Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0453521
Funder
Australian Research Council
Funding Amount
$508,374.00
Summary
National Heavy Ion Accelerator. The principal objectives are to develop a facility to provide energetic heavy ions for basic science, applications and research training. This will be accomplished through an enhancement of a superconducting linear accelerator using innovative technology, and extension of the available beam species through improvements to a large electrostatic tandem accelerator. The facility provides research resources for a broad range of national and international users.
The Early History of Dark Energy. The national benefit will be the inclusion of Australian researchers (Glazebrook and his students/postdocs) in a major UK-Japanese international research project to study dark energy. This will be the successor to the highly successful WiggleZ project (on which Glazebrook is a designer and CI) using the much larger mirror of Subaru to push back the mapping of cosmic sound to much earlier epochs in the history of the Universe. Although Australia built parts of th ....The Early History of Dark Energy. The national benefit will be the inclusion of Australian researchers (Glazebrook and his students/postdocs) in a major UK-Japanese international research project to study dark energy. This will be the successor to the highly successful WiggleZ project (on which Glazebrook is a designer and CI) using the much larger mirror of Subaru to push back the mapping of cosmic sound to much earlier epochs in the history of the Universe. Although Australia built parts of the FMOS instrument (under contract) there is currently no national right of access to any of the science surveys so it is only by developing these collaborations that we can capitalize on our innovative instrument design.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0454184
Funder
Australian Research Council
Funding Amount
$155,792.00
Summary
Silicon Imaging Device Construction Facility - Wirebonder. The development of state-of-the-art, high precision semiconductor imaging devices (for high energy particle physics, synchrotron science and medical imaging ) requires a significant capability in modern assembly facilities. In constructing test and 'production' modules consisting of fine-grained, multi-channel bare silicon or other semiconductor imaging devices and custom electronic chips, a high-reliability, highly flexible wire-bonding ....Silicon Imaging Device Construction Facility - Wirebonder. The development of state-of-the-art, high precision semiconductor imaging devices (for high energy particle physics, synchrotron science and medical imaging ) requires a significant capability in modern assembly facilities. In constructing test and 'production' modules consisting of fine-grained, multi-channel bare silicon or other semiconductor imaging devices and custom electronic chips, a high-reliability, highly flexible wire-bonding machine is an essential tool. The international reputation from success in several challenging projects under difficult conditions, gained by the Chief Investigators has resulted in several more projects being planned in addition to a foreseen program of device development. A modern wirebonder, to replace the existing 30 year-old machine, has become critical to maintain our leading position in this area.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0882531
Funder
Australian Research Council
Funding Amount
$250,000.00
Summary
Quantum Limited Single Atom Detectors. The technology that has shaped our society, solid state diodes, transistors and computer chips is based on our ability to manipulate the average quantum properties of materials such as semiconductors. This physics has been well understood for decades. Many technologies that will shape our societies in this century will be based on our ability to manipulate quantum systems precisely, an area that is the focus of quantum atom optics. The detectors requested i ....Quantum Limited Single Atom Detectors. The technology that has shaped our society, solid state diodes, transistors and computer chips is based on our ability to manipulate the average quantum properties of materials such as semiconductors. This physics has been well understood for decades. Many technologies that will shape our societies in this century will be based on our ability to manipulate quantum systems precisely, an area that is the focus of quantum atom optics. The detectors requested in this proposal will ensure that Australia remains competitive in the technologies that will emerge from the new field of quantum atom optics.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
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
Development of a neutral helium beam microscope. This project would demonstrate Australia's capability in developing leading edge technologies applicable to the growing nanotechnology industry. The development of a neutral helium beam microscope brings into Australia expertise in the emerging field of molecular optics, and would place Australia as one of the first countries to make a commitment to this field. The project will develop a prototype instrument which is aimed at becoming a commercial ....Development of a neutral helium beam microscope. This project would demonstrate Australia's capability in developing leading edge technologies applicable to the growing nanotechnology industry. The development of a neutral helium beam microscope brings into Australia expertise in the emerging field of molecular optics, and would place Australia as one of the first countries to make a commitment to this field. The project will develop a prototype instrument which is aimed at becoming a commercially viable product - the neutral helium beam microscope. The possibilities of using the microscope system as a nanofabrication device would also give researchers in Australia the ability to fabricate structures that could not be manufactured anywhere else in the world.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
Critical Tests of Quantum Electro-Dynamics (QED) in heavy atomic systems. The 2005 Nobel prize was awarded for high-precision spectroscopy and a critical test of QED in light atomic systems. This led to dramatic applications to constants of nature and Quantum Optics. Our research has also developed state-of-the-art detector and spectrometer technology in pursuit of fundamental knowledge, but in the X-ray regime. We will make major progress for heavy atomic systems. Applications include the deve ....Critical Tests of Quantum Electro-Dynamics (QED) in heavy atomic systems. The 2005 Nobel prize was awarded for high-precision spectroscopy and a critical test of QED in light atomic systems. This led to dramatic applications to constants of nature and Quantum Optics. Our research has also developed state-of-the-art detector and spectrometer technology in pursuit of fundamental knowledge, but in the X-ray regime. We will make major progress for heavy atomic systems. Applications include the development of a few-electron calibration lamp, widely discussed as a new energy standard. These studies provide data, physical insights and highly skilled personnel for Australia's future in frontier technologies. Our fundamental research has led to two orders of magnitude improvement in mammographic diagnostic accuracy.Read moreRead less
The first critical tests of many-body and correlated Quantum Electro-Dynamics (QED) in medium-Z atomic systems. Major difficulties are being encountered in the computation of high-order and correlated terms of Quantum Electro-Dynamical effects in atoms. We will make the first measurements for medium-Z atoms critically sensitive to two-electron QED, and the first tests of QED in this region accurate to 1%. This accuracy will allow new insight into two-electron systems, theoretical approaches, and ....The first critical tests of many-body and correlated Quantum Electro-Dynamics (QED) in medium-Z atomic systems. Major difficulties are being encountered in the computation of high-order and correlated terms of Quantum Electro-Dynamical effects in atoms. We will make the first measurements for medium-Z atoms critically sensitive to two-electron QED, and the first tests of QED in this region accurate to 1%. This accuracy will allow new insight into two-electron systems, theoretical approaches, and recent observed discrepancies between QED theory and experiment. This proposal follows recent successful experimental work using new capabilities of Electron-Beam Ion Traps (EBITs). Our recent publications have proven that this novel approach can yield new insight into the interaction of light with matter.Read moreRead less