Ultimate quantum limits to coherence. This project aims to discover the ultimate quantum limits to optical coherence. Quantum physics underpin the miniaturisation of technology, and quantum devices can do things better, often with vastly fewer resources, than conventional devices. Lasers underpin most modern optical technologies, and have been studied for decades, but the ultimate quantum limits are unknown. To find them, this project will use theoretical techniques that have not hitherto been c ....Ultimate quantum limits to coherence. This project aims to discover the ultimate quantum limits to optical coherence. Quantum physics underpin the miniaturisation of technology, and quantum devices can do things better, often with vastly fewer resources, than conventional devices. Lasers underpin most modern optical technologies, and have been studied for decades, but the ultimate quantum limits are unknown. To find them, this project will use theoretical techniques that have not hitherto been combined. This project will likely influence the long-term development of lasers and other quantum devices and underpin innovation in miniaturised optical technology and other quantum devices, leading ultimately to commercial products that yield a better quality of life.Read moreRead less
Bulk-boundary correspondence in quantum many-body systems. This project will develop theoretical and numerical methods to explore how the bulk properties of quantum materials at low temperature are manifested on the edge of the material. Characterising this bulk-boundary correspondence will uncover new regimes of physics and underpin the development of powerful quantum technologies in the laboratory.
Discovery Early Career Researcher Award - Grant ID: DE120101498
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Superspace and dualities in supersymmetric field theories, supergravity and string theory. Supersymmetry, supergravity and string theory have represented the most promising frontiers of high-energy theoretical physics. This project will develop new techniques and explore novel dynamical features at the forefront of some of the most exiting fields of fundamental physics.
The New Atom Laser: Theory of Quantum Atom Optical Sources. The atom laser is a new device which produces a coherent source of ultracold atoms. A practical atom laser will be a revolutionary source for atom optics. This project will develop a comprehensive and practical quantum theory of a new generation of atom lasers which can produce a continuous beam. This will require a different and more complicated theoretical approach to that which worked for optical lasers, but the result will be a d ....The New Atom Laser: Theory of Quantum Atom Optical Sources. The atom laser is a new device which produces a coherent source of ultracold atoms. A practical atom laser will be a revolutionary source for atom optics. This project will develop a comprehensive and practical quantum theory of a new generation of atom lasers which can produce a continuous beam. This will require a different and more complicated theoretical approach to that which worked for optical lasers, but the result will be a device with a spectral flux which is orders of magnitude better than the current state of the art.Read moreRead less
Solid Light: Frontiers and applications of solid-state Cavity Quantum Electro-Dynamics. Our understanding of quantum mechanics directly fuels new technology. We are on the verge of a new revolution in technology, where the aspects of quantum physics that we haven't been able to understand are now within technological reach. Our concept of solid-light joins two of the most important branches of physics, and in so doing develops a new technology of diamond-based quantum processors that will be b ....Solid Light: Frontiers and applications of solid-state Cavity Quantum Electro-Dynamics. Our understanding of quantum mechanics directly fuels new technology. We are on the verge of a new revolution in technology, where the aspects of quantum physics that we haven't been able to understand are now within technological reach. Our concept of solid-light joins two of the most important branches of physics, and in so doing develops a new technology of diamond-based quantum processors that will be built in Australia. This will benefit the Australian scientific community by providing devices to solve important quantum problems, and benefit the wider community by growing a new industry based around diamond quantum nanoscience.Read moreRead less
Detection and Control of Ultracold Atoms. Australia is at the forefront of research into atom lasers, a device that may be as important to science and technology this century as the laser was in the last. This project will provide important theoretical tools for developing the atom laser from an object of intrinsic interest to a useful tool. It will develop Australian scientific expertise in this area, and provide training for the next generation of Australian scientists.
Novel aspects and applications of quantum measurement theory. The first aim is to develop further a novel formalism for quantum measurement theory based on retrodiction (rather than prediction). The second is to apply this theory to non-Markovian systems (in which the measurement is smeared-out in time). The third is to combine quantum measurement theory with natural selection better to understand the appearance of the everyday world. The expected outcomes include a deeper understanding of quant ....Novel aspects and applications of quantum measurement theory. The first aim is to develop further a novel formalism for quantum measurement theory based on retrodiction (rather than prediction). The second is to apply this theory to non-Markovian systems (in which the measurement is smeared-out in time). The third is to combine quantum measurement theory with natural selection better to understand the appearance of the everyday world. The expected outcomes include a deeper understanding of quantum physics and the establishment of new techniques for analysing problems in quantum communication and quantum-limited technologies. These advances are significant both fundamentally and, at the dawn of the quantum information age, in practice.Read moreRead less
Entanglement Processing in N-Atom Systems. An essential part of modern technological society is an understanding the scientific explanation of the world around us, and a realization that these explanations must be critically tested in the light of technological advances. The study of multi-atom entanglement is closely related to questions of fundamental physics. A breakthrough in stimulating this problem could have applications in other areas of physics and in technology, such as information pro ....Entanglement Processing in N-Atom Systems. An essential part of modern technological society is an understanding the scientific explanation of the world around us, and a realization that these explanations must be critically tested in the light of technological advances. The study of multi-atom entanglement is closely related to questions of fundamental physics. A breakthrough in stimulating this problem could have applications in other areas of physics and in technology, such as information processing and cryptography.Read moreRead less
Diagnosing quantum noise sources in quantum information processors via machine learning. Noise is the primary obstacle to building large-scale quantum information processors that have the potential to revolutionise our understanding of the world. This project will use the powerful techniques and methods of machine learning to identify, characterise, and correct noise sources in the next generation of quantum information processors. These innovative techniques will allow the reliability of quantu ....Diagnosing quantum noise sources in quantum information processors via machine learning. Noise is the primary obstacle to building large-scale quantum information processors that have the potential to revolutionise our understanding of the world. This project will use the powerful techniques and methods of machine learning to identify, characterise, and correct noise sources in the next generation of quantum information processors. These innovative techniques will allow the reliability of quantum computer components to be tested, and thus help identify which candidate technologies are capable of building a scalable quantum computer.Read moreRead less
Quantum algorithms for computational physics. The project intends to provide a solid base of quantum algorithms that would enable quantum computers to tackle currently insurmountable problems. Many of the highest-value applications in computing are based on solving problems in physics. Quantum computers take advantage of the power of quantum mechanics to outperform even the fastest conceivable supercomputers. This project plans to use new tools in quantum algorithms to provide much faster ways f ....Quantum algorithms for computational physics. The project intends to provide a solid base of quantum algorithms that would enable quantum computers to tackle currently insurmountable problems. Many of the highest-value applications in computing are based on solving problems in physics. Quantum computers take advantage of the power of quantum mechanics to outperform even the fastest conceivable supercomputers. This project plans to use new tools in quantum algorithms to provide much faster ways for quantum computers to simulate physics, including molecular modelling, field theories that explain elementary forces in the universe, and differential equations needed to model classical physics. The increases in computing speed have the potential to enable new technology in areas such as drug design and materials science, as well as providing testable predictions for new theories of physics.Read moreRead less