An Australian storm wave damage and beach erosion early warning system. This project aims to develop a new coastal hazard early-warning system capability for Australia, to alert coastal communities, emergency managers and coastal engineers to impending storm wave damage and coastal erosion. Emergency preparedness informed by early warning is expected to significantly benefit vulnerable communities and infrastructure along Australia’s coasts.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE170100090
Funder
Australian Research Council
Funding Amount
$600,000.00
Summary
Coastal Engineering Research Field Station (CERFS). This project aims to establish a Coastal Engineering Research Field Station (CERFS) with instrument modules for measuring waves, tides, currents, seabed and beach profiles and sediment characteristics. There are critical knowledge gaps in the understanding of coastal processes, including the effects of climate variability and change, and a need to generate long-term data-sets for calibration of coastal models against Australian conditions. The ....Coastal Engineering Research Field Station (CERFS). This project aims to establish a Coastal Engineering Research Field Station (CERFS) with instrument modules for measuring waves, tides, currents, seabed and beach profiles and sediment characteristics. There are critical knowledge gaps in the understanding of coastal processes, including the effects of climate variability and change, and a need to generate long-term data-sets for calibration of coastal models against Australian conditions. The coastal process data obtained will lead to improved models, management strategies and design guidelines improving techniques to address coastal infrastructure design, beach management strategies and impact assessment to meet the challenges of future major coastal development. This will help decision-makers to reduce the risk to coastal communities, coastal ecosystems and maritime operations from extreme storms, climate change, infrastructure development and urbanisation.Read moreRead less
Beach Erosion and Recovery: Quantifying the Hazard. Coastal erosion is confronting societies and the natural environment. The economic value in Australia of built assets at risk includes roads ($60 billion), commercial buildings ($81 billion) and homes ($63 billion). Hard engineering entire coastlines is rarely feasible, with beaches providing the best coastal defence along the great majority of sandy coastlines. But how wide should a buffer zone be to provide adequate protection from storms? An ....Beach Erosion and Recovery: Quantifying the Hazard. Coastal erosion is confronting societies and the natural environment. The economic value in Australia of built assets at risk includes roads ($60 billion), commercial buildings ($81 billion) and homes ($63 billion). Hard engineering entire coastlines is rarely feasible, with beaches providing the best coastal defence along the great majority of sandy coastlines. But how wide should a buffer zone be to provide adequate protection from storms? And critically, how reliable are the present modelling tools used to predict this, and can they be improved? Underpinned by innovative field observations to fill fundamental knowledge gaps, this project aims to deliver advanced understanding and the best available solution to storm erosion prediction.Read moreRead less
Transitions in wave breaking from deep to shallow water . The predominant impact on coastal geomorphology, marine safety and coastal structures is from breaking waves, especially from storms. This project will provide the first unified formulation of breaking wave effects from deep to shallow water, which will increase wave forecast model accuracy and hence improve coastal zone design and safety outcomes.
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.
Quantifying vertical and lateral ocean transport due to fronts and eddies. This project aims to quantify the intensity and location of ocean currents at unprecedented fine spatial scales by using data from a new generation of high-resolution satellites. These fine scales dominate the lateral and vertical transport of ocean-borne material, including heat, larvae and pollutants like oil and plastics, yet are poorly understood. New algorithms for processing satellite data will be developed and test ....Quantifying vertical and lateral ocean transport due to fronts and eddies. This project aims to quantify the intensity and location of ocean currents at unprecedented fine spatial scales by using data from a new generation of high-resolution satellites. These fine scales dominate the lateral and vertical transport of ocean-borne material, including heat, larvae and pollutants like oil and plastics, yet are poorly understood. New algorithms for processing satellite data will be developed and tested using in situ data in the significant North West Shelf region. Expected outcomes will be novel methods to identify ocean currents and a paradigm shift in quantification of fine-scale ocean dynamics. This will benefit operational oceanography in the areas of maritime safety, defence, fisheries and the offshore industry.Read moreRead less
Ocean response to tropical cyclone forcing on the Australian North West Shelf. Tropical cyclones are a major hazard for the offshore oil and gas industry. This project will develop the ability to predict the ocean response to tropical cyclones, leading to a paradigm shift in the way industry designs and operates both present and future offshore projects.
Development and validation of an innovative wind stress model to obtain robust storm surge forecasts. Storm surges represent a major ocean flood hazard to coastal communities but present models have large errors, which are often dangerously low. Through international collaboration, this project will collect new field data and develop a new storm surge model which will enhance community safety by ensuring accurate forecasts of ocean flood levels.
Wave dynamics in topographically-complex coastal reef systems. Both tropical coral and temperate rocky reefs are abundant features of Australia's coastline, yet their hydrodynamics (waves, currents and water levels) are poorly understood relative to other coastal environments such as beaches. This project will elucidate the complex hydrodynamic processes when waves interact with the steep-slopes and large bottom roughness of reefs, by establishing an international research program combining labo ....Wave dynamics in topographically-complex coastal reef systems. Both tropical coral and temperate rocky reefs are abundant features of Australia's coastline, yet their hydrodynamics (waves, currents and water levels) are poorly understood relative to other coastal environments such as beaches. This project will elucidate the complex hydrodynamic processes when waves interact with the steep-slopes and large bottom roughness of reefs, by establishing an international research program combining laboratory and field measurements with numerical modelling. The improved process-understanding of reef hydrodynamics developed through this project will lead to significant advances in our ability to predict the impacts of extreme events (for example, storms and tsunamis) and climate change on coasts, both here and abroad.Read moreRead less
Physical processes in complex coastal reef environments: the dynamics of wave- and tide-dominated systems. Coastal reefs are ubiquitous features of Australia's coastline, yet the dynamics controlling water motion on reefs still remain poorly understood. This project will significantly advance our understanding of coastal processes within reef environments, thus improving predictions of the impacts of extreme storms and climate change on our coasts.