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Manipulation and Shaping of Light in the Far-Field using Advanced Fresnel Fibres. This project will focus on developing and understanding further the recent invention of the Fresnel fibre, which is designed to overcome diffraction from the end of an optical fibre. More sophisticated designs and combinations will allow arbitrary shaping of the optical field exiting an optical fibre for numerous applications. The physical basis for such phenomena to be realised is the efficient degree of coherent ....Manipulation and Shaping of Light in the Far-Field using Advanced Fresnel Fibres. This project will focus on developing and understanding further the recent invention of the Fresnel fibre, which is designed to overcome diffraction from the end of an optical fibre. More sophisticated designs and combinations will allow arbitrary shaping of the optical field exiting an optical fibre for numerous applications. The physical basis for such phenomena to be realised is the efficient degree of coherent scattering possible in air-material fibre such as air-silica photonic crystal fibres. In conjunction advanced characterisation techniques will be developed.Read moreRead less
Hypersensitisation and Patterned Photosensitivity in Glass. Recent developments involving holographically patterned photosensitivity in glass-based optical waveguides developed by our group can be extended to fabricate complex two-dimensional structures including planar waveguide photonic bandgap devices for applications in telecommunications, sensing and signal processing. These will include novel grating-array based 2-D DFB lasers and filters in rare-earth doped planar waveguides. Novel etchin ....Hypersensitisation and Patterned Photosensitivity in Glass. Recent developments involving holographically patterned photosensitivity in glass-based optical waveguides developed by our group can be extended to fabricate complex two-dimensional structures including planar waveguide photonic bandgap devices for applications in telecommunications, sensing and signal processing. These will include novel grating-array based 2-D DFB lasers and filters in rare-earth doped planar waveguides. Novel etching techniques to be used to enhance index contrast, as well as to characterise such devices, will be developed based on our recent observation of hydrogen-enhanced etching of glass. Such methods could potentially be applicable to not only photonic technologies but also semiconductor lithography of oxides.Read moreRead less
UNSW-Harvard-Cambridge Partnership in Semiconductor Nanostructures for Quantum Computing and Quantum Science. Breakthrough nanotechnologies based on quantum mechanics promise important new devices with many applications in information and communications technologies. For example, quantum computers promise an enormous increase in computing power, allowing fast and complex processing in areas such as database searching, gene sequencing and weather modeling. This new collaboration brings together r ....UNSW-Harvard-Cambridge Partnership in Semiconductor Nanostructures for Quantum Computing and Quantum Science. Breakthrough nanotechnologies based on quantum mechanics promise important new devices with many applications in information and communications technologies. For example, quantum computers promise an enormous increase in computing power, allowing fast and complex processing in areas such as database searching, gene sequencing and weather modeling. This new collaboration brings together researchers from major national Centres in Australia (UNSW), Great Britain (University of Cambridge) and the USA (Harvard University) to tackle one of modern sciences most challenging problems - how to control and manipulate quantum states.Read moreRead less
Photonic structures for high efficiency, low cost solar cells. Photovoltaics is a non-polluting, environmentally sustainable way of converting sunlight directly to electricity. The reduction of cost is the most important issue in photovoltaic solar energy conversion. This project will lead to the development of solar cell structures and techniques that have the potential to significantly reduce the cost of thin film solar cells, which are the major contender for the lowest cost photovoltaic te ....Photonic structures for high efficiency, low cost solar cells. Photovoltaics is a non-polluting, environmentally sustainable way of converting sunlight directly to electricity. The reduction of cost is the most important issue in photovoltaic solar energy conversion. This project will lead to the development of solar cell structures and techniques that have the potential to significantly reduce the cost of thin film solar cells, which are the major contender for the lowest cost photovoltaic technology. If the cost of photovoltaics was sufficiently reduced it could have a major impact on reducing greenhouse gas emissions and pollution in Australia.Read moreRead less
Nanostructured Silicon-Based Tandem Solar Cells. The expected outcome from the project is a new generation of low-cost silicon solar cell that will significantly reduce the costs of generating electricity from sunlight. Solar cells are presently the world's most rapidly growing energy source, with Australians and Australian companies already major players in the associated rapidly expanding industry. Solar cells represent the most benign technology yet suggested for supplying the world's future ....Nanostructured Silicon-Based Tandem Solar Cells. The expected outcome from the project is a new generation of low-cost silicon solar cell that will significantly reduce the costs of generating electricity from sunlight. Solar cells are presently the world's most rapidly growing energy source, with Australians and Australian companies already major players in the associated rapidly expanding industry. Solar cells represent the most benign technology yet suggested for supplying the world's future energy needs. A cleaner environment in the future than would otherwise be likely is another expected outcome as is the creation of major new opportunities for Australian industry.Read moreRead less
Terahertz optoelectronics based on spintronics materials. Spintronic devices have many advantages which include non-volatility, permitting data retention in non-powered conditions, increased integration densities, high data processing speeds, low electrical energy demands, and a fabrication process compatible with those currently used in semiconductor microelectronics. The low energy consumption of spintronic devices also leads to economic and environmental benefits. Spintronic devices will help ....Terahertz optoelectronics based on spintronics materials. Spintronic devices have many advantages which include non-volatility, permitting data retention in non-powered conditions, increased integration densities, high data processing speeds, low electrical energy demands, and a fabrication process compatible with those currently used in semiconductor microelectronics. The low energy consumption of spintronic devices also leads to economic and environmental benefits. Spintronic devices will help to meet the sensing and storage demands of information technology in the decades to come. The project will enhance the international competitiveness and export power of Australian industry in the areas of information technology, quantum computing, magnetic recording and optoelectronics.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL0992306
Funder
Australian Research Council
Funding Amount
$2,753,841.00
Summary
Nanowire Quantum Structures for Next Generation Optoelectronics. This innovative project on quantum nanowire optoelectronics will bring international kudos to Australian science in a hot research area of immense international interest, allow us to build new capabilities in nanotechnology, strengthen international linkages and lead to training of a world class high tech work force for Australian industries. This project has the potential to lead to fundamental discoveries and technologies of imm ....Nanowire Quantum Structures for Next Generation Optoelectronics. This innovative project on quantum nanowire optoelectronics will bring international kudos to Australian science in a hot research area of immense international interest, allow us to build new capabilities in nanotechnology, strengthen international linkages and lead to training of a world class high tech work force for Australian industries. This project has the potential to lead to fundamental discoveries and technologies of immense international and industrial interest. In addition to high impact publications, this project has the potential to lead to high tech start up companies and patentable technologies of benefit to Australian industry. Read moreRead less
Photon induced nonlinear absorption and transport in semiconductor nanostructures. Photon induced transport in electronic systems is of great importance in fundamental science and in development of new optoelectronics devices. In this project we aim to study the microwave radiation induced dc transport and nonlinear absorption in high mobility systems. The result will shed light on newly discoveredzero-resistance state in semiconductor nanostructures. The expected outcome is an improved underst ....Photon induced nonlinear absorption and transport in semiconductor nanostructures. Photon induced transport in electronic systems is of great importance in fundamental science and in development of new optoelectronics devices. In this project we aim to study the microwave radiation induced dc transport and nonlinear absorption in high mobility systems. The result will shed light on newly discoveredzero-resistance state in semiconductor nanostructures. The expected outcome is an improved understanding on the mechanism of reducing dc resistance in low-dimensional electronic systems.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0453974
Funder
Australian Research Council
Funding Amount
$113,190.00
Summary
T-ray factory: a new Australian source of strong, pulsed, broadband, terahertz radiation. Australian scientists and engineers require immediate access to frontier T-ray (terahertz radiation) technology to solve pressing current problems in semiconductor nanostructures and emerging problems in fields as diverse as biophysics and national security. Recent innovations now make practical the production of bursts of terahertz radiation by applying ultrafast optical pulses to photoconductive or elect ....T-ray factory: a new Australian source of strong, pulsed, broadband, terahertz radiation. Australian scientists and engineers require immediate access to frontier T-ray (terahertz radiation) technology to solve pressing current problems in semiconductor nanostructures and emerging problems in fields as diverse as biophysics and national security. Recent innovations now make practical the production of bursts of terahertz radiation by applying ultrafast optical pulses to photoconductive or electro-optic media, facilitating unparalleled time-resolved spectroscopy and imaging. The state-of-the-art equipment to be purchased and installed at Wollongong will enhance the existing excellent terahertz infrastructure (unique spectrometers, optically-pumped molecular laser) and efficiently service researchers in the dynamic Sydney (UTS, UNSW) - Wollongong (UoW) - Canberra (ANU) corridor.Read moreRead less
Non-linear dynamics in electronic systems and devices under intense terahertz radiation. Non-linear interactions allow for a detailed and intricate probing of materials. Sufficiently high-power light directed at a subject can yield spectroscopic data about multiple material parameters, providing a unique diagnostic tool for many applications. We propose to study the non-linear dynamic properties of electronic systems and devices under various external conditions. A thorough understanding of non- ....Non-linear dynamics in electronic systems and devices under intense terahertz radiation. Non-linear interactions allow for a detailed and intricate probing of materials. Sufficiently high-power light directed at a subject can yield spectroscopic data about multiple material parameters, providing a unique diagnostic tool for many applications. We propose to study the non-linear dynamic properties of electronic systems and devices under various external conditions. A thorough understanding of non-linear properties will accelerate development of new optoelectronic device in the terahertz frequency regime. Examples of these devices are oscillators and sensors.Read moreRead less