Optical-spin coupling in the nitrogen-vacancy centre in diamond. Australia has made investment in the developing area of quantum information processing where information is stored and processed by manipulating the spin states in solids. One of the most promising materials for this purpose is diamond incorporating nitrogen-vacancy colour centres. The appeal with this material is that the processing can be faster and components smaller as the spins can be controlled by laser beams. This project in ....Optical-spin coupling in the nitrogen-vacancy centre in diamond. Australia has made investment in the developing area of quantum information processing where information is stored and processed by manipulating the spin states in solids. One of the most promising materials for this purpose is diamond incorporating nitrogen-vacancy colour centres. The appeal with this material is that the processing can be faster and components smaller as the spins can be controlled by laser beams. This project investigates the control of spin with light to obtain optimum performance.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
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
Electron Emission from Diamond. Israel is emerging as an international hub of technology with one of the highest rates of R&D in the world. This collaborative project will access one of the world leading experts in diamond science and technology, Professor Alon Hoffman, to exploit the remarkable properties of diamond for a new generation of detectors and devices. Success in this project can lay the groundwork for tapping into the successful record of advanced technologies and venture capital fun ....Electron Emission from Diamond. Israel is emerging as an international hub of technology with one of the highest rates of R&D in the world. This collaborative project will access one of the world leading experts in diamond science and technology, Professor Alon Hoffman, to exploit the remarkable properties of diamond for a new generation of detectors and devices. Success in this project can lay the groundwork for tapping into the successful record of advanced technologies and venture capital funding that abound in Israel today. Read moreRead less
Exploring the Fundamentals of Atomically Precise Manufacturing with Scanning Probe Microscopes. Over the past five years, Australian researchers have pioneered the development of a new method for fabricating electrical devices in silicon with atomic precision. By partnering with the world leader in nanotechnology manufacturing, these same researchers now have an opportunity to extend Australia's early lead in this area. The proposed research will lead to new capabilities for Australia within the ....Exploring the Fundamentals of Atomically Precise Manufacturing with Scanning Probe Microscopes. Over the past five years, Australian researchers have pioneered the development of a new method for fabricating electrical devices in silicon with atomic precision. By partnering with the world leader in nanotechnology manufacturing, these same researchers now have an opportunity to extend Australia's early lead in this area. The proposed research will lead to new capabilities for Australia within the growing field of electro-mechanical devices. It will strengthen and broaden Australia's leadership in atomic-scale device fabrication in silicon. It will assist world-leading Australian researchers to evaluate and prioritise the commercial potential of their technologies.Read moreRead less
Three Dimensional Integrated Circuits. Pushing the boundaries of current silicon fabrication technology, this proposal will investigate the possibilities of new 3D architectures to ensure that Australia remains at the forefront of world-wide research into atomic-scale electronics. It creates an important link to the latest technologies in atomistic device modelling in the US, developed at Texas Instruments. More importantly, by anticipating the problems that electronic device manufacturers are c ....Three Dimensional Integrated Circuits. Pushing the boundaries of current silicon fabrication technology, this proposal will investigate the possibilities of new 3D architectures to ensure that Australia remains at the forefront of world-wide research into atomic-scale electronics. It creates an important link to the latest technologies in atomistic device modelling in the US, developed at Texas Instruments. More importantly, by anticipating the problems that electronic device manufacturers are currently facing, and will face over their long-term horizons, the proposed research also seeks to provide Australia with a chance to lift its involvement in the multi-trillion dollar global semiconductor industry.Read moreRead less
Atomic Electronics: Precompetitive Research for the Global Semiconductor Industry. The demonstration in Australia that electronic devices in silicon can be fabricated at the atomic-scale has provided a vision for global semiconductor manufacturers. By engaging with leading US companies to tackle the problems industry faces as it attempts to reach this scale, this Fellowship will ensure that Australia remains at the forefront of growing world-wide research into atomic-scale electronics. Equally ....Atomic Electronics: Precompetitive Research for the Global Semiconductor Industry. The demonstration in Australia that electronic devices in silicon can be fabricated at the atomic-scale has provided a vision for global semiconductor manufacturers. By engaging with leading US companies to tackle the problems industry faces as it attempts to reach this scale, this Fellowship will ensure that Australia remains at the forefront of growing world-wide research into atomic-scale electronics. Equally important, by anticipating the problems that electronic device manufacturers are currently facing, and will face over their long-term horizons, the proposed research seeks to provide Australia with a long-term opportunity to lift its involvement in the multi-trillion dollar global semiconductor industry.Read moreRead less
Insight and understanding in Rare-Earth magnetism. Today's technologically driven society relies on magnetic materials to an extent unimaginable even as recently as 20 years ago. Rare-earth transition-metal intermetallics are among the most important magnetic materials, providing the World's strongest magnet with extensive applications. Despite these impressive technological and commercial developments numerous aspects of rare-earth magnetism remain to be developed and resolved. The two innovati ....Insight and understanding in Rare-Earth magnetism. Today's technologically driven society relies on magnetic materials to an extent unimaginable even as recently as 20 years ago. Rare-earth transition-metal intermetallics are among the most important magnetic materials, providing the World's strongest magnet with extensive applications. Despite these impressive technological and commercial developments numerous aspects of rare-earth magnetism remain to be developed and resolved. The two innovative topics we shall research are the critical interplay between the rare-earth and transition-metal sublattices in ternary compounds, enabling us to understand complex compounds, and exploration of a set of quaternary compounds we have recently discovered, thus opening new areas of rare-earth magnetism.Read moreRead less
Towards Quantum Electromechanical Devices with Semiconductor Nanowires. More importantly, semiconductor nanowires and nanorods represent a novel nanosystem being intensely researched world wide for applications in high efficiency solar cells, ultra bright light emitting diodes, single photon emitters, fast post CMOS wrap-gate field effect transistors, high efficiency thermoelectric devices and chemical sensing. The current proposal thus helps to ensure Australias forefront involvement in this qu ....Towards Quantum Electromechanical Devices with Semiconductor Nanowires. More importantly, semiconductor nanowires and nanorods represent a novel nanosystem being intensely researched world wide for applications in high efficiency solar cells, ultra bright light emitting diodes, single photon emitters, fast post CMOS wrap-gate field effect transistors, high efficiency thermoelectric devices and chemical sensing. The current proposal thus helps to ensure Australias forefront involvement in this quickly evolving and highly promising research field.Read moreRead less