Geo-hydrodynamic modelling and estuarine evolution. We have accumulated considerable knowledge of the geomorphology, sedimentology and hydrodynamics of estuarine systems in southeastern Ausralia. This project represents the first rigorous attempt to combine these diverse factors to provide a process-based mathematical model of long- to medium-term sedimentation that can be used for environmental management. To be predictive the model has to use documented changes in the sedimentation histories o ....Geo-hydrodynamic modelling and estuarine evolution. We have accumulated considerable knowledge of the geomorphology, sedimentology and hydrodynamics of estuarine systems in southeastern Ausralia. This project represents the first rigorous attempt to combine these diverse factors to provide a process-based mathematical model of long- to medium-term sedimentation that can be used for environmental management. To be predictive the model has to use documented changes in the sedimentation histories of different estuary types over the past 8000 years in order to predict their evolution over the next 1000 years. The models that are developed can be applied to estuarine systems both nationally and internationally.Read moreRead less
Role of vegetation patchiness and self organisation in the ecohydrologic response of water limited ecosystems to climate variability and change. The semi-arid Australian rangelands are some of the most sensitive regions to degradation and climate change, particularly with respect to hydrology and ecology. Our predictive ability in these environments is quite poor, however, climatic change (particularly changes in rainfall regimes) are expected to intensify vegetation patterning, intensify erosi ....Role of vegetation patchiness and self organisation in the ecohydrologic response of water limited ecosystems to climate variability and change. The semi-arid Australian rangelands are some of the most sensitive regions to degradation and climate change, particularly with respect to hydrology and ecology. Our predictive ability in these environments is quite poor, however, climatic change (particularly changes in rainfall regimes) are expected to intensify vegetation patterning, intensify erosion and reduce runoff. This project will develop a modelling framework to better understand the impact of these natural (climate variability and change) and anthropogenic (grazing, deforestation) disturbances on runoff and erosion in these regions.Read moreRead less
Efficient and Robust Prediction at Ungauged Catchments. Hydrological models are an integral part of virtually all environmental models formulated at the catchment scale. They are used in the planning, design and operation of water infrastructure. Despite the importance of these models limited rainfall and streamflow gauging forces these models to be routinely applied at ungauged locations where predictive power is poorly understood and almost always unsatisfactory. This project will directly ben ....Efficient and Robust Prediction at Ungauged Catchments. Hydrological models are an integral part of virtually all environmental models formulated at the catchment scale. They are used in the planning, design and operation of water infrastructure. Despite the importance of these models limited rainfall and streamflow gauging forces these models to be routinely applied at ungauged locations where predictive power is poorly understood and almost always unsatisfactory. This project will directly benefit model users by providing (a) robust framework for quantifying uncertainty and (b) improved predictions at ungauged basins. This will provide more realistic guidance for design engineers and policy makers and be of significant benefit to a large range of Australian water users.Read moreRead less