Multi-scale ensemble modelling of coastal systems in a changing climate. This project aims to incorporate sandy shoreline adaptation by developing a time-varying framework for model ensemble averaging. This will significantly advance our ability to predict shoreline change over a range of management timescales from days to decades along high-value coastlines. This project expects to generate new knowledge in Coastal Engineering using new methods to train models and deliver unprecedented new shor ....Multi-scale ensemble modelling of coastal systems in a changing climate. This project aims to incorporate sandy shoreline adaptation by developing a time-varying framework for model ensemble averaging. This will significantly advance our ability to predict shoreline change over a range of management timescales from days to decades along high-value coastlines. This project expects to generate new knowledge in Coastal Engineering using new methods to train models and deliver unprecedented new shoreline data. The expected outcomes are enhanced capacity to predict shoreline change over a range of timescales and a better understanding of how sandy coastlines adapt to future climate variability. This should provide significant benefits by enabling a better assessment of coastal hazards along our high-value coastline.Read moreRead less
Are coastal wetlands vulnerable to bushfires? The ‘Black Summer’ fires burned extensive areas of coastal wetland not typically associated with fire impact. These wetlands rely upon plant growth and sediment delivery to respond to sea-level rise, processes which may be impacted by fire. This project aims to quantify the distribution and severity of fire impact, and establish post-fire vegetation and surface elevation trajectories. By integrating fire ecology and wetland science approaches, this p ....Are coastal wetlands vulnerable to bushfires? The ‘Black Summer’ fires burned extensive areas of coastal wetland not typically associated with fire impact. These wetlands rely upon plant growth and sediment delivery to respond to sea-level rise, processes which may be impacted by fire. This project aims to quantify the distribution and severity of fire impact, and establish post-fire vegetation and surface elevation trajectories. By integrating fire ecology and wetland science approaches, this project will ascertain the resilience of coastal wetlands to the cumulative impacts of fire and sea-level rise. Expected outcomes of this project include new, spatially-explicit fire management tools which will aid the sustainable, long-term management of coastal wetlands in a changing climate.Read moreRead less
Natural flood management: Nature-based flood mitigation in the 21st Century. The 2021-22 floods in Eastern Australia revealed the vulnerability of rivers to climate extremes. To prepare for a future with more intense floods, we must integrate nature-based flood mitigation strategies into river management. This project aims to address the potential of using Natural Flood Management (NFM) as a 21st Century flood mitigation solution. NFM uses natural processes to slow floods, reduce erosion, and mi ....Natural flood management: Nature-based flood mitigation in the 21st Century. The 2021-22 floods in Eastern Australia revealed the vulnerability of rivers to climate extremes. To prepare for a future with more intense floods, we must integrate nature-based flood mitigation strategies into river management. This project aims to address the potential of using Natural Flood Management (NFM) as a 21st Century flood mitigation solution. NFM uses natural processes to slow floods, reduce erosion, and minimise flood risk. Collaborating with NSW government partners the project expects to deliver scientific evidence for NFM and solutions for implementation in river rehabilitation, planning and community capacity building. The results will impact society's ability to adapt, reduce economic costs, and benefit the environment.Read moreRead less
Early Career Industry Fellowships - Grant ID: IE230100697
Funder
Australian Research Council
Funding Amount
$442,000.00
Summary
Quantifying eco-geomorphic linkages to enhance marine park management . This project aims to develop a novel framework for predicting the future resilience of reef-fronted coastal habitats within marine parks. Through innovative observations of reef-fronted coastal dynamics, it will quantify the relationships between coastline evolution, physical drivers, reef geomorphology, sediment supply and reef ecology. Expected outcomes include new practical tools and transferable knowledge that can identi ....Quantifying eco-geomorphic linkages to enhance marine park management . This project aims to develop a novel framework for predicting the future resilience of reef-fronted coastal habitats within marine parks. Through innovative observations of reef-fronted coastal dynamics, it will quantify the relationships between coastline evolution, physical drivers, reef geomorphology, sediment supply and reef ecology. Expected outcomes include new practical tools and transferable knowledge that can identify coastal regions that are sensitive to changing environmental conditions and/or reef ecology. These tools will enable marine managers to identify areas that are most vulnerable or resilient to change, allowing prioritisation of resources, conservation efforts, restoration activities, and management interventions.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100552
Funder
Australian Research Council
Funding Amount
$414,000.00
Summary
Landscape-climate disequilibrium in dune fields. This project aims to predict how wind-blown landscapes respond to changes in climate. This project expects to use novel experiments and theoretical advances to meet this aim, then apply the prediction to the dune fields which cover a third of Australia's surface to generate new knowledge on what climate shaped them in the past, and how they will respond to anthropogenic climate change. Expected outcomes of this project will strengthen collaboratio ....Landscape-climate disequilibrium in dune fields. This project aims to predict how wind-blown landscapes respond to changes in climate. This project expects to use novel experiments and theoretical advances to meet this aim, then apply the prediction to the dune fields which cover a third of Australia's surface to generate new knowledge on what climate shaped them in the past, and how they will respond to anthropogenic climate change. Expected outcomes of this project will strengthen collaboration with discipline-leading international researchers and develop a globally-unique laboratory experimental capability in Australia. This should provide significant benefits to understanding environmental change in Australia by vastly improving predictions of dune-field response to future climate.Read moreRead less