Developing and exploiting a beam of exotic neutron halo nuclei: probing quantum coherence and decoherence at the femtoscale. Developing an Australian rare isotope beam capability with unique features will be a breakthrough in Australia's capability in science. It will create new opportunities for local research with radioactive isotope beams, a field being vigorously developed world-wide, as new access to short-lived radioactive isotopes will open up many opportunities in fundamental research an ....Developing and exploiting a beam of exotic neutron halo nuclei: probing quantum coherence and decoherence at the femtoscale. Developing an Australian rare isotope beam capability with unique features will be a breakthrough in Australia's capability in science. It will create new opportunities for local research with radioactive isotope beams, a field being vigorously developed world-wide, as new access to short-lived radioactive isotopes will open up many opportunities in fundamental research and applications. The experience and strong international linkages from this project will facilitate the longer-term use of future large-scale international facilities. This project will also build links with other areas of research strength in Australia, and keep us at the cutting-edge in research and training in nuclear science, a matter of national importance.Read moreRead less
Breakup and Fusion of Stable and Radioactive Nuclei. All Research Priority areas use tools based on nuclear physics research. Further advances will come from new A$1bn accelerators of radioactive nuclei. Exploiting our new ideas, we will develop a unified framework allowing prediction of the products of nuclear reactions with stable and radioactive nuclei, giving a better understanding of the fundamental process of nuclear fusion, and of radioactive beam applications. Early participation in a si ....Breakup and Fusion of Stable and Radioactive Nuclei. All Research Priority areas use tools based on nuclear physics research. Further advances will come from new A$1bn accelerators of radioactive nuclei. Exploiting our new ideas, we will develop a unified framework allowing prediction of the products of nuclear reactions with stable and radioactive nuclei, giving a better understanding of the fundamental process of nuclear fusion, and of radioactive beam applications. Early participation in a significant new area of research will strengthen Australia's capacity to exploit future opportunities with these accelerators. Top-level research training in nuclear physics, a subject with strategic implications for Australia, will help in the forthcoming international shortage of nuclear experts. Read moreRead less
Multiple atomic photoionization in superstrong electromagnetic field. Correlation, or entanglement, of electrons in matter governs many important phenomena in nature, such as chemical reactions, superconductivity and ferromagnetism. However, it is the many-electron processes in atoms which allow the study of electron correlations most clearly. In this project we will investigate such a process of two-electron atomic photoionization by an intense laser pulse. We will combine advanced theoretical ....Multiple atomic photoionization in superstrong electromagnetic field. Correlation, or entanglement, of electrons in matter governs many important phenomena in nature, such as chemical reactions, superconductivity and ferromagnetism. However, it is the many-electron processes in atoms which allow the study of electron correlations most clearly. In this project we will investigate such a process of two-electron atomic photoionization by an intense laser pulse. We will combine advanced theoretical and experimental tools with the aim of understanding how the electron correlation interplays with the superstrong electromagnetic field. This will provide insight into fundamental processes of interaction of intense laser pulses with matter which are important in a wide range of applications.Read moreRead less
Multiple ionization of atoms and molecules in strong laser fields. Our research contributes to multidisciplinary efforts to unravel the
fundamental mechanisms that govern interaction of intense laser
radiation with matter. Understanding and accurate numerical modelling
of such preocesses have far-reaching implications for astrophysics,
plasma physics and controlled fusion, life and materials sciences. The
research project will further enhance our reputation in an area where
Australian the ....Multiple ionization of atoms and molecules in strong laser fields. Our research contributes to multidisciplinary efforts to unravel the
fundamental mechanisms that govern interaction of intense laser
radiation with matter. Understanding and accurate numerical modelling
of such preocesses have far-reaching implications for astrophysics,
plasma physics and controlled fusion, life and materials sciences. The
research project will further enhance our reputation in an area where
Australian theorists are preeminent, and the research training will
produce PhD graduates with a high-level ability in numerical modelling
using supercomputers. Such skills are essential in many defense,
information and nano-technology applications of national priority.
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Two-electron atomic photoionization in superstrong electromagnetic field. Correlation, or entanglement, of electrons in matter governs many important phenomena in nature, such as chemical reactions, superconductivity and ferromagnetism. However, it is the many-electron processes in atoms which allow the study of electron correlations most clearly. In this project we will investigate such a process of two-electron atomic photoionization by an intense laser pulse. We will combine advanced theoret ....Two-electron atomic photoionization in superstrong electromagnetic field. Correlation, or entanglement, of electrons in matter governs many important phenomena in nature, such as chemical reactions, superconductivity and ferromagnetism. However, it is the many-electron processes in atoms which allow the study of electron correlations most clearly. In this project we will investigate such a process of two-electron atomic photoionization by an intense laser pulse. We will combine advanced theoretical and experimental tools with the aim of understanding how the electron correlation interplays with the
superstrong electromagnetic field. This will provide insight into fundamental processes of interaction of intense laser pulses with matter which are important in a wide range of applications.
Read moreRead less
Atomic Ionization on the Attosecond Time Scale. Electrons emit light, carry electric current, and bind atoms together to form molecules. Insight into their atomic-scale motion is the key to understanding the functioning of biological systems, developing efficient sources of x-ray light, and speeding up electronics. Capturing this electron motion requires attosecond (one quintillionth of a second) time resolution. Our research aims to understand and accurately model fundamental atomic processes ....Atomic Ionization on the Attosecond Time Scale. Electrons emit light, carry electric current, and bind atoms together to form molecules. Insight into their atomic-scale motion is the key to understanding the functioning of biological systems, developing efficient sources of x-ray light, and speeding up electronics. Capturing this electron motion requires attosecond (one quintillionth of a second) time resolution. Our research aims to understand and accurately model fundamental atomic processes taking place on the attosecond time scale. This research project will further enhance our reputation in an area where Australian theorists are preeminent, and the research training will produce PhD graduates with the skills essential in a multitude of nano-technology applications. Read moreRead less
Dynamics of Nuclear Fusion: Evolution Through a Complex Multi-Dimensional Landscape. The key questions in the fusion of heavy nuclei form an interlocking puzzle, which can be resolved using our recently developed analysis concepts and measurement techniques. The newly completed, unique, and highly efficient superconducting fusion product separator, together with Australian's Heavy Ion Accelerator, will be used to unlock the puzzle and reveal how fusing nuclei evolve in a multi-dimensional landsc ....Dynamics of Nuclear Fusion: Evolution Through a Complex Multi-Dimensional Landscape. The key questions in the fusion of heavy nuclei form an interlocking puzzle, which can be resolved using our recently developed analysis concepts and measurement techniques. The newly completed, unique, and highly efficient superconducting fusion product separator, together with Australian's Heavy Ion Accelerator, will be used to unlock the puzzle and reveal how fusing nuclei evolve in a multi-dimensional landscape. This will impact on the emerging fields of superheavy element formation, physics with rare isotope beams, and on coupling-assisted quantum tunnelling. This project will maintain Australia's world-leading position in the current race to develop a quantitative understanding of fusion.
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Dynamics of multi-component matter waves. The recent observation of Bose-Einstein condensation (BEC) in weakly interacting ultracold gases has opened the door to the field of coherent matter-wave optics. When the BEC is treated within a mean-field approach the equations resemble those for the propagation of light in nonlinear media. The main aim of this project is to bring our broad and deep nonlinear optical expertise to bare on the classical nonlinear dynamics of multi-component BEC like syste ....Dynamics of multi-component matter waves. The recent observation of Bose-Einstein condensation (BEC) in weakly interacting ultracold gases has opened the door to the field of coherent matter-wave optics. When the BEC is treated within a mean-field approach the equations resemble those for the propagation of light in nonlinear media. The main aim of this project is to bring our broad and deep nonlinear optical expertise to bare on the classical nonlinear dynamics of multi-component BEC like systems. The expected outcome is a position of world leadership in the theoretical understanding of the dynamics of atom lasers, mixed atom-molecule BECs, and fragmented BECs in optical lattices.Read moreRead less
Quantum Simulations with Dilute Gas Bose Einstein Condensates. Fundamental scientific research, such as we propose, is an important contributor to the long term wealth and well being of the Nation. It shapes our culture, our ways of thinking, and our beliefs. It also contributes directly, and in the shorter term, through the technology development that accompanies scientific research at the frontiers of knowledge. The students participating in this research will develop skills in innovation, int ....Quantum Simulations with Dilute Gas Bose Einstein Condensates. Fundamental scientific research, such as we propose, is an important contributor to the long term wealth and well being of the Nation. It shapes our culture, our ways of thinking, and our beliefs. It also contributes directly, and in the shorter term, through the technology development that accompanies scientific research at the frontiers of knowledge. The students participating in this research will develop skills in innovation, intellectual property management, and commercialisation - all of which are critical to the Nation's future.Read moreRead less
Australian Centre for Quantum-Atom Optics. The Centre will combine pre-eminent Australian theoretical and experimental research groups in quantum and atom optics to create a powerful network to advance the rapidly developing field of Quantum-Atom Optics. We will exploit the quantum nature of multiple particle quantum states of atoms and photons including entangled light and Bose-Einstein condensates. The Centre will focus on fundamental research, but our long term goal is to underpin and develo ....Australian Centre for Quantum-Atom Optics. The Centre will combine pre-eminent Australian theoretical and experimental research groups in quantum and atom optics to create a powerful network to advance the rapidly developing field of Quantum-Atom Optics. We will exploit the quantum nature of multiple particle quantum states of atoms and photons including entangled light and Bose-Einstein condensates. The Centre will focus on fundamental research, but our long term goal is to underpin and develop the next generation quantum technology. We aim to build a quantum toolbox to enable applications such as the transfer and storage of information for photonics, and precision quantum control of atoms for enhanced atom interferometry.Read moreRead less