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Crossing quantum-classical boundaries in a single particle. This project is aimed at constructing and observing an individual quantum system that can exhibit chaotic behaviour under controllable conditions. It is a long-sought goal of modern physics that can become reality for the first time in the world, thanks to the unique availability in Australia of the most quantum-coherent single spin ever made and a long history of theoretical advances in the field. Turning a spin into a chaotic system w ....Crossing quantum-classical boundaries in a single particle. This project is aimed at constructing and observing an individual quantum system that can exhibit chaotic behaviour under controllable conditions. It is a long-sought goal of modern physics that can become reality for the first time in the world, thanks to the unique availability in Australia of the most quantum-coherent single spin ever made and a long history of theoretical advances in the field. Turning a spin into a chaotic system will uncover the true nature of the quantum-classical boundary, and verify whether an underlying classical chaotic dynamics ultimately influences the behaviour of quantum systems. It is expected that the discoveries made will illuminate the path towards the technological exploitation of increasingly complex quantum devices.Read moreRead less
Chaotic Semiconductor Lasers and Controllability of Semiconductor Laser Noise. Chaotic semiconductor lasers (CSLs) are emerging as a potentially important light source for optical communication systems with improved security. Novel designs for compact, practical CSLs that can be integrated into existing optical communications networks will result. CSL systems suitable for secure point-to-point optical communication systems will also be developed. Fabrication of the devices in Australia means th ....Chaotic Semiconductor Lasers and Controllability of Semiconductor Laser Noise. Chaotic semiconductor lasers (CSLs) are emerging as a potentially important light source for optical communication systems with improved security. Novel designs for compact, practical CSLs that can be integrated into existing optical communications networks will result. CSL systems suitable for secure point-to-point optical communication systems will also be developed. Fabrication of the devices in Australia means there is the opportunity for commercial exploitation at a national level. The scientific study of the characteristics of the CSLs, especially the chaos, will be interesting to the scientific and general community. The early career researchers involved will benefit from high quality professional development experiences.Read moreRead less
Quantum limits in measurement and communication. By manipulating atoms and single particles of light, quantum technologies promise a revolution in communications systems and high-precision measurements for scientific and engineering applications. The benefits of this revolution may be comparable with those of modern semiconductors. This project will bring these benefits closer by achieving the fundamental limits to measurement allowed by quantum physics, and harnessing the power of these measure ....Quantum limits in measurement and communication. By manipulating atoms and single particles of light, quantum technologies promise a revolution in communications systems and high-precision measurements for scientific and engineering applications. The benefits of this revolution may be comparable with those of modern semiconductors. This project will bring these benefits closer by achieving the fundamental limits to measurement allowed by quantum physics, and harnessing the power of these measurements for communication. It will also identify ways to simplify potential quantum technologies, hastening their adoption. This research will place Australian theoretical and experimental researchers at the forefront of 21st century technology.Read moreRead less
Controlling spin coherence with rotation. This project aims to harness the ability to control the fundamental interactions which limit the precision of a diamond quantum sensor, enabling more sensitive magnetometry. Quantum sensors are unveiling new insights into nano-scale phenomena. Single atom defects in diamonds have been at the forefront of this revolution in nano-scale sensor technology. A unique capability, spinning diamond quantum sensors at up to 500,000 rpm, fast enough that quantum pr ....Controlling spin coherence with rotation. This project aims to harness the ability to control the fundamental interactions which limit the precision of a diamond quantum sensor, enabling more sensitive magnetometry. Quantum sensors are unveiling new insights into nano-scale phenomena. Single atom defects in diamonds have been at the forefront of this revolution in nano-scale sensor technology. A unique capability, spinning diamond quantum sensors at up to 500,000 rpm, fast enough that quantum properties of the defects are preserved during a cycle has been established. This project will address the long-standing problem of nano-scale solid-materials characterisation using rotationally-enhanced quantum magnetic resonance spectroscopy.Read moreRead less
Integrated quantum photonics. Australia is a leader in quantum science and technology - from nanotechnology to quantum computers, amazing advances are being made possible as we harness the laws of quantum physics. This project will enhance the nation's profile in this discipline by developing a new technology that allows photons - single particles of light - to be added together to form powerful quantum machines; and using this to explore the phenomenon that makes quantum technology powerful. Th ....Integrated quantum photonics. Australia is a leader in quantum science and technology - from nanotechnology to quantum computers, amazing advances are being made possible as we harness the laws of quantum physics. This project will enhance the nation's profile in this discipline by developing a new technology that allows photons - single particles of light - to be added together to form powerful quantum machines; and using this to explore the phenomenon that makes quantum technology powerful. This work will put Australian researchers at the forefront of new quantum technologies. 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
Emergent many-body phenomena in engineered quantum optical systems. In recent years, scientists have realised unprecedented control over light-matter interaction. Single particle dynamics in engineered systems are now well understood, but when scaled up, the many-body behaviour remains unexplored. This project will significantly advance our understanding of new emergent quantum phenomena arising from engineered interactions between many particles. These phenomena are qualitatively new behaviour ....Emergent many-body phenomena in engineered quantum optical systems. In recent years, scientists have realised unprecedented control over light-matter interaction. Single particle dynamics in engineered systems are now well understood, but when scaled up, the many-body behaviour remains unexplored. This project will significantly advance our understanding of new emergent quantum phenomena arising from engineered interactions between many particles. These phenomena are qualitatively new behaviour that cannot be explained as an extension of single-particle behaviour. The chief aim is to unravel the quantum dynamics of these systems. The project is expected to assist in producing new quantum technologies such as sources and detectors of quantum light and new atomic clocks.
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Observing the quantum chaotic trajectories of a single nucleus. This project aims to explain the fundamental link between quantum chaos, quantum measurement and the quantum/classical transition. This will be achieved by observing the chaotic dynamics of a highly controllable, extremely coherent, single nuclear spin - the world-first experimental demonstration of quantum chaos in a single particle. The project expects to deepen our understanding and control of the physical world and has potential ....Observing the quantum chaotic trajectories of a single nucleus. This project aims to explain the fundamental link between quantum chaos, quantum measurement and the quantum/classical transition. This will be achieved by observing the chaotic dynamics of a highly controllable, extremely coherent, single nuclear spin - the world-first experimental demonstration of quantum chaos in a single particle. The project expects to deepen our understanding and control of the physical world and has potential to benefit the industry sector.Read moreRead less
Quantum sensing from the bottom up with engineered semiconductor devices. This project aims to develop electronic devices that work as sensors of electromagnetic fields, wherein genuine quantum effects are used to reach unprecedented gains in sensitivity. It combines the significance of unveiling the fundamental limits of quantum-enhanced metrology, with the convenience of doing so in potentially manufacturable semiconductor devices. The expected outcome is a novel, bottom-up understanding of ho ....Quantum sensing from the bottom up with engineered semiconductor devices. This project aims to develop electronic devices that work as sensors of electromagnetic fields, wherein genuine quantum effects are used to reach unprecedented gains in sensitivity. It combines the significance of unveiling the fundamental limits of quantum-enhanced metrology, with the convenience of doing so in potentially manufacturable semiconductor devices. The expected outcome is a novel, bottom-up understanding of how best to utilize exotic quantum states of matter and fields for metrological advantage. These results will inform the design of the next-generation of extreme quantum sensors, with potential impact ranging from fundamental physics research to applications in mining or defense.Read moreRead less
Frequency standards with breakthrough performance: engineering immunity to local oscillator instabilities using dynamical error suppression. This project aims to dramatically advance state-of-the-art performance of one of the most important technological systems in modern electronics - precision frequency standards. Our work will provide orders of magnitude gains in performance by translating new knowledge from quantum information to the precision metrology research community.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE180100142
Funder
Australian Research Council
Funding Amount
$727,900.00
Summary
Australian quantum gas microscope. This project aims to create a quantum gas microscope for ultra-cold dysprosium atoms, realising a versatile system for quantum emulation, tests of fundamental, atom interferometry, and precision measurement. Quantum gas microscopy is a frontier area allowing atom-by-atom synthesis and probing of tailored quantum materials such as topological insulators. Using the lanthanide element dysprosium, which is highly magnetic and possesses both bosonic and fermionic is ....Australian quantum gas microscope. This project aims to create a quantum gas microscope for ultra-cold dysprosium atoms, realising a versatile system for quantum emulation, tests of fundamental, atom interferometry, and precision measurement. Quantum gas microscopy is a frontier area allowing atom-by-atom synthesis and probing of tailored quantum materials such as topological insulators. Using the lanthanide element dysprosium, which is highly magnetic and possesses both bosonic and fermionic isotopes, this facility will serve the needs of multiple research groups with diverse scientific interests.Read moreRead less