Pushing the frontiers of gravitational wave science: from technology to astrophysics. The direct detection of Einstein's elusive gravitational waves will not only confirm one of the most important theories in physics, it will unleash a new form of radiation (in addition to electromagnetic) with which to study the Universe. Our participation in this quest continues Australia's role in the vanguard of new astronomy and its exploitation. This proposal will produce scientists highly trained in ar ....Pushing the frontiers of gravitational wave science: from technology to astrophysics. The direct detection of Einstein's elusive gravitational waves will not only confirm one of the most important theories in physics, it will unleash a new form of radiation (in addition to electromagnetic) with which to study the Universe. Our participation in this quest continues Australia's role in the vanguard of new astronomy and its exploitation. This proposal will produce scientists highly trained in areas of national priority, including frontier technologies such as photonics and smart information use through GRID computing. Developing ways to build instruments of almost unimaginable sensitivity fosters innovation leading to spin-offs into other areas of optical sensing - fundamental research resulting in economic benefit.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989093
Funder
Australian Research Council
Funding Amount
$1,800,000.00
Summary
Australian Partnership in Advanced LIGO. Advanced Interferometer Gravitational-Wave Observatory (LIGO) (AdvLIGO) will be the first gravitational wave observatory capable of frequent observation of known sources of gravitational waves leading to the birth of gravitational wave astronomy. The development of instruments capable of doing this is driving technology in fields such as lasers , optics, photonics and data analysis. By playing a key role in this facility, Australia will reap the scienti ....Australian Partnership in Advanced LIGO. Advanced Interferometer Gravitational-Wave Observatory (LIGO) (AdvLIGO) will be the first gravitational wave observatory capable of frequent observation of known sources of gravitational waves leading to the birth of gravitational wave astronomy. The development of instruments capable of doing this is driving technology in fields such as lasers , optics, photonics and data analysis. By playing a key role in this facility, Australia will reap the scientific and technical rewards of being part of the most exciting frontier of physics in the 21st Century whilst training scientists and technologists for tomorrow.Read moreRead less
Slow light in nanostructured materials. This project will introduce and demonstrate novel concepts for dynamically controlling the speed of light and manipulating optical pulses in specially designed nanoscale structures, making an essential step towards the creation of all-optical devices performing fast switching and processing of optical signals. These developments underpin the next generation of high-performance networks, promising to revolutionize global communications. This project will ke ....Slow light in nanostructured materials. This project will introduce and demonstrate novel concepts for dynamically controlling the speed of light and manipulating optical pulses in specially designed nanoscale structures, making an essential step towards the creation of all-optical devices performing fast switching and processing of optical signals. These developments underpin the next generation of high-performance networks, promising to revolutionize global communications. This project will keep Australia at the forefront of international research and provide training of students on breakthrough applications of photonics and nanotechnology, contributing to the uptake of frontier technologies by Australian industries for successful operation in a competitive global environment.Read moreRead less
Engineering phase and the flow of light in nanophotonics. Optical devices on the scale of only billionths of a meter impel photonic revolution in information technologies. The extraordinary sensitivity and tunability of light confined on nano-scale is caused by the yet unexplored and poorly understood world of tiniest flows of energy, the optical vortices. In this project we will learn to manipulate optical vortices with the light itself, introducing original concepts for intelligent engineering ....Engineering phase and the flow of light in nanophotonics. Optical devices on the scale of only billionths of a meter impel photonic revolution in information technologies. The extraordinary sensitivity and tunability of light confined on nano-scale is caused by the yet unexplored and poorly understood world of tiniest flows of energy, the optical vortices. In this project we will learn to manipulate optical vortices with the light itself, introducing original concepts for intelligent engineering of nano-elements of a photonic chip. This project will deliver underpinning knowledge, foremost practical expertise, and the prominent training of young researchers to secure Australia's international leadership in the rapidly growing and competitive field of nanophotonics.Read moreRead less
Digital Interferometry: A platform technology for robust optical measurements. Digital interferometry is a new concept which will allow the measurement precision of interferometry to be applied in otherwise inaccessible or unsuitable environments. It will enhance the performance of major scientific instruments, such as gravitational wave detectors and optical telescopes, whilst reducing the cost, giving Australia a high profile in the quest to understand the universe. When applied to everyday ....Digital Interferometry: A platform technology for robust optical measurements. Digital interferometry is a new concept which will allow the measurement precision of interferometry to be applied in otherwise inaccessible or unsuitable environments. It will enhance the performance of major scientific instruments, such as gravitational wave detectors and optical telescopes, whilst reducing the cost, giving Australia a high profile in the quest to understand the universe. When applied to everyday situations, such as surveillance, traffic flow or vibration monitoring, it can give Australian industry a economic and social advantage, increasing the wealth and security of the nation. Read moreRead less
Non-Gaussian states and entanglement distillation for Continuous Variable quantum information protocols. Amplifiers are important devices for electronic, computer as well as telecommunication industries. In the quantum world where light's corpuscular nature is prominent, amplification of a beam of light will have its associated noise penalty. This noise penalty sets limit to many quantum optical applications. This proposal aims to use a method based on conditional detection to realize a 'noisel ....Non-Gaussian states and entanglement distillation for Continuous Variable quantum information protocols. Amplifiers are important devices for electronic, computer as well as telecommunication industries. In the quantum world where light's corpuscular nature is prominent, amplification of a beam of light will have its associated noise penalty. This noise penalty sets limit to many quantum optical applications. This proposal aims to use a method based on conditional detection to realize a 'noiseless linear amplifier' that has no noise penalty probabilistically. Realization of this key device is central to extending the range of quantum communication, such as quantum cryptography. It also has applications in quantum computing and the potential to enhance sensitive measurements.Read moreRead less
Quantum and atom optics. The applicant leads a highly successful group of young investigators, achieving internationally acclaimed work in quantum optics. Photonics technology is now at the brink of using the full advantage of quantum mechanics, through the concept of quantum information in optical and atomic systems. The experiments at the ANU group can provide new applications to the photonics industry, in particular in communication, sensing and microscopy. The proposed work is expected to ....Quantum and atom optics. The applicant leads a highly successful group of young investigators, achieving internationally acclaimed work in quantum optics. Photonics technology is now at the brink of using the full advantage of quantum mechanics, through the concept of quantum information in optical and atomic systems. The experiments at the ANU group can provide new applications to the photonics industry, in particular in communication, sensing and microscopy. The proposed work is expected to create fundamental research and generate future commercial opportunities in an area where Australian science is at the leading edge of research and the international demand is rising.Read moreRead less
Quantum spatial modes and their use in imaging, measurement, and communication. Quantum optics has the potential to provide highly accurate physical measurements, and to improve the speed and security of communication. The spatial modes of a light field provide a new and interesting basis for these investigations.
This fellowship proposes to generate spatially correlated quantum light beams, applying them to spatial positioning applications, such as atomic force microscopy, and to quantum ....Quantum spatial modes and their use in imaging, measurement, and communication. Quantum optics has the potential to provide highly accurate physical measurements, and to improve the speed and security of communication. The spatial modes of a light field provide a new and interesting basis for these investigations.
This fellowship proposes to generate spatially correlated quantum light beams, applying them to spatial positioning applications, such as atomic force microscopy, and to quantum communication protocols. I will experimentally develop general techniques to losslessly combine multiple quantum spatial modes, and demonstrate multi-mode quantum correlations in a light beam. I will investigate the potential of this light to cryptography, densecoding, and atomic force microscopy.
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Advances in Quantum Imaging and Quantum Memory using Squeezed Light and Entanglement. Maintaining a leading position in fundamental research will always result in directly related technologies or spin-offs. Being the first to demonstrate a Quantum Memory and spatial entanglement will guarantee Australia a leading role in two promising quantum research fields. High sensitive position measurements as used in Atomic Force Microscopy can directly benefit from developments of this project. The demons ....Advances in Quantum Imaging and Quantum Memory using Squeezed Light and Entanglement. Maintaining a leading position in fundamental research will always result in directly related technologies or spin-offs. Being the first to demonstrate a Quantum Memory and spatial entanglement will guarantee Australia a leading role in two promising quantum research fields. High sensitive position measurements as used in Atomic Force Microscopy can directly benefit from developments of this project. The demonstration of a Quantum Memory for continuous variables will boost the progress in the realisation of a future quantum network. The participation at a high level in the Quantum research community will bring worldwide recognition to Australia.Read moreRead less
The Standard Quantum Limit and Beyond. The uncertainty principle sets limits on the sensitivity to which any measurement can be made - the standard quantum limit (SQL). This limit is yet to be reached on a macroscopic object and, until recently, was regarded as unsurpassable. Due to the rapid improvement in optical measurement technology developed for Gravitational Wave Astronomy, there is now the prospect of experimentally reaching the standard quantum limit within this decade. This project wi ....The Standard Quantum Limit and Beyond. The uncertainty principle sets limits on the sensitivity to which any measurement can be made - the standard quantum limit (SQL). This limit is yet to be reached on a macroscopic object and, until recently, was regarded as unsurpassable. Due to the rapid improvement in optical measurement technology developed for Gravitational Wave Astronomy, there is now the prospect of experimentally reaching the standard quantum limit within this decade. This project will harness much of this technology to achieve the SQL. It will also experimentally develop new quantum measurement techniques to surpass this limit.Read moreRead less