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
Many-body physics with atomic Bose gases. Interdisciplinary research in science is promising new and revolutionary developments that may ultimately impact our daily lives. One such area, where the blurring of the boundaries between two disciplines could result in significant advancement of understanding and development of novel technologies, is the overlap of condensed matter or solid-state physics with atomic physics. This proposal seeks to put Australian science at the forefront of this new an ....Many-body physics with atomic Bose gases. Interdisciplinary research in science is promising new and revolutionary developments that may ultimately impact our daily lives. One such area, where the blurring of the boundaries between two disciplines could result in significant advancement of understanding and development of novel technologies, is the overlap of condensed matter or solid-state physics with atomic physics. This proposal seeks to put Australian science at the forefront of this new and exciting area of research. As a result, Australia will have a significant international presence, researchers will receive the cutting edge training necessary to be competitive with other countries and Australia will be poised to exploit the potentially beneficial developments.Read moreRead less
In and beyond the standard model of particle physics. The standard model of particle physics was developed twenty years ago, and it has been remarkably successful at describing the experiments carried out since then. Now, however there is evidence that there is physics beyond the standard model, and new and planned experiments will make the details of this new physics clearer in the lifetime of this grant. We will study a wide variety of systems, from the foundations of quantum mechanics to ....In and beyond the standard model of particle physics. The standard model of particle physics was developed twenty years ago, and it has been remarkably successful at describing the experiments carried out since then. Now, however there is evidence that there is physics beyond the standard model, and new and planned experiments will make the details of this new physics clearer in the lifetime of this grant. We will study a wide variety of systems, from the foundations of quantum mechanics to extra dimensions of space-time and much between and will find guides to the nature of the new physics.
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The New Dimensions of the Quantum Universe. This Fellowship will help build and strengthen significant world-class research capacity at the frontier of fundamental science. More students will be motivated to pursue careers in science, increasing the number of talented, world-class science graduates in Australia. It will forge strong research links both locally and internationally so as to enhance existing networks and create new ones. It will greatly enhance Australia's standing in particle phys ....The New Dimensions of the Quantum Universe. This Fellowship will help build and strengthen significant world-class research capacity at the frontier of fundamental science. More students will be motivated to pursue careers in science, increasing the number of talented, world-class science graduates in Australia. It will forge strong research links both locally and internationally so as to enhance existing networks and create new ones. It will greatly enhance Australia's standing in particle physics, the epitome of Big Science, and garner new respect from one of the world's most influential scientific communities. Having this kind of world-class research in Australia, will also help foster public education and advance the public understanding of fundamental science.
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Branes and unification. This project will explore theories which hypothesis that our universe is a 3-dimensional mem-(brane) residing in higher dimensional space. We will construct completely realistic theories and find ways to test them experimentally. This project is at the forefront of international developments in our understanding of the universe - an area that has grown in importance following the construction of the Large Hadron Collider at the European Giant accelerator laboraroty. The p ....Branes and unification. This project will explore theories which hypothesis that our universe is a 3-dimensional mem-(brane) residing in higher dimensional space. We will construct completely realistic theories and find ways to test them experimentally. This project is at the forefront of international developments in our understanding of the universe - an area that has grown in importance following the construction of the Large Hadron Collider at the European Giant accelerator laboraroty. The project will expose postgraduate students to exciting developments in this fascinating field pf physics.Read moreRead less
Particle physics and cosmology of neutrinos. Neutrinos are a particularly interesting class of elementary particle. The Standard Model of particle physics sees neutrinos as having exactly zero mass. However, recent experimental data have all but demonstrated that massless neutrinos are inconsistent with observations. If neutrinos have mass, then quantum mechanics allows them to oscillate between the different neutrino types as they propagate through space. Nonzero neutrino masses and the associa ....Particle physics and cosmology of neutrinos. Neutrinos are a particularly interesting class of elementary particle. The Standard Model of particle physics sees neutrinos as having exactly zero mass. However, recent experimental data have all but demonstrated that massless neutrinos are inconsistent with observations. If neutrinos have mass, then quantum mechanics allows them to oscillate between the different neutrino types as they propagate through space. Nonzero neutrino masses and the associated oscillations lead to important new physics in the elementary particle domain and in cosmology. This project will explore the implications of neutrino oscillations in diverse areas in particle physics and cosmology.Read moreRead less
The Origin of Mass at the Large Hadron Collider. The Large Hadron Collider is an enormous worldwide effort to understand the building blocks of the Universe. This project will help strengthen world-class research capacity in one of the most exciting frontiers of basic research. It will excite more high-achieving students to pursue careers in science increasing the number of talented graduates in Australia. In addition the big fundamental questions addressed in this research are of great fascin ....The Origin of Mass at the Large Hadron Collider. The Large Hadron Collider is an enormous worldwide effort to understand the building blocks of the Universe. This project will help strengthen world-class research capacity in one of the most exciting frontiers of basic research. It will excite more high-achieving students to pursue careers in science increasing the number of talented graduates in Australia. In addition the big fundamental questions addressed in this research are of great fascination to the general public and will help to further advance the public education of science.Read moreRead less
Origin of the Mass. A hundred metres below ground, under the French-Swiss border, scientists are preparing to travel back in time to study matter as it was in the first fractions of a second after the beginning of the Universe. They are building the world's largest scientific instrument to help reveal how this primordial matter developed into the building blocks that form the great diversity of today. Australian physicists are preparing to extract the few fundamental particles that will explain ....Origin of the Mass. A hundred metres below ground, under the French-Swiss border, scientists are preparing to travel back in time to study matter as it was in the first fractions of a second after the beginning of the Universe. They are building the world's largest scientific instrument to help reveal how this primordial matter developed into the building blocks that form the great diversity of today. Australian physicists are preparing to extract the few fundamental particles that will explain the origin of the mass from the debris of billions of proton collisions. While solving the major issue confronting particle physics today, we will train students who will subsequently apply their skills in fields as diverse as science, medicine, industry and finance.Read moreRead less
Predictions of nucleon-nucleus cross sections for all energies to 300 MeV based upon microscopic theories of N-A scattering. Cross sections from nucleon-nucleus scattering and reactions are central quantities of import in diverse fields of study. They are most important in evaluations for nucleon radiation therapy, in material science for radiation safety as well as damage to electronics, with use of accelerator technology for waste management as well as possible power generation. They are im ....Predictions of nucleon-nucleus cross sections for all energies to 300 MeV based upon microscopic theories of N-A scattering. Cross sections from nucleon-nucleus scattering and reactions are central quantities of import in diverse fields of study. They are most important in evaluations for nucleon radiation therapy, in material science for radiation safety as well as damage to electronics, with use of accelerator technology for waste management as well as possible power generation. They are important in fundamental physics problems as in nuclear astrophysics and in studies of radioactive nuclear ions. A theoretical framework is required to make reliable predictions of nucleon-nucleus scattering. This project seeks to establish predictive methods of analysis for all nucleon energies to 300 MeV. Read moreRead less