Invariants of singular spaces from noncommutative geometry. The project addresses questions of significance at the international forefront in the mathematical sciences and the ARC funds will enable research training of students and postdoctoral fellows at this very high level. International collaboration and networking is a key feature that will enhance Australia's scientific standing and provide opportunities for early career researchers to engage internationally with world leaders. The mainten ....Invariants of singular spaces from noncommutative geometry. The project addresses questions of significance at the international forefront in the mathematical sciences and the ARC funds will enable research training of students and postdoctoral fellows at this very high level. International collaboration and networking is a key feature that will enhance Australia's scientific standing and provide opportunities for early career researchers to engage internationally with world leaders. The maintenance of a high quality research program at ANU enhances Australia's ability to attract international students and places the ANU in the top league of world universities. It brings with it recognition of Australia as a culturally advanced nation.Read moreRead less
Quantum Integrable Systems and Applications: From Condensed Matter to Quantum Information. Quantum integrable systems have produced exciting results and techniques vital in the efforts to achieve the ultimate goal of understanding quantum science beyond perturbation. The proposal gathers four world experts from Australia, Japan and Russia to work on highly interdisciplinary projects designed to resolve fundamental problems in the field, which will underpin the development of emerging technologie ....Quantum Integrable Systems and Applications: From Condensed Matter to Quantum Information. Quantum integrable systems have produced exciting results and techniques vital in the efforts to achieve the ultimate goal of understanding quantum science beyond perturbation. The proposal gathers four world experts from Australia, Japan and Russia to work on highly interdisciplinary projects designed to resolve fundamental problems in the field, which will underpin the development of emerging technologies. As a result, Australian science will be seen to be at the forefront internationally, and the leading status of Australia in the field will be greatly strengthened. Early career researchers and PhD students will be trained as part of the project, important in enhancing Australia's capability to develop and retain scientific talent. Read moreRead less
Searching for solvability in Statistical Mechanics and beyond using advanced Enumerative Combinatorics. Standard models in lattice statistical mechanics provide basic models of a large variety of physical systems from polymers to the spread of forest fires. The ability to write down some kind of solution to these problems provides inestimable insight into their generic and universal behaviour. This project aims to expand the types of "solution" that mathematicians and physicists can write down.
Integrable quantum systems: mathematical foundations for developing quantum science. Quantum science is an exciting and challenging area, one which will underpin the development of the next generation of computers and novel devices such as atom lasers. New mathematical techniques are being pursued, to formulate the frameworks that will provide deep insights into the complex nature of the physical principles governing this field, in order to fully realise the potential applications. This project ....Integrable quantum systems: mathematical foundations for developing quantum science. Quantum science is an exciting and challenging area, one which will underpin the development of the next generation of computers and novel devices such as atom lasers. New mathematical techniques are being pursued, to formulate the frameworks that will provide deep insights into the complex nature of the physical principles governing this field, in order to fully realise the potential applications. This project will enhance the scale of an established and internationally competitive program in mathematics research, producing new approaches to meet these demands. It will also provide opportunities for research training, important in ensuring that Australia is well equipped to play a leading role in future quantum science developments.
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Algebraic Structures and Correlations in Quantum Many-Body Systems. Algebraic structures such as quantized superalgebras are among the most important discoveries in mathematics and have applications in a wide range of physics. Internationally there has been recent excitement about vertex operators and representations of these algebraic structures and their applications to integrable systems and quantum field theory. I have made significant contributions to this rapidly expanding field, and will ....Algebraic Structures and Correlations in Quantum Many-Body Systems. Algebraic structures such as quantized superalgebras are among the most important discoveries in mathematics and have applications in a wide range of physics. Internationally there has been recent excitement about vertex operators and representations of these algebraic structures and their applications to integrable systems and quantum field theory. I have made significant contributions to this rapidly expanding field, and will capitalize on this success. I will develop a comprehensive theory of these mathematical structures and their applications in the construction of correlation functions and form factors, and in so doing write a definitive monograph on the subject.Read moreRead less
Metallic nanograins: superconducting correlations, Josephson tunneling and conformal field theory. Experimental studies of aluminium grains which are a few nanometres in size have exposed unexpected physical characteristics, including pairing interactions which are responsible for bulk superconductivity. Our previous theoretical work has shown that precise information about these nanograins can be gained in the framework of the exact solution of the BCS model. This project will continue our work ....Metallic nanograins: superconducting correlations, Josephson tunneling and conformal field theory. Experimental studies of aluminium grains which are a few nanometres in size have exposed unexpected physical characteristics, including pairing interactions which are responsible for bulk superconductivity. Our previous theoretical work has shown that precise information about these nanograins can be gained in the framework of the exact solution of the BCS model. This project will continue our work in this area with an emphasis on investigating the nature of Josephson tunneling between coupled nanograins. The results of this project will have important applications in emerging technologies such as the implementation of Josephson junctions of nanoscale size.Read moreRead less
Quantum many-body systems with long-range interactions. Integrable many-body systems with long-range interactions are the subject of intense research activity worldwide, because they involve powerful mathematics and have various physical applications ranging from condensed matter physics to high energy physics. This project involves intensive collaboration between leading mathematical physics groups in Japan and Australia on exciting new developments in the theory of such systems and their appli ....Quantum many-body systems with long-range interactions. Integrable many-body systems with long-range interactions are the subject of intense research activity worldwide, because they involve powerful mathematics and have various physical applications ranging from condensed matter physics to high energy physics. This project involves intensive collaboration between leading mathematical physics groups in Japan and Australia on exciting new developments in the theory of such systems and their applications to physics. The expected outcomes are new progress in an area at the cutting edge of mathematical physics and the establishment of strong research links between Japan and Australia.Read moreRead less
Quantum many-body systems with higher mathematical symmetries. Ongoing developments in the experimental realisation of ultracold quantum systems play a leading role in the international effort towards the eventual realisation of quantum technology. This project brings together Australian and US researchers with complementary strengths to develop the mathematical study of fundamental systems of interacting quantum particles of relevance to experiments. The project will ensure that Australian rese ....Quantum many-body systems with higher mathematical symmetries. Ongoing developments in the experimental realisation of ultracold quantum systems play a leading role in the international effort towards the eventual realisation of quantum technology. This project brings together Australian and US researchers with complementary strengths to develop the mathematical study of fundamental systems of interacting quantum particles of relevance to experiments. The project will ensure that Australian researchers participate in and benefit from international developments in a leading edge area of fundamental research. It will also contribute to training students in rapidly advancing areas with the capacity to contribute to a wide range of problems, including the emerging technology of quantum devices.Read moreRead less
Quantized Algebraic (Super) Structures and Applications. Algebraic structures such as quantized superalgebras and affine Lie (super)algebras provide a universal common algebraic framework underlying applications in a wide range of physical systems, leading to a high level of research activity worldwide. The project involves intensive collaborations between leading mathematical physics groups in China and Australia on exciting new developments in the theory of these algebraic structures and their ....Quantized Algebraic (Super) Structures and Applications. Algebraic structures such as quantized superalgebras and affine Lie (super)algebras provide a universal common algebraic framework underlying applications in a wide range of physical systems, leading to a high level of research activity worldwide. The project involves intensive collaborations between leading mathematical physics groups in China and Australia on exciting new developments in the theory of these algebraic structures and their applications to condensed matter physics and quantum field theories. The expected outcomes are significant new progress in an area at the forefront of mathematical physics and the establishment of strong research links between China and Australia.Read moreRead less
Quantum integrable models in nano and mesoscopic physics. The current advances in nanoscale and mesoscopic physics are
generating a wealth of activity with many exciting applications. This
project aims to study several theoretical aspects in three key areas;
the theory of ultrasmall metallic grains of dimensions of a few nanometres,
which through experimental work have shown characteristics which
are similar to macroscopic superconductors, the Nobel Prize
winning phenomenon of Bose-Einstei ....Quantum integrable models in nano and mesoscopic physics. The current advances in nanoscale and mesoscopic physics are
generating a wealth of activity with many exciting applications. This
project aims to study several theoretical aspects in three key areas;
the theory of ultrasmall metallic grains of dimensions of a few nanometres,
which through experimental work have shown characteristics which
are similar to macroscopic superconductors, the Nobel Prize
winning phenomenon of Bose-Einstein condensation in dilute alkali gases and the effects of magnetic impurities in strongly interacting electron systems. The approach of the project is to use the mathematical theory of exactly solvable systems to study these important areas in contemporary physics.
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