Solid Light: Frontiers and applications of solid-state Cavity Quantum Electro-Dynamics. Our understanding of quantum mechanics directly fuels new technology. We are on the verge of a new revolution in technology, where the aspects of quantum physics that we haven't been able to understand are now within technological reach. Our concept of solid-light joins two of the most important branches of physics, and in so doing develops a new technology of diamond-based quantum processors that will be b ....Solid Light: Frontiers and applications of solid-state Cavity Quantum Electro-Dynamics. Our understanding of quantum mechanics directly fuels new technology. We are on the verge of a new revolution in technology, where the aspects of quantum physics that we haven't been able to understand are now within technological reach. Our concept of solid-light joins two of the most important branches of physics, and in so doing develops a new technology of diamond-based quantum processors that will be built in Australia. This will benefit the Australian scientific community by providing devices to solve important quantum problems, and benefit the wider community by growing a new industry based around diamond quantum nanoscience.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0668398
Funder
Australian Research Council
Funding Amount
$177,900.00
Summary
Advanced Microwave Facility for Quantum-Atom Optics. Atoms can be controlled using light in visible and infra-red regions, as well as electromagnetic waves of longer wavelength in the microwave (MW) and radiofrequency (RF) part of the spectrum. We presently use optical radiation to control atoms at the quantum level where they can behave like waves and can interact with light to store and manipulate information. The MW and RF facility will extend our abilities and enable more complete control of ....Advanced Microwave Facility for Quantum-Atom Optics. Atoms can be controlled using light in visible and infra-red regions, as well as electromagnetic waves of longer wavelength in the microwave (MW) and radiofrequency (RF) part of the spectrum. We presently use optical radiation to control atoms at the quantum level where they can behave like waves and can interact with light to store and manipulate information. The MW and RF facility will extend our abilities and enable more complete control of the atoms, which will help us develop the first generation quantum technology. This will enable the creation of quantum devices such as atom lasers, atom interferometers and quantum information networks for communication and ultra-sensitive measurement applications.Read moreRead less
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
Quantum correlations in ultra-cold Fermi gases. The field of ultra-cold Fermi gases provides a unique opportunity to develop and test theoretical methods for novel experimental environments of exceptional purity and simplicity. This improved understanding will have potential applications in many fields, ranging from the astrophysics of neutron stars to condensed matter systems such as superconductors or nanostructures. Just as importantly, the project will develop linkages with world leading the ....Quantum correlations in ultra-cold Fermi gases. The field of ultra-cold Fermi gases provides a unique opportunity to develop and test theoretical methods for novel experimental environments of exceptional purity and simplicity. This improved understanding will have potential applications in many fields, ranging from the astrophysics of neutron stars to condensed matter systems such as superconductors or nanostructures. Just as importantly, the project will develop linkages with world leading theoretical groups, which will greatly aid research student education. There are direct applications to experiments on molecule formation with ultra-cold fermions in the ARC Centre of Excellence for Quantum-Atom Optics.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0882580
Funder
Australian Research Council
Funding Amount
$400,000.00
Summary
Laser facility for quantum optics, imaging, and fabrication. The laser facility will play a role in advancing high-profile leading-edge Australian research underpinning a diverse range of technologies, from quantum communications and quantum computing, to biomedical imaging, fibre sensing and nanofabrication.
Quantum and classical imaging with light and atoms. Powerful new methods will be developed to extract greater information from optical and quantum imaging systems. These methods will be applied to important problems in biomedical and industrial optical and x-ray imaging and to experiments which test the foundations of quantum physics. Our work will help maintain Australia's strong international profile in optics and in optical imaging, while providing a professional and broad training environm ....Quantum and classical imaging with light and atoms. Powerful new methods will be developed to extract greater information from optical and quantum imaging systems. These methods will be applied to important problems in biomedical and industrial optical and x-ray imaging and to experiments which test the foundations of quantum physics. Our work will help maintain Australia's strong international profile in optics and in optical imaging, while providing a professional and broad training environment for our best and brightest graduate students.Read moreRead less
Understanding Collisions of Cold Polar Molecules. This project is in a high impact research field and therefore has several immediate and substantial national benefits. First, this project will directly raise the quality of Australian science in ultracold atomic physics, cold polar molecules physics, and quantum chemistry. Second, it will constitute high impact research from an Australian institute which will raise the recognition of the high quality Australian science. Third, it will further ....Understanding Collisions of Cold Polar Molecules. This project is in a high impact research field and therefore has several immediate and substantial national benefits. First, this project will directly raise the quality of Australian science in ultracold atomic physics, cold polar molecules physics, and quantum chemistry. Second, it will constitute high impact research from an Australian institute which will raise the recognition of the high quality Australian science. Third, it will further develop capabilities of the ARC Centre of Excellence for Quantum-Atom Optics (ACQAO). Fourth, this work will start high calibre international collaborations, most notably with a world renowned experimental group at Yale University among others.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
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