WAKE FLOWS WITH UPSTREAM TURBULENCE IN MARINE, ATMOSPHERIC AND BUILT ENVIRONMENTS. Through improved understanding of turbulent wakes the project will have applications across aeronautics and hydrodynamics, leading to more efficient engineering designs to reduce flow drag. In marine environments our findings will improve coastal ocean models and the prediction of pollutant dispersal, nutrient fluxes and sediment transport, and contribute to the management of biological productivity (NRP 1.5). In ....WAKE FLOWS WITH UPSTREAM TURBULENCE IN MARINE, ATMOSPHERIC AND BUILT ENVIRONMENTS. Through improved understanding of turbulent wakes the project will have applications across aeronautics and hydrodynamics, leading to more efficient engineering designs to reduce flow drag. In marine environments our findings will improve coastal ocean models and the prediction of pollutant dispersal, nutrient fluxes and sediment transport, and contribute to the management of biological productivity (NRP 1.5). In the atmospheric boundary layer, the results will assist planners to improve wind environments near large buildings or clusters of buildings, benefiting the safety of aircraft at takeoff and landing. The project will develop collaboration and help maintain the strength of Australian research in environmental flows.Read moreRead less
Characterizing the hydrological cycle using water isotopes, land-surface models and satellite observations. Water is our most precious natural resource. In Australia, it is also our most precarious. The hydrological cycle describes the movement of water between the ocean, atmosphere and land. Understanding the effect and impact that a changing climate might have on the hydrological cycle is critical to securing Australia's water resources. To address these challenges, we must improve our basic u ....Characterizing the hydrological cycle using water isotopes, land-surface models and satellite observations. Water is our most precious natural resource. In Australia, it is also our most precarious. The hydrological cycle describes the movement of water between the ocean, atmosphere and land. Understanding the effect and impact that a changing climate might have on the hydrological cycle is critical to securing Australia's water resources. To address these challenges, we must improve our basic understanding of the water exchange processes within the Earth system. Our project will exploit new technology in ground and space based observation, combined with advanced modeling and measurement capabilities, to develop an improved understanding and characterization of Australian hydrological cycles and aid in assessing climate change related impacts. Read moreRead less