Optical circuits for quantum non-locality with single photons. This collaborative project between the University of Queensland and Hokkaido University will investigate fundamental aspects of quantum mechanics concerned with non-locality. The results will have direct relevance to the emerging field of quantum technology - new technologies based exploiting the quantum mechanical nature of physical systems. Through the collaboration Australia will gain access to world-class single photon generation ....Optical circuits for quantum non-locality with single photons. This collaborative project between the University of Queensland and Hokkaido University will investigate fundamental aspects of quantum mechanics concerned with non-locality. The results will have direct relevance to the emerging field of quantum technology - new technologies based exploiting the quantum mechanical nature of physical systems. Through the collaboration Australia will gain access to world-class single photon generation facilities that will be replicated here. A strong link between Japanese and Australian researchers, including students, will be formed.Read moreRead less
Quantum Atom Optics and Single Atom Detection with Micro-Bose-Einstein Condensates. A Bose Einstein condensate (BEC) is a collection of atoms, all in the same quantum state, like the photons in a laser. It is now possible to create a micro-BEC and move it around on an 'atom chip'. We propose an experimental and theoretical study of its properties including those quantum statistical effects which will limit future ultra-sensitive measurement technologies such as quantum electromechanical transdu ....Quantum Atom Optics and Single Atom Detection with Micro-Bose-Einstein Condensates. A Bose Einstein condensate (BEC) is a collection of atoms, all in the same quantum state, like the photons in a laser. It is now possible to create a micro-BEC and move it around on an 'atom chip'. We propose an experimental and theoretical study of its properties including those quantum statistical effects which will limit future ultra-sensitive measurement technologies such as quantum electromechanical transducers. We will develop methods to count small numbers of ultra-cold atoms, engineer their state and build a prototype device.Read moreRead less
Controlling quantum technologies. Australia is a leader in quantum technology - from molecular machines to quantum computers, amazing advances are being made possible as we harness the laws of quantum physics. Our project will enhance the nation's profile in this discipline by developing some of the ground rules for measuring and controlling the operation of quantum devices. This foundational work will put Australian theoretical and experimental researchers at the forefront of this new field, an ....Controlling quantum technologies. Australia is a leader in quantum technology - from molecular machines to quantum computers, amazing advances are being made possible as we harness the laws of quantum physics. Our project will enhance the nation's profile in this discipline by developing some of the ground rules for measuring and controlling the operation of quantum devices. This foundational work will put Australian theoretical and experimental researchers at the forefront of this new field, and there is significant opportunity for development of intellectual property such as patents. Young researchers and postgraduate students will play a substantial role in the project, maximising the training impact for new professionals in cutting-edge science and high technology.Read moreRead less
Direct deep-ultraviolet tunable laser sources generating continuous and ultra-short-pulse radiation for photonics applications. This project will develop two versatile and efficient sources of tunable deep-ultraviolet laser radiation. These sources are an enabling photonics technology that will have impact in the applied fields of precision spectroscopy and flow cytometry for detection of biological agents. The proposed ultrafast laser source will enable new fundamental research probing high-ene ....Direct deep-ultraviolet tunable laser sources generating continuous and ultra-short-pulse radiation for photonics applications. This project will develop two versatile and efficient sources of tunable deep-ultraviolet laser radiation. These sources are an enabling photonics technology that will have impact in the applied fields of precision spectroscopy and flow cytometry for detection of biological agents. The proposed ultrafast laser source will enable new fundamental research probing high-energy processes, such as ultrafast chemical reactions, on the femtosecond timescale.
Training through an APD fellowship in the national priority area of Frontier technologies: photonics will enhance Australia's expertise in this important area. Read moreRead less
Detectors and sources for photonic quantum engineering. This collaboration brings together two of the leading groups in quantum information and will speed the development of breakthrough technologies. Dr Jennewein is a senior member of one of the leading quantum optics groups in the world, with strong scientific credentials; Prof. White is an expert in making, applying, and detecting photons for quantum information. Dr Jennewein's experience will enhance research training of Australian students; ....Detectors and sources for photonic quantum engineering. This collaboration brings together two of the leading groups in quantum information and will speed the development of breakthrough technologies. Dr Jennewein is a senior member of one of the leading quantum optics groups in the world, with strong scientific credentials; Prof. White is an expert in making, applying, and detecting photons for quantum information. Dr Jennewein's experience will enhance research training of Australian students; using the unique facilities available in Australia, his research will be the first in the world to combine bright photon sources and efficient photon detectors, enabling new quantum technologies such as quantum communication, metrology, and computation.Read moreRead less
The Development of High Power Cryo-Cooled Lasers and Their Application to Remote Sensing and Other Satelite-based Data Acquisition. We shall develop high power cryo-cooled lasers which will contribute directly to the national research priorities in Frontier Technologies and Safe Guarding Australia. In particular it will contribute to photonics, to remote sensing of the environment and to space based defence and surveillance applications. It will establish Australia as a pioneer in the field and ....The Development of High Power Cryo-Cooled Lasers and Their Application to Remote Sensing and Other Satelite-based Data Acquisition. We shall develop high power cryo-cooled lasers which will contribute directly to the national research priorities in Frontier Technologies and Safe Guarding Australia. In particular it will contribute to photonics, to remote sensing of the environment and to space based defence and surveillance applications. It will establish Australia as a pioneer in the field and generate important IP. It will be of benefit to Australian and international laser and defence industry, and it will be an ideal project for educating young laser physicists and engineers, of which there currently is a serious shortage in Australia.Read moreRead less
Development of Optical Clocks and Their Applications to Precision Frequency Measurements and Time Keeping. The goal of the proposed international researcher exchange program is to enhance the ongoing collaboration between the Frequency Standards and Metrology (FSM) Group at the University of Western Australia and leading US research institutions, including National Institute of Standards and Technology (NIST) in the field of (i) laser cooled atomic frequency standards, (ii) methods of optical ....Development of Optical Clocks and Their Applications to Precision Frequency Measurements and Time Keeping. The goal of the proposed international researcher exchange program is to enhance the ongoing collaboration between the Frequency Standards and Metrology (FSM) Group at the University of Western Australia and leading US research institutions, including National Institute of Standards and Technology (NIST) in the field of (i) laser cooled atomic frequency standards, (ii) methods of optical frequency synthesis and coherent time transfer between widely separated parts of electromagnetic spectrum and (iii) generation of low noise microwave signals directly from frequency stabilised ultra-fast pulsed lasers.Read moreRead less
Imaging Light and Gases with Low Energy Electrons. The imaging of light and atoms trapped in the potential minima of optical lattices will be a world first, positioning Australia at the forefront of the merging fields of electron microscopy and atom optics, leading to important international recognition and publicity. This project, relevant to the frontier technologies of photonics, atom optics and quantum information processing, will also develop a skills base in surface electron microscopy and ....Imaging Light and Gases with Low Energy Electrons. The imaging of light and atoms trapped in the potential minima of optical lattices will be a world first, positioning Australia at the forefront of the merging fields of electron microscopy and atom optics, leading to important international recognition and publicity. This project, relevant to the frontier technologies of photonics, atom optics and quantum information processing, will also develop a skills base in surface electron microscopy and laser science by providing high level training for post-graduate and honours students. In addition, the utilisation of optical lattices as micro-environmental cells in electron microscopy will be an important development for in situ studies of the gas phase including chemical reactions.
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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
Measuring the linewidth enhancement factor and optical feedback level factor of semiconductor lasers based on optical feedback self-mixing interferometry. This project aims to develop a high performance solution for the challenging problem of measuring the linewidth enhancement factor (LEF) of semiconductor lasers (SLs) and the optical feedback level factor, C, for the optical feedback self-mixing (OFSM) systems. Specific outcomes of the research include (1) a new model for an optical feedback ....Measuring the linewidth enhancement factor and optical feedback level factor of semiconductor lasers based on optical feedback self-mixing interferometry. This project aims to develop a high performance solution for the challenging problem of measuring the linewidth enhancement factor (LEF) of semiconductor lasers (SLs) and the optical feedback level factor, C, for the optical feedback self-mixing (OFSM) systems. Specific outcomes of the research include (1) a new model for an optical feedback self-mixing effect, (2) a new approach for measuring LEF and C based on the proposed model, (3) signal processing algorithms for improving the performance of the proposed approach, and (4) an OFSM system prototype based on the new model and algorithms.Read moreRead less