Advanced Magnetic Resonance Imaging at 7 Tesla: Resolving the fundamental radiofrequency field-tissue interaction problem at ultra-high field. Ultra-high-field Magnetic Resonance Imaging (MRI) systems offer the potential for faster, more accurate diagnostic imaging. However, current applications are limited by the fundamental challenge of strong interactions between the electromagnetic field and human tissues, which result in poor image quality and/or compromised patient safety. Using a novel, s ....Advanced Magnetic Resonance Imaging at 7 Tesla: Resolving the fundamental radiofrequency field-tissue interaction problem at ultra-high field. Ultra-high-field Magnetic Resonance Imaging (MRI) systems offer the potential for faster, more accurate diagnostic imaging. However, current applications are limited by the fundamental challenge of strong interactions between the electromagnetic field and human tissues, which result in poor image quality and/or compromised patient safety. Using a novel, subject-specific imaging approach, this research will design and develop an ultra-high-field radiofrequency technology capable of offering high-performance imaging without jeopardising patient safety. This research will lay the groundwork for the translation of ultra-high field MRI research into clinical practice, generating new capabilities for diagnostic technologies.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE150100078
Funder
Australian Research Council
Funding Amount
$190,000.00
Summary
An advanced multimodal terahertz spectroscopy and imaging system for WA. An advanced multimodal terahertz spectroscopy and imaging system: Terahertz (THz) technology is in use in diverse applications from semiconductor inspection, metamaterials, biology and protein analysis, pharmaceutical sciences and formulations; security and surveillance, and biomedical imaging for burn assessment and cancer detection. This project will provide researchers with access to state-of-the-art THz spectroscopy and ....An advanced multimodal terahertz spectroscopy and imaging system for WA. An advanced multimodal terahertz spectroscopy and imaging system: Terahertz (THz) technology is in use in diverse applications from semiconductor inspection, metamaterials, biology and protein analysis, pharmaceutical sciences and formulations; security and surveillance, and biomedical imaging for burn assessment and cancer detection. This project will provide researchers with access to state-of-the-art THz spectroscopy and imaging facilities, resulting in high-impact outcomes across the physical and biological sciences and engineering, broadly contributing to Australia's economic and social well being.Read moreRead less
Real-time cardiac magnetic resonance imaging: a compressed-sensing framework incorporating sensor design and multidimensional signal reconstruction. Conventional Magnetic Resonance Imaging (MRI) technology is fundamentally constrained by slow scan speeds. Taking a new approach to cardiac imaging - which integrates MRI hardware design with a novel dynamic imaging method based on compressed sensing - this project enables faster and more accurate dynamic imaging for the diagnosis of heart disease.
Congestion control of networks: a unified stochastic framework. Systems such as the internet, wireless networks and the power grid require efficient allocation of shared resources. This research will develop ways to reduce delays in the internet and allow for growth in the power grid, without requiring additional infrastructure.
Green cool wine: solar powered solid adsorption refrigeration system with ice storage to provide cooling capability for wine industry. The project is to develop a solar thermal powered refrigeration system that is able to build up an ice bank (as a storage) through daily intermittent cycle, from late Australian spring. The ice bank will used in the vintage season in a winery for cooling purposes. The system is able to reduce the carbon foot print of the wineries significantly.
Heteronuclear parallel imaging and spectroscopy for magnetic resonance. This project will develop novel imaging technology for improved interrogation of biological processes in living tissue. Successful outcomes of this project are expected to contribute significantly to biomedical research efforts, such as improved early detection and treatment of cancer and chronic disease.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100082
Funder
Australian Research Council
Funding Amount
$120,000.00
Summary
Ultraviolet laser system (193 nanometres). New grating and integrated component technologies—many of which were pioneered in Australia at the existing facility—are revolutionising the role of photonics in disciplines outside of telecommunications. From ultra-high temperature fibre gratings for both the energy and mining industries and high power fibre lasers, through to the processing of substrates to pattern chemical attachment of self-assembled structures, and novel quantum processing approach ....Ultraviolet laser system (193 nanometres). New grating and integrated component technologies—many of which were pioneered in Australia at the existing facility—are revolutionising the role of photonics in disciplines outside of telecommunications. From ultra-high temperature fibre gratings for both the energy and mining industries and high power fibre lasers, through to the processing of substrates to pattern chemical attachment of self-assembled structures, and novel quantum processing approaches, new research areas are emerging. 193nm laser processing remains central to all these technologies. This facility will continue to keep Australia at the forefront of such research underpinning this next generation of technologies.Read moreRead less
A high flux continuous atom laser. This project aims to create an unprecedented ultra-cold atom source - a high brightness continuous atom laser. Such a device, the atomic analogue of an optical laser, may find near term application in precision inertial sensing based on atom interferometry. The proposed apparatus will utilise new techniques in cutting edge laser cooling and continuous all-optical wave-guiding to dramatically boost the density, collision rate and flux in a guided system. It is e ....A high flux continuous atom laser. This project aims to create an unprecedented ultra-cold atom source - a high brightness continuous atom laser. Such a device, the atomic analogue of an optical laser, may find near term application in precision inertial sensing based on atom interferometry. The proposed apparatus will utilise new techniques in cutting edge laser cooling and continuous all-optical wave-guiding to dramatically boost the density, collision rate and flux in a guided system. It is expected that the project will allow the study of previously unexplored territory in ultra-cold atom atomic physics.Read moreRead less
Creating high flux degenerate quantum atomic sources with active feedback. This project aims to deliver a new technique for cooling dilute ultracold gases, which are rapidly transitioning from a fundamental physics platform to a building block for quantum technology. This technique is measurement-based feedback cooling. Unlike the current evaporative methods, feedback cooling neither loses atoms, nor relies on elastic collisions or internal atomic structure. This opens up the possibility of dire ....Creating high flux degenerate quantum atomic sources with active feedback. This project aims to deliver a new technique for cooling dilute ultracold gases, which are rapidly transitioning from a fundamental physics platform to a building block for quantum technology. This technique is measurement-based feedback cooling. Unlike the current evaporative methods, feedback cooling neither loses atoms, nor relies on elastic collisions or internal atomic structure. This opens up the possibility of directly cooling traditionally un-coolable systems. This project will expand the quality and range of available atomic sources, benefitting research into exotic materials, and improving precision sensor applications. Quantum sensors are rapidly reforming our image of what a sensor is and what it can do, offering unprecedented opportunities in sensor fusion, and directly impacting business opportunities in mineral exploration, mapping and navigation.Read moreRead less