Investigating Near-Threshold Atomic and Molecular Collision Processes with Multiparameter Detection Techniques. We are proposing to perform state-of-the-art, electron impact excitation and ionization measurements on a range of atoms and molecules. The combination of new detector technology and innovative experimental design will enable measurements of near-threshold excitation and ionization in a number of important atomic and molecular systems. The measurements will have implications for the ....Investigating Near-Threshold Atomic and Molecular Collision Processes with Multiparameter Detection Techniques. We are proposing to perform state-of-the-art, electron impact excitation and ionization measurements on a range of atoms and molecules. The combination of new detector technology and innovative experimental design will enable measurements of near-threshold excitation and ionization in a number of important atomic and molecular systems. The measurements will have implications for the further development of atomic scattering theory, particularly the role of electron-electron correlations, and provide much needed absolute scattering information on the excitation of molecules which are of relevance to our atmosphere and various technological devices.Read moreRead less
Electronic and atomic collision theory. Recently there has been rapid progress in the field of electronic and atomic collisions. Consequently, many new problems have emerged of interest to science and industry. The proposed collaboration will determine the most promising theoretical techniques for their solution. The problems include, for example, electron
collisions with noble gases, cesium and mercury, of interest to the laser, lighting and plasma processing industries. Time-dependent and tim ....Electronic and atomic collision theory. Recently there has been rapid progress in the field of electronic and atomic collisions. Consequently, many new problems have emerged of interest to science and industry. The proposed collaboration will determine the most promising theoretical techniques for their solution. The problems include, for example, electron
collisions with noble gases, cesium and mercury, of interest to the laser, lighting and plasma processing industries. Time-dependent and time independent, relativistic and non-relativistic approaches will be considered, thereby determining the direction of the field for the foreseeable future.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
Studying Molecular Dynamics with Electron and Laser Interactions. We plan to use state-of-the-art experimental techniques and methodologies to probe the dynamics of molecular processes stimulated by either laser or electron interactions. These processes are fundamental to our understanding of both natural phenomena and many devices used in the technology of today and of the future. As a result of this study our insight into the mechanisms underpining these phenomena and devices will be enhanced.
Fermionic superfluidity in lower dimensional quantum gases. This project seeks to carry out cutting edge research on fermionic superfluidity using ultracold quantum gases. Through collaboration with one of the world's leading groups we will investigate the emerging issue of superfluidity in two-dimensional environments. This research will forge strong links with the European community and raise Australia's international profile in this rapidly growing field. Outstanding opportunities for youn ....Fermionic superfluidity in lower dimensional quantum gases. This project seeks to carry out cutting edge research on fermionic superfluidity using ultracold quantum gases. Through collaboration with one of the world's leading groups we will investigate the emerging issue of superfluidity in two-dimensional environments. This research will forge strong links with the European community and raise Australia's international profile in this rapidly growing field. Outstanding opportunities for young Australian scientists will arise through this collaboration and our findings may have implications for future superconducting technologies, based on the remarkable properties of fermionic superfluids.Read moreRead less
Collision data for lighting industry and plasma modeling. The project's primary aim is to progress the design of more efficient
and environmentally friendly light sources. Given the number of light
sources in use worldwide even a small improvement in the efficiency
could lead to enormous benefits to society via reduction of energy
consumption. Design of new mercury-free light sources will eliminate a
major neuro-toxin pollution source. Collaboration with research groups
at the OSRAM-SYLVA ....Collision data for lighting industry and plasma modeling. The project's primary aim is to progress the design of more efficient
and environmentally friendly light sources. Given the number of light
sources in use worldwide even a small improvement in the efficiency
could lead to enormous benefits to society via reduction of energy
consumption. Design of new mercury-free light sources will eliminate a
major neuro-toxin pollution source. Collaboration with research groups
at the OSRAM-SYLVANIA Corporation (USA) and Sheffield University (UK)
will herald the beginning of industrial application for our successful
atomic collisions research program. The previous substantial ARC
investment towards this fundamental science program has now enabled
practical application.Read moreRead less
Nonlinear dynamics and chaos in Bose-Einstein Condensates on atom chips. The field of Bose-Einstein condensation (BEC) has recently seen some remarkable achievements. Researchers are now able to produce and
manipulate BECs in magnetic microtraps formed by current carrying wires patterned onto a substrate (atom chip). This project extends work in this field to the investigation of physics at the quantum/classical boundary through the study of the dynamics of BECs on atom chips. By probing a no ....Nonlinear dynamics and chaos in Bose-Einstein Condensates on atom chips. The field of Bose-Einstein condensation (BEC) has recently seen some remarkable achievements. Researchers are now able to produce and
manipulate BECs in magnetic microtraps formed by current carrying wires patterned onto a substrate (atom chip). This project extends work in this field to the investigation of physics at the quantum/classical boundary through the study of the dynamics of BECs on atom chips. By probing a nonlinear system with a BEC we will examine how the quantum mechanics affects classically chaotic dynamics. We will also examine the classically forbidden phenomena of dynamical tunnelling and localisation.Read moreRead less
Positron processes - From Basic to Applied Science. Australian scientists are at the forefront of international activities in atomic and molecular physics and materials science research. This program will expand the level of expertise in an emerging field that has importance in both these areas - the use of positron beams. Australia is developing a new and exciting capacity for positron research through the National Positron Beamline Facility. Scientists in this collaboration will work with o ....Positron processes - From Basic to Applied Science. Australian scientists are at the forefront of international activities in atomic and molecular physics and materials science research. This program will expand the level of expertise in an emerging field that has importance in both these areas - the use of positron beams. Australia is developing a new and exciting capacity for positron research through the National Positron Beamline Facility. Scientists in this collaboration will work with other outstanding, international research groups in the field of positron studies to stimulate new directions for their research. The international links, and the novel capabilities of the new Australian Facility, will enable our researchers to fully exploit this new field of research.Read moreRead less
Environmental and Technological Applications of Electron-Driven Processes. We plan to use state-of-the-art experimental techniques and methodologies for the measurement of collision cross sections and reaction rates for low energy electron-driven process in molecules and molecular radicals. These processes are fundamental to our understanding of our environment and many devices used in the technology of today and of the future. In particular we will provide accurate cross sections for NOx and SO ....Environmental and Technological Applications of Electron-Driven Processes. We plan to use state-of-the-art experimental techniques and methodologies for the measurement of collision cross sections and reaction rates for low energy electron-driven process in molecules and molecular radicals. These processes are fundamental to our understanding of our environment and many devices used in the technology of today and of the future. In particular we will provide accurate cross sections for NOx and SOx pollutants and H2O, as well for molecules such as C4F8, and its radicals such as CF2, which are used extensively in plasma processing technologies.Read moreRead less
Superfluidity in strongly correlated ultra-cold atomic Fermi gases. Ultra-cold atoms are one of the most rapidly developing areas in twenty-first century physics. The scientific importance of studying strongly interacting Fermi gases is indicated by the fact that five Nobel prizes in physics were awarded in fields relevant to ultra-cold atoms in the last decade. Australia is now developing a reputation for world-class research in this new area, with new ultra-cold fermion experiments now underwa ....Superfluidity in strongly correlated ultra-cold atomic Fermi gases. Ultra-cold atoms are one of the most rapidly developing areas in twenty-first century physics. The scientific importance of studying strongly interacting Fermi gases is indicated by the fact that five Nobel prizes in physics were awarded in fields relevant to ultra-cold atoms in the last decade. Australia is now developing a reputation for world-class research in this new area, with new ultra-cold fermion experiments now underway in Melbourne. This project will build national and international cooperation in this field, provide world-class research training opportunities and advance Australia's leadership position. As well as improving scientific understanding, it has the potential to lead to new energy-saving technologies in the future.Read moreRead less