Dynamics of Interacting Bose Gases/Fluids in Atomic and Condensed Matter Systems. This research would raise the profile of Australian theoretical physics in two key areas of fundamental research. The work on correlated electron fluids will be directly related to the breakdown of the quantum Hall effect, which is used to maintain the resistance standard, with one possible outcome being the improvement of the accuracy of this standard. The work on the dynamics of dilute gas Bose-Einstein condensat ....Dynamics of Interacting Bose Gases/Fluids in Atomic and Condensed Matter Systems. This research would raise the profile of Australian theoretical physics in two key areas of fundamental research. The work on correlated electron fluids will be directly related to the breakdown of the quantum Hall effect, which is used to maintain the resistance standard, with one possible outcome being the improvement of the accuracy of this standard. The work on the dynamics of dilute gas Bose-Einstein condensates will promote understanding of such systems and propose knew methods of exploring this novel state of matter. Drawing analogies between these two diverse subjects will promote a greater understanding of both research fields. The work would be in collaboration with internationally renowned research groups.Read moreRead less
The Mechanics of Nanoscale Devices. Australian developments in biosensing, medical diagnostics, clean energy, communication and security technologies, are rapidly growing due to our mounting capacity in nanoscale fabrication. Vital for evolution of next-generation nanodevices is an understanding of how mechanical processes operate at such small scales. This application will contribute to this scientific knowledge base. This will in turn assist Australian industries to progress these applications ....The Mechanics of Nanoscale Devices. Australian developments in biosensing, medical diagnostics, clean energy, communication and security technologies, are rapidly growing due to our mounting capacity in nanoscale fabrication. Vital for evolution of next-generation nanodevices is an understanding of how mechanical processes operate at such small scales. This application will contribute to this scientific knowledge base. This will in turn assist Australian industries to progress these applications and devices, leading to economic, social and technological gains for the Australian community.Read moreRead less
Dual Geothermal System for Fresh Water Production and Power Generation. The dual geothermal system for fresh water production and power generation developed in this project will use relatively low-temperature geothermal resources and assist in supplying domestic fresh water as well as electricity to small communities remote from the main electricity grid without any associated greenhouse gas emissions. The technology developed will provide an opportunity for industry development, employment crea ....Dual Geothermal System for Fresh Water Production and Power Generation. The dual geothermal system for fresh water production and power generation developed in this project will use relatively low-temperature geothermal resources and assist in supplying domestic fresh water as well as electricity to small communities remote from the main electricity grid without any associated greenhouse gas emissions. The technology developed will provide an opportunity for industry development, employment creation and export potential through commercial manufacture in Australia of small to medium scale dual geothermal systems (e.g., 0.1 MW, 75000 litres fresh water per day).Read moreRead less
Measurement and Prediction of Vulnerable Plaque Formation and Rupture. The major health problem of atherosclerosis, leading to large numbers of deaths from heart attacks and strokes worldwide, will be studied by a multidisciplinary team. Better understanding of how the disease evolves and its earlier detection will arise from this project, which will use synchrotron imaging and supercomputer prediction.
Electrohydrodynamically-Driven Microcentrifugation for Microfluidic Applications. Microfluidics has the potential to revolutionise the way we live. Imagine portable pocket sized devices for cheap and rapid medical diagnostics and drug delivery. Or miniaturised chemical/biological sensors as early warning detection systems against terrorist threats. The research is thus intended to not only commercially benefit various industries, but also to improve the quality of life as a whole by making medic ....Electrohydrodynamically-Driven Microcentrifugation for Microfluidic Applications. Microfluidics has the potential to revolutionise the way we live. Imagine portable pocket sized devices for cheap and rapid medical diagnostics and drug delivery. Or miniaturised chemical/biological sensors as early warning detection systems against terrorist threats. The research is thus intended to not only commercially benefit various industries, but also to improve the quality of life as a whole by making medical diagnosis or chemical/biological detection more readily accessible, portable and more efficient. Moreover, the fundamental studies, aimed at generating an understanding of the complex physics involved, has generic benefits to researchers in applied physics as well as providing practical protocols for microdevice development.Read moreRead less
Renewable energy generation from flow-induced vibration. Much engineering effort has been expended to eliminate vibration of marine structures. This project seeks to provide the basis for the development of tidal energy harnessing, by deliberately amplifying and harnessing vibration. This technology offers the promise of capturing clean, zero-emissions energy, while presenting no risk to marine life.
Control of Transitions in Wakes and Swirling Flows. We will attack industrially-important problems in fluid mechanics by building new, and substantially enhancing existing, international collaborations between key complementary teams of internationally-recognised French and Australian researchers. Funding will support the exchange of 6 senior staff and 3 graduate students, which, in turn, will measurably benefit the research output of a further 20 graduate students and 7 post-doctoral fellows as ....Control of Transitions in Wakes and Swirling Flows. We will attack industrially-important problems in fluid mechanics by building new, and substantially enhancing existing, international collaborations between key complementary teams of internationally-recognised French and Australian researchers. Funding will support the exchange of 6 senior staff and 3 graduate students, which, in turn, will measurably benefit the research output of a further 20 graduate students and 7 post-doctoral fellows associated with closely-related projects. From the Australian perspective, the planned exchanges will bring new research expertise, knowledge and skills, which will be focussed on a diverse range of applications. Target industries (with existing collaborations) include Airbus and Dassault Aviation in Europe, and Aerosonde and Warman pumps in Australia. Read moreRead less
Understanding and modifying vortex structures in wind turbine wakes. At a fundamental research level, Australia's active participation in this area of national priority and research strength will be advanced through our published research, which will increase our understanding of wind turbine wakes and their effects in wind farms. This understanding will then be used to produce improved methods of predicting wind turbine performance. Such methods are needed by wind energy designers to produce b ....Understanding and modifying vortex structures in wind turbine wakes. At a fundamental research level, Australia's active participation in this area of national priority and research strength will be advanced through our published research, which will increase our understanding of wind turbine wakes and their effects in wind farms. This understanding will then be used to produce improved methods of predicting wind turbine performance. Such methods are needed by wind energy designers to produce better wind farms. It will also be used to recommend how to improve the aerodynamic design of turbine components, such as the blades and hub. Numerical tools will be developed for industry use, and training will be provided to personnel, thereby increasing the capabilities of Australia's growing wind energy industry.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100067
Funder
Australian Research Council
Funding Amount
$210,000.00
Summary
Wind profiler network for planetary boundary layer research. Understanding winds in the lower atmosphere is of great fundamental and practical importance. This new wind monitoring network will help Australian scientists to better predict propagation of tropical cyclones, to improve the efficiency of wind energy production, and to better understand atmosphere-ocean interactions affecting weather and climate.
Analysis and application of a Lagrangian turbulence model for smoothed particle hydrodynamics. The project will use a new turbulence model to improve the predictions of chaotic motions that include plunging waves, fast flows carrying sediment and the mixing of pollutants.