Magnetic ground state and dynamics in high temperature superconductors. This project is aimed at studies of novel advanced materials. It will contribute to research at the leading edge of fundamental physics. This is an international project that incorporates collaboration with two leading German experimental groups. This raises the profile of the project internationally. This collaboration may bring some experiments of overseas scientists to ANSTO OPAL reactor and hence facilitate interactions ....Magnetic ground state and dynamics in high temperature superconductors. This project is aimed at studies of novel advanced materials. It will contribute to research at the leading edge of fundamental physics. This is an international project that incorporates collaboration with two leading German experimental groups. This raises the profile of the project internationally. This collaboration may bring some experiments of overseas scientists to ANSTO OPAL reactor and hence facilitate interactions between Australian and overseas experimental groups.Read moreRead less
Does High Temperature Superconductivity Reside in Plane or Charge Reservoir (CR) Oxygen, in YBa2Cu3O7 (YBC)? One of the outstanding problems in contemporary solid state physics concerns the mechanism of high temperature superconductivity (HTS). In particular, what binds charges that normally repel one another, into (Cooper) pairs? Closely related to this question is where the superconductivity resides in the material. We aim to answer the latter question in the much studied prototypical HTS YBa2 ....Does High Temperature Superconductivity Reside in Plane or Charge Reservoir (CR) Oxygen, in YBa2Cu3O7 (YBC)? One of the outstanding problems in contemporary solid state physics concerns the mechanism of high temperature superconductivity (HTS). In particular, what binds charges that normally repel one another, into (Cooper) pairs? Closely related to this question is where the superconductivity resides in the material. We aim to answer the latter question in the much studied prototypical HTS YBa2Cu3O7. In doing so we expect to demonstrate that phonons, widely believed not to play a role in HTS are in fact an important component in the HTS pairing mechanism.Read moreRead less
Theoretical studies of strongly correlated quantum states in novel condensed matter systems. Strongly correlated quantum electronic and magnetic systems represent one of the most active and exciting areas of condensed matter physics, and one that will continue to have a major bearing on technology. We will pursue an extensive program of research into many aspects of this field, using a variety of analytical and numerical methods, in many of which we are among the world leaders. The project will ....Theoretical studies of strongly correlated quantum states in novel condensed matter systems. Strongly correlated quantum electronic and magnetic systems represent one of the most active and exciting areas of condensed matter physics, and one that will continue to have a major bearing on technology. We will pursue an extensive program of research into many aspects of this field, using a variety of analytical and numerical methods, in many of which we are among the world leaders. The project will add significantly to understanding of the physics of quantum phase transitions, spin-liquids, novel superconductors, and other related phenomena, and of the properties of quantum lattice models.Read moreRead less
Interlayer magnetoresistance of strongly correlated electron materials. The continued rapid expansion of information and entertainment technology requires new materials and devices for information storage. State of the art computer and iPod memories utilise advanced materials composed of layers of atoms, recognised by the 2007 Nobel Prize in Physics. These materials have metallic properties quite unlike those of simple metals such as copper and brass. This research will lead to a greater underst ....Interlayer magnetoresistance of strongly correlated electron materials. The continued rapid expansion of information and entertainment technology requires new materials and devices for information storage. State of the art computer and iPod memories utilise advanced materials composed of layers of atoms, recognised by the 2007 Nobel Prize in Physics. These materials have metallic properties quite unlike those of simple metals such as copper and brass. This research will lead to a greater understanding of and ability to design the next generation of materials. Australia's capacity for research and development in this scientifically challenging and technologically important field will be enhanced by this project. Read moreRead less
The theory of interferometers in nano-scale electronics. Soon the electronic circuits in computer chips will be so small that new effects due to quantum phyiscs will become important.
The proposed research will provide a better understanding of a range of nano-scale electronic devices including electron interferometers based on quantum points contacts and quantum dots.
Sepcifically, a new understanding of quantum coherent phenomena
in nano-scale interferometers will offers a potential ap ....The theory of interferometers in nano-scale electronics. Soon the electronic circuits in computer chips will be so small that new effects due to quantum phyiscs will become important.
The proposed research will provide a better understanding of a range of nano-scale electronic devices including electron interferometers based on quantum points contacts and quantum dots.
Sepcifically, a new understanding of quantum coherent phenomena
in nano-scale interferometers will offers a potential application
to other quantum technologies important to the future
of computing.
Read moreRead less
Spin-dependent interactions: a fundamental basis for spin-electronics. This project will establish a comprehensive understanding of spin-dependent interactions and correlated behaviour of multi-electron systems that are responsible for spin-relaxation, spin transport and spin coherence in spin-electronic devices. Our approach is based on the spin-resolved two-electron coincidence spectroscopy that is inherently suited for studying electronic correlations. Systematic investigations of spin-depend ....Spin-dependent interactions: a fundamental basis for spin-electronics. This project will establish a comprehensive understanding of spin-dependent interactions and correlated behaviour of multi-electron systems that are responsible for spin-relaxation, spin transport and spin coherence in spin-electronic devices. Our approach is based on the spin-resolved two-electron coincidence spectroscopy that is inherently suited for studying electronic correlations. Systematic investigations of spin-dependent interactions in atoms, molecules and ultrathin films will increase understanding of magnetic (spin) properties of artificially structured materials with reduced dimensionality for the benefit of nanotechnology. This understanding will be used to design and control, at the quantum mechanical level, the building blocks of spin-electronic devices.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
Quantum states of matter: from spin liquids to superconductors. Condensed matter physics has produced the technologies and materials that fuelled the digital and communications revolution. The scientific importance of condensed matter physics is indicated by the fact that ten Nobel prizes have been awarded for work in this field since 1990. This proposal brings together world leading chemists, experimental physicists and theoretical physicists from Australia, USA and UK to work on highly interdi ....Quantum states of matter: from spin liquids to superconductors. Condensed matter physics has produced the technologies and materials that fuelled the digital and communications revolution. The scientific importance of condensed matter physics is indicated by the fact that ten Nobel prizes have been awarded for work in this field since 1990. This proposal brings together world leading chemists, experimental physicists and theoretical physicists from Australia, USA and UK to work on highly interdisciplinary projects designed to discover how quantum mechanics leads to the novel properties of chemically complex materials. Such materials will be of central importance to the technologies of the future such as computer memories and the superconducting magnets in hospital MRI machines.Read moreRead less
Strongly correlated electron models for organic superconductors. In conventional metals such as copper the interactions between the electrons do not qualitively change the behaviour of the material. However, over the last few decades many materials have been discovered whose behaviours are dominated by the interactions between electrons. These 'strongly correlated' materials include technologically important materials used in power distribution, catalysis and plastic display technologies. This p ....Strongly correlated electron models for organic superconductors. In conventional metals such as copper the interactions between the electrons do not qualitively change the behaviour of the material. However, over the last few decades many materials have been discovered whose behaviours are dominated by the interactions between electrons. These 'strongly correlated' materials include technologically important materials used in power distribution, catalysis and plastic display technologies. This project will combine theoretical and experimental methods from chemistry and physics in an effort to explain the novel behaviours seen in certain classes of organic strongly correlated materials. This understanding has the potential to impact future electronic devices and advanced materials.Read moreRead less
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