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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
Relative quantum information theory. Quantum information encoded in relative degrees of freedom of multiple quantum systems offers striking advantages in communication and cryptography: it is immune to common types of noise and does not require reference systems shared between parties. This project aims to formulate a theory of relative quantum information, to develop practical information processing protocols that take advantage of relative encodings, and to propose proof-of-principle experim ....Relative quantum information theory. Quantum information encoded in relative degrees of freedom of multiple quantum systems offers striking advantages in communication and cryptography: it is immune to common types of noise and does not require reference systems shared between parties. This project aims to formulate a theory of relative quantum information, to develop practical information processing protocols that take advantage of relative encodings, and to propose proof-of-principle experiments in quantum optics that reveal these advantages. Expected outcomes include powerful communication and cryptographic protocols, a design for programmable quantum computation, and a fundamentally relative theory of quantum information connecting with other foundational fields of physics.Read moreRead less
The investigation of the effects of catalyst doping, element substitution and defects design in carbon materials for hydrogen storage. The successful introduction of an efficient and clean hydrogen economy is contingent on developing a cost-effective storage technology. Carbon materials have demonstrated significant promise in this area. The project aims to investigate the storage capacity of hydrogen in carbon materials by doping catalysts, substituting elements and introducing designed defect ....The investigation of the effects of catalyst doping, element substitution and defects design in carbon materials for hydrogen storage. The successful introduction of an efficient and clean hydrogen economy is contingent on developing a cost-effective storage technology. Carbon materials have demonstrated significant promise in this area. The project aims to investigate the storage capacity of hydrogen in carbon materials by doping catalysts, substituting elements and introducing designed defects into the structures of carbon materials, with both theoretical and experimental methods. This project also aims to foster a long term linkage with the National Institute of Advanced Industrial Science and Technology, Japan thus enhancing Australian Universities's integration with the research institutions overseas in research and developmentRead 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
Nonlinear dynamics and chaos in Bose-Einstein Condensates on atom chips. The field of Bose-Einstein condensation (BEC) has recently seen some remarkable achievements. Researchers are now able to produce and
manipulate BECs in magnetic microtraps formed by current carrying wires patterned onto a substrate (atom chip). This project extends work in this field to the investigation of physics at the quantum/classical boundary through the study of the dynamics of BECs on atom chips. By probing a no ....Nonlinear dynamics and chaos in Bose-Einstein Condensates on atom chips. The field of Bose-Einstein condensation (BEC) has recently seen some remarkable achievements. Researchers are now able to produce and
manipulate BECs in magnetic microtraps formed by current carrying wires patterned onto a substrate (atom chip). This project extends work in this field to the investigation of physics at the quantum/classical boundary through the study of the dynamics of BECs on atom chips. By probing a nonlinear system with a BEC we will examine how the quantum mechanics affects classically chaotic dynamics. We will also examine the classically forbidden phenomena of dynamical tunnelling and localisation.Read moreRead less