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
Ultracold atomic Fermi gases in the strongly interacting regime: A new frontier of quantum many-body physics. 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 have been 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 ....Ultracold atomic Fermi gases in the strongly interacting regime: A new frontier of quantum many-body physics. 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 have been 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 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 future.Read moreRead less
Imbalanced superfluidity: The quantum mystery that defies solution. The project focuses on ground-breaking research in ultra-cold atomic Fermi gases, the fastest developing area in twenty-first century physics. Australia has already invested heavily in ultra-cold atomic Bose gases including atom lasers. An experimental program on atomic Fermi gases has also been initiated in the ARC Centre of Excellence for Quantum-Atom Optics (ACQAO). Our project, if successful, will help elevate Australia to a ....Imbalanced superfluidity: The quantum mystery that defies solution. The project focuses on ground-breaking research in ultra-cold atomic Fermi gases, the fastest developing area in twenty-first century physics. Australia has already invested heavily in ultra-cold atomic Bose gases including atom lasers. An experimental program on atomic Fermi gases has also been initiated in the ARC Centre of Excellence for Quantum-Atom Optics (ACQAO). Our project, if successful, will help elevate Australia to a major international research centre in cold Fermi gases, complementing its ongoing strength developed through the ACQAO experiments, and will bring fundamental knowledge that could have a significant and profound influence upon future technologies: for example, novel electronics, lossless power transmission and magnetic levitation.Read moreRead less
Quantum magnetometry on the microscale. This proposal will create a microscope for magnetic fields by measuring the quantum spin of a Bose-Einstein condensate at temperatures near absolute zero. Classical measurements of spin have underpinned transforming technologies, from magnetic resonance imaging to terabyte-scale hard-disc storage. We will make a truly quantum measurement of spin which will create a magnetic field microscope one million times more sensitive than the current state-of-the-art ....Quantum magnetometry on the microscale. This proposal will create a microscope for magnetic fields by measuring the quantum spin of a Bose-Einstein condensate at temperatures near absolute zero. Classical measurements of spin have underpinned transforming technologies, from magnetic resonance imaging to terabyte-scale hard-disc storage. We will make a truly quantum measurement of spin which will create a magnetic field microscope one million times more sensitive than the current state-of-the-art. The magnetic field microscope will be sensitive enough to measure fields from single biological cells and from superconducting nanosurfaces, giving critical new perspectives in biomedical research and next-generation electronics.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0560959
Funder
Australian Research Council
Funding Amount
$165,000.00
Summary
The Macquarie National Low Temperature Optoelectronic Thin Film Growth Facility. Funding is requested for an Australian facility for the growth of nitride and oxide thin films with in-situ optical analysis equipment for the monitoring of growth parameters. It is envisaged that this facility would be for the development of materials and device structures for photonic, electronic and optoelectronic applications. The facility will also provide a leading Australian source of these materials for fund ....The Macquarie National Low Temperature Optoelectronic Thin Film Growth Facility. Funding is requested for an Australian facility for the growth of nitride and oxide thin films with in-situ optical analysis equipment for the monitoring of growth parameters. It is envisaged that this facility would be for the development of materials and device structures for photonic, electronic and optoelectronic applications. The facility will also provide a leading Australian source of these materials for fundamental material studies utilising nuclear analysis and implantation technologies, high resolution X-ray diffraction, high spatial resolution micro-cathodoluminescence and other forms of analysis. Ex-situ optical analysis equipment is also requested for post-growth evaluation to compliment and evaluate the in-situ analysis.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210101093
Funder
Australian Research Council
Funding Amount
$439,587.00
Summary
Development and application of super-sensitive spinning quantum sensors. This project aims to use physical rotation of diamonds on timescales faster than quantum decoherence to set new detection limits for precision quantum sensing of electric and magnetic fields. This potentially allows us to see for the first time how the Coriolis force acts on current flowing in a frame rotating 700,000,000 times faster than the earth. The project's expected outcomes are electro-magnetic sensors with unpreced ....Development and application of super-sensitive spinning quantum sensors. This project aims to use physical rotation of diamonds on timescales faster than quantum decoherence to set new detection limits for precision quantum sensing of electric and magnetic fields. This potentially allows us to see for the first time how the Coriolis force acts on current flowing in a frame rotating 700,000,000 times faster than the earth. The project's expected outcomes are electro-magnetic sensors with unprecedented sensitivity that could find application in areas ranging from detecting household wiring to locating magnetic anomalies for defence. These outcomes should fill a blind spot of quantum magnetometry, have commercial impact and expand our knowledge of quantum physics in the rotating frame.Read moreRead less
Dynamics and correlations of many-body systems. The proposed program will greatly enhance Australian science through linking innovative
theoretical techniques with the successful ongoing Australian experimental program in atom
lasers, atom chip interferometry and ultra-cold fermions. Pioneering theoretical methods in
quantum phase-space are internationally recognized, and will be extended into new areas relevant
to Australia. These have fundamental significance to fields ranging from nanotec ....Dynamics and correlations of many-body systems. The proposed program will greatly enhance Australian science through linking innovative
theoretical techniques with the successful ongoing Australian experimental program in atom
lasers, atom chip interferometry and ultra-cold fermions. Pioneering theoretical methods in
quantum phase-space are internationally recognized, and will be extended into new areas relevant
to Australia. These have fundamental significance to fields ranging from nanotechnology to
astrophysics, as well as providing a route to improved atomic clocks and other instruments.
Combining these theoretical and computational methods from the physical sciences with biology
and genetics will provide future cross-disciplinary benefits to Australian biomedical science.Read moreRead less
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