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Discovery Early Career Researcher Award - Grant ID: DE120100364
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Understanding winds: energy transfer in rotating turbulent fluids. The Earth's rotation affects how large atmospheric winds and cyclones interact with each other and with the surface of our planet. This controls how the wind energy is distributed in the global atmosphere. By studying rotating turbulence in laboratory experiments, we can improve our understanding of atmospheric dynamics and make better predictions in meteorology, and atmospheric physics.
Physical factors affecting deposition of combustion submicrometer particles in the human lung. Particles generated from combustion sources have a profound effect on human health, yet there is lack of scientific understanding of the role of different physical mechanisms on particle deposition in the lung. This program will advance scientific knowledge in this field through multidisciplinary efforts of a team from QUT and the University of Salzburg, Austria. It aims at quantification of particle d ....Physical factors affecting deposition of combustion submicrometer particles in the human lung. Particles generated from combustion sources have a profound effect on human health, yet there is lack of scientific understanding of the role of different physical mechanisms on particle deposition in the lung. This program will advance scientific knowledge in this field through multidisciplinary efforts of a team from QUT and the University of Salzburg, Austria. It aims at quantification of particle deposition in human lung through experimental studies and advanced modelling. The program will enhance and strengthen the existing collaboration between the universities and its outcome will be of significance in the vital area of human health and risk assessment.Read moreRead less
Fluid mechanics and physiology of blockages in vascular systems. Vascular disease is a major health problem both in Australia and worldwide. In particular, cardiovascular disease is a major killer of adult Australians. Engineers and mathematicians working with biologists will gain a greater understanding of vascular diseases, a major health problem, including cardiovascular disease, which is one of the biggest killers worldwide, as well as tackling renal circulation problems, which are a signifi ....Fluid mechanics and physiology of blockages in vascular systems. Vascular disease is a major health problem both in Australia and worldwide. In particular, cardiovascular disease is a major killer of adult Australians. Engineers and mathematicians working with biologists will gain a greater understanding of vascular diseases, a major health problem, including cardiovascular disease, which is one of the biggest killers worldwide, as well as tackling renal circulation problems, which are a significant problem and may contribute to hypertension. Detailed measurement and prediction will be undertaken of the mechanical loading and response of cells to their microenvironment, an important first step to controlling pathological responses which lead to a variety of autoimmune problems.Read moreRead less
Extreme wave events on the water surface. Giant waves observed in the ocean present a catastrophic threat to ships and offshore structures. Rogue waves in optical fibres, on the other hand, may help developing powerful light sources for long-distance telecommunications. This study of capillary rogue waves on the water surface will help to predict and control the probability of extreme waves.
Dynamic tomography: high-resolution, four-dimensional imaging of processes. This project will develop imaging technology that allows us to collect detailed, three dimensional movies of complex, microscopic processes in a laboratory. This technology will have applications in soil science, biology, oil extraction, and carbon sequestration.
Quantitative Brain Dynamics. This proposal will benefit Australia through unique and fundamental contributions to understanding brain dynamics via the development of innovative approaches and technologies. It will contribute to the national priority goals of Breakthrough Science, Frontier Technologies, and Promoting an Innovation Culture and Economy. Science outcomes will include improved understanding and probing of brain self-organization, dynamics, and function, including unique contributio ....Quantitative Brain Dynamics. This proposal will benefit Australia through unique and fundamental contributions to understanding brain dynamics via the development of innovative approaches and technologies. It will contribute to the national priority goals of Breakthrough Science, Frontier Technologies, and Promoting an Innovation Culture and Economy. Science outcomes will include improved understanding and probing of brain self-organization, dynamics, and function, including unique contributions to understanding alertness and the foundations of vision. These outcomes will be applied to develop new technologies for brain imaging and monitoring.Read moreRead less
Parametric Brain Imaging via Modeling and Analysis of Electroencephalographic Signals. Parameters of brain function and physiology will be spatially imaged with high time resolution via their effects on electroencephalographic (EEG) signals, a form of imaging that is impossible with existing methods. This will be achieved by improving existing physiologically-based models of the generation of EEGs and developing analysis tools based on fitting of model predictions to multielectrode EEG data. T ....Parametric Brain Imaging via Modeling and Analysis of Electroencephalographic Signals. Parameters of brain function and physiology will be spatially imaged with high time resolution via their effects on electroencephalographic (EEG) signals, a form of imaging that is impossible with existing methods. This will be achieved by improving existing physiologically-based models of the generation of EEGs and developing analysis tools based on fitting of model predictions to multielectrode EEG data. The results will be used to probe spatiotemporal features of EEGs in normal subjects to explore the underlying fundamental mechanisms and to infer novel parameter variations of practical relevance.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
Nanoparticle radiosensitisation. This project aims to develop new knowledge through a better understanding of physics interactions of particles in compounds with sub-micron size. Research on radiosensitisation by sub-micrometre sized nanoparticles (NPs) is hot worldwide because it could treat cancer, but the physical/physico-chemical/biological mechanism of radiosensitisation is unclear because no physical models describe particle interactions at nanometre scale in solid state nanometre sized ob ....Nanoparticle radiosensitisation. This project aims to develop new knowledge through a better understanding of physics interactions of particles in compounds with sub-micron size. Research on radiosensitisation by sub-micrometre sized nanoparticles (NPs) is hot worldwide because it could treat cancer, but the physical/physico-chemical/biological mechanism of radiosensitisation is unclear because no physical models describe particle interactions at nanometre scale in solid state nanometre sized objects. This project will develop and evaluate specialised physics models to describe particle interactions in NPs and help optimise nanoparticle technology. It will develop expertise in Australia in physics modelling for nanomedicine and other applications of nanotechnology exposed to radiation (e.g. telecommunications, aviation and space).Read moreRead less