Spin-liquids, antiferromagnetism, and superconductivity in organic charge transfer salts: synthesis, neutron scattering and theory. Materials have driven the digital revolution. Understanding and controlling silicon has allowed us to make smaller devices that perform better; an iPhone has more computing power than a PC had ten years ago. For this remarkable trend to continue future devices will need to utilise novel physics and be made from new materials. We will grow crystals of organic molecul ....Spin-liquids, antiferromagnetism, and superconductivity in organic charge transfer salts: synthesis, neutron scattering and theory. Materials have driven the digital revolution. Understanding and controlling silicon has allowed us to make smaller devices that perform better; an iPhone has more computing power than a PC had ten years ago. For this remarkable trend to continue future devices will need to utilise novel physics and be made from new materials. We will grow crystals of organic molecules, whose properties derive from the correlated motion of the electrons in these materials. State-of-the-art 'neutron scattering' experiments will test theories of the way the electrons behave in these materials. We will answer fundamental questions, which is an important first step towards harnessing such effects for future technology.Read moreRead less
Modelling quantum dynamics of electronic excited states in complex molecular materials. Understanding new materials that are the basis of new sources of renewable energy sources represents a major scientific challenge. Many of these materials are composed of large organic molecules containing hundreds of atoms. Their properties and the concepts needed to understand these materials are distinctly different from semiconductors such as silicon. This research will enhance our ability to design bett ....Modelling quantum dynamics of electronic excited states in complex molecular materials. Understanding new materials that are the basis of new sources of renewable energy sources represents a major scientific challenge. Many of these materials are composed of large organic molecules containing hundreds of atoms. Their properties and the concepts needed to understand these materials are distinctly different from semiconductors such as silicon. This research will enhance our ability to design better materials and optimize the performance of organic solar cells and LEDs. Australia's capacity for research and development in this scientifically challenging and technologically important field will be enhanced by this project. Read moreRead less
Organic superconductors and frustrated antiferromagnets: from quantum chemistry to quantum many-body theory to experiment. Aims. To obtain an understanding of how quantum physics and the
interactions between electrons determine the unusual properties of
organic superconductors and frustrated antiferromagnets.
Significance. The project brings together investigators who are
each world leaders in their respective areas of expertise.
Expected outcomes. Answers will be obtained to fundamenta ....Organic superconductors and frustrated antiferromagnets: from quantum chemistry to quantum many-body theory to experiment. Aims. To obtain an understanding of how quantum physics and the
interactions between electrons determine the unusual properties of
organic superconductors and frustrated antiferromagnets.
Significance. The project brings together investigators who are
each world leaders in their respective areas of expertise.
Expected outcomes. Answers will be obtained to fundamental questions about how the quantum
properties of individual molecules combine to determine the
macroscopic properties of new states of matter.Read moreRead less
Superfluidity and metrology with ring shaped Bose-Einstein condensates. This proposal will answer a fundamental question about superfluidity, expanding our understanding of quantum many-particle systems. Australia excels in the fields of ultra-cold gases and quantum physics, and this proposal will further strengthen our international standing in these flagship areas of modern physics. The project will train a number of students in high-level technology and computing skills that are in high deman ....Superfluidity and metrology with ring shaped Bose-Einstein condensates. This proposal will answer a fundamental question about superfluidity, expanding our understanding of quantum many-particle systems. Australia excels in the fields of ultra-cold gases and quantum physics, and this proposal will further strengthen our international standing in these flagship areas of modern physics. The project will train a number of students in high-level technology and computing skills that are in high demand in our growing knowledge-based economy. Improved understanding of how Bose-Einstein condensates behave will assist in their development as sensitive measurement devices, with possible intellectual property benefits in the future as we learn to tame these unique systems.Read moreRead less
Algebraic Structures in Mathematical Physics and Their Applications. Algebraic structures such as affine (super)algebras, quantised algebras and vertex operator algebras are among the most important discoveries in mathematics. They provide a universal common algebraic framework underlying applications in a wide range of physics (eg. statistical mechanics, string theory, condensed matter physics etc.) leading to a high level of research activity worldwide. The project harnessess the high level ....Algebraic Structures in Mathematical Physics and Their Applications. Algebraic structures such as affine (super)algebras, quantised algebras and vertex operator algebras are among the most important discoveries in mathematics. They provide a universal common algebraic framework underlying applications in a wide range of physics (eg. statistical mechanics, string theory, condensed matter physics etc.) leading to a high level of research activity worldwide. The project harnessess the high level of expertise in mathematical physics across Australia to focus on exciting new developments in the theory of these algebraic structures and their application to physics, thus ensuring Australia plays a leading role in this rapidly expanding field.Read moreRead less
Spin tunnelling transport and quantum effects in magnetic nanostructures. A new field of "spintronics" takes advantage of the spin of electrons and revolutionises electronics leading to quantum devices. By understanding the behaviour of electron spin in materials we can learn new fundamentals in solid-state physics that will lead to a new generation of electronic, optoelectronic and magneto-electronic devices. The aim of this project is to study the spin tunnelling transport and noise, and relat ....Spin tunnelling transport and quantum effects in magnetic nanostructures. A new field of "spintronics" takes advantage of the spin of electrons and revolutionises electronics leading to quantum devices. By understanding the behaviour of electron spin in materials we can learn new fundamentals in solid-state physics that will lead to a new generation of electronic, optoelectronic and magneto-electronic devices. The aim of this project is to study the spin tunnelling transport and noise, and related quantum effects in various magnetic nanostructures, such as ferromagnet/semiconductor/ferromagnet junctions, using quantum statistics approsches. The outcome of the project is of considerable relevance to the researches of nanostructure and quantum information/computation in Australia.Read moreRead less
Interplay of superconductivity and magnetism in layered molecular crystals. The most interesting new electronic materials discovered in the past decade are built from layers of atoms or molecules. Many exhibit a subtle competition between magnetism and superconductivity.
This project will develop new theoretical concepts and models for the electronic properties of organic molecular crystals. The theoretical predictions will be tested experimentally at the USA National High Magnetic Field Labo ....Interplay of superconductivity and magnetism in layered molecular crystals. The most interesting new electronic materials discovered in the past decade are built from layers of atoms or molecules. Many exhibit a subtle competition between magnetism and superconductivity.
This project will develop new theoretical concepts and models for the electronic properties of organic molecular crystals. The theoretical predictions will be tested experimentally at the USA National High Magnetic Field Laboratory.
The outcome will be a better understanding of a wide range of materials (including high-temperature superconductors, giant magnetoresistance and plastic electronic materials) that could be the
basis of much of the electronic technology of the twenty-first century.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0239943
Funder
Australian Research Council
Funding Amount
$245,000.00
Summary
Access for Australian Researchers to Advanced Neutron-Beam Technique. Neutron scattering is one of the most powerful and important investigative tools in the study of materials. Australia has only a low-flux neutron source, HIFAR, which provides no cold or hot neutrons. This excludes large, important areas of science, such as functional films, polymers, self-assembly systems, biological materials, colloids and emulsions, and real-time in-situ studies.
This application aims to continue Aus ....Access for Australian Researchers to Advanced Neutron-Beam Technique. Neutron scattering is one of the most powerful and important investigative tools in the study of materials. Australia has only a low-flux neutron source, HIFAR, which provides no cold or hot neutrons. This excludes large, important areas of science, such as functional films, polymers, self-assembly systems, biological materials, colloids and emulsions, and real-time in-situ studies.
This application aims to continue Australia's parnership with the world's most intense neutron source, ISIS in the UK, in order to sustain the considerable Australian scientific momentum which now relies on ISIS.
The outcome will be new science that cannot be generated solely within Australia.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
ARC Complex Open Systems Research Network. Complexity is the common frontier in the physical, biological and social sciences. This Network will link specialists in all three sciences through five generic conceptual and mathematical theme activities. It will promote research into how subsystems self-organise into new emergent structures when assembled into an open, non-equilibrium system. Outcomes will include new technologies and software tools and deeper understanding of fundamental questions i ....ARC Complex Open Systems Research Network. Complexity is the common frontier in the physical, biological and social sciences. This Network will link specialists in all three sciences through five generic conceptual and mathematical theme activities. It will promote research into how subsystems self-organise into new emergent structures when assembled into an open, non-equilibrium system. Outcomes will include new technologies and software tools and deeper understanding of fundamental questions in science. An essential function of the network will be introducing researchers end users to new tools and broadening the horizons of graduate students.Read moreRead less