success in this investigation could have wide applications in the development of future mobile and fixed wireless communication systems.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0453541
Funder
Australian Research Council
Funding Amount
$298,052.00
Summary
Raman Photonic Device Facility. We are seeking funding for an Raman Photonic Device Facility. This represents a new opportunity for Australia to become a world leader in the rapidly advancing area of Raman interactions in photonic devices covering both real-world application and fundamental physical research. The equipment request comprises ultrafast and high-power laser systems, forming a unique integrated facility within Australia. This facility will link Australia's premier research organizat ....Raman Photonic Device Facility. We are seeking funding for an Raman Photonic Device Facility. This represents a new opportunity for Australia to become a world leader in the rapidly advancing area of Raman interactions in photonic devices covering both real-world application and fundamental physical research. The equipment request comprises ultrafast and high-power laser systems, forming a unique integrated facility within Australia. This facility will link Australia's premier research organization in the area of photonics, including the University of Sydney, Macquarie University and The Australian National University.Read moreRead less
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
Asymmetric InP-based structures for high power laser diodes at 1400-1500 nm for pumping optical amplifiers used in communication systems. This project is aimed at obtaining high power, single mode 1400-1500 nm wavelength laser diodes using a novel design of asymmetric InP-based structures. These devices are in great demand for pumping of erbium-doped and Raman amplifiers for powering the next generation of dense wavelength division multiplexing optical networks. The low modal gain (confinement f ....Asymmetric InP-based structures for high power laser diodes at 1400-1500 nm for pumping optical amplifiers used in communication systems. This project is aimed at obtaining high power, single mode 1400-1500 nm wavelength laser diodes using a novel design of asymmetric InP-based structures. These devices are in great demand for pumping of erbium-doped and Raman amplifiers for powering the next generation of dense wavelength division multiplexing optical networks. The low modal gain (confinement factor) of this asymmetric structure is expected to reduce internal losses and hence increase the output power with better thermal dissipation. Single mode could be obtained by careful design in the trade-off between filamentation and threshold current. Ion implantation is also proposed to suppress higher order modes.Read moreRead less
Singular optics of polychromatic light. This project targets fundamental research in the emerging field of nonlinear singular optics with polychromatic light. It underpins new technological advances in the field of photonics, where Australia has built strong expertise and plays a significant role in the international development. This research will assist in the development of new type of photonic applications, where the spatial and spectral coherence of light plays a key role. Therefore our pro ....Singular optics of polychromatic light. This project targets fundamental research in the emerging field of nonlinear singular optics with polychromatic light. It underpins new technological advances in the field of photonics, where Australia has built strong expertise and plays a significant role in the international development. This research will assist in the development of new type of photonic applications, where the spatial and spectral coherence of light plays a key role. Therefore our project will contribute to the designated priority area 'Frontier Technologies for Building and Transforming Australian Industries' by providing fundamental understanding of novel physical phenomena and by building experimental and theoretical basis for new photonic technologies.Read moreRead less