Benthic Processes and Oceanic Internal Waves. Direct observations will be made of the turbulent motion and sediment re-suspension near the sea bed of the ocean in regions strongly influenced by tides and internal waves. Combined with numerical models, the study will provide new insights into processes that are of fundamental importance to understanding the global dissipation of tidal energy and the role of internal waves in these processes. With observations from the continental slope region of ....Benthic Processes and Oceanic Internal Waves. Direct observations will be made of the turbulent motion and sediment re-suspension near the sea bed of the ocean in regions strongly influenced by tides and internal waves. Combined with numerical models, the study will provide new insights into processes that are of fundamental importance to understanding the global dissipation of tidal energy and the role of internal waves in these processes. With observations from the continental slope region of the Australian North West Shelf, results will also benefit the offshore engineering industry through knowledge of sediment scour and loadings on offshore structures.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE130101336
Funder
Australian Research Council
Funding Amount
$374,354.00
Summary
Inter-ocean exchange around Australia and its relation to regional and global climate. The flow of water from the Pacific to the Indian Ocean is important to both regional and global climate. Most of the water flows through the Indonesian Archipelago, but there is also a westward flow south of Tasmania. We will study the dynamics of this inter-ocean exchange and investigate how it impacts regional climate and marine ecosystems.
Discovery Early Career Researcher Award - Grant ID: DE210100004
Funder
Australian Research Council
Funding Amount
$440,185.00
Summary
Mixing and air-sea coupling in the Pacific: Toward better El Nino forecasts. The Tropical Pacific drives significant year-to-year variability in Australian rainfall and climate extremes. However, tropical climate predictions are severely limited due to systematic biases in numerical climate models. Using new techniques and leveraging international collaborations, this project aims to transform our ability to simulate tropical Pacific climate through a new understanding of key air-sea interaction ....Mixing and air-sea coupling in the Pacific: Toward better El Nino forecasts. The Tropical Pacific drives significant year-to-year variability in Australian rainfall and climate extremes. However, tropical climate predictions are severely limited due to systematic biases in numerical climate models. Using new techniques and leveraging international collaborations, this project aims to transform our ability to simulate tropical Pacific climate through a new understanding of key air-sea interaction and ocean mixing processes. Expected outcomes include a better representation of tropical climate in the Australian climate model and improved seasonal to interannual predictive capability. These improved predictions will give communities more time to prepare for extreme events such as droughts, heatwaves and bushfires.Read moreRead less
Forecasting wave breaking in directional seas. Wave breaking in Australia's coastal and open ocean regions has significant consequences for weather forecasting, marine safety, defence and renewable energy, yet no conceptual or computing framework exists for this fundamental process. This innovative project extends our recent advances in predicting wave breaking onset and strength of unidirectional wave groups to forecast breaking in realistic directional wind seas. The results of this project wi ....Forecasting wave breaking in directional seas. Wave breaking in Australia's coastal and open ocean regions has significant consequences for weather forecasting, marine safety, defence and renewable energy, yet no conceptual or computing framework exists for this fundamental process. This innovative project extends our recent advances in predicting wave breaking onset and strength of unidirectional wave groups to forecast breaking in realistic directional wind seas. The results of this project will provide the scientific basis needed to include reliable breaking wave information in forecast models, and will improve their accuracy. It will also increase the international competitiveness of Australian commerce reliant on accurate marine environmental forecasts.
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Coastal cold core eddies of the East Australian Current and their fisheries potential. Offshore eddies shed by the East Australian Current can draw in coastal water from the Stockton Bight on the NSW central coast. This area is anecdotally recognized as a fisheries nursery area. It is often enriched by upwelling of cold, nutrient-rich waters which can seed these eddies with larval fish and their food. We will test if such eddies nurture plankton communities and then transport them back to the co ....Coastal cold core eddies of the East Australian Current and their fisheries potential. Offshore eddies shed by the East Australian Current can draw in coastal water from the Stockton Bight on the NSW central coast. This area is anecdotally recognized as a fisheries nursery area. It is often enriched by upwelling of cold, nutrient-rich waters which can seed these eddies with larval fish and their food. We will test if such eddies nurture plankton communities and then transport them back to the coast, giving rise to a useful index for predicting future fisheries, as well as explaining biodiversity changes to marine park planners. We will provide a census of these eddies during El Nino-Southern Oscillation events and climate change of the past 15 years in unprecedented detail.Read moreRead less
Eddy mixing and water mass formation in the Southern Ocean in a global 1/4 degree model. The next generation of ocean climate models will rely on linkages between experts in large-scale oceanography, mesoscale ocean physics and computational techniques. This project brings together such expertise. It will result in the development of better ocean models for use in climate prediction by improving the representation of eddy contributions to air/sea interactions. Australia's climate is extreme, wi ....Eddy mixing and water mass formation in the Southern Ocean in a global 1/4 degree model. The next generation of ocean climate models will rely on linkages between experts in large-scale oceanography, mesoscale ocean physics and computational techniques. This project brings together such expertise. It will result in the development of better ocean models for use in climate prediction by improving the representation of eddy contributions to air/sea interactions. Australia's climate is extreme, with harsh droughts, severe bushfire seasons, soil loss, and salinity all posing potentially enormous socio-economic challenges over the next fifty years. Improving climate models is thus highly significant for Australia, as mitigating the effects of climate change depend on reliable climate prediction systems.Read moreRead less
Advancing dynamical understanding in the East Australian Current: Optimising the ocean observation and prediction effort. The East Australian Current is a highly dynamic system, thus is very difficult to observe, measure and predict. Our aim is to advance the dynamical understanding of this complex system and to quantify the value of specific observations in improving ocean state-estimates. State-estimates are critical for robust ocean predictions in a region that is warming faster than anywhere ....Advancing dynamical understanding in the East Australian Current: Optimising the ocean observation and prediction effort. The East Australian Current is a highly dynamic system, thus is very difficult to observe, measure and predict. Our aim is to advance the dynamical understanding of this complex system and to quantify the value of specific observations in improving ocean state-estimates. State-estimates are critical for robust ocean predictions in a region that is warming faster than anywhere else on the planet. This project will integrate innovative numerical modeling techniques with a state-of-the-art ocean observing system. The expected outcomes will guide future ocean observing efforts; maximising impact while reducing cost. The results will be readily applicable to analogous systems around the world and our team is well placed to implement them internationally.Read moreRead less
Quantifying the role of salps in marine food webs and organic carbon export. Australia has recently committed significant resources to the observation and forecasting of ocean temperature and circulation that will vastly improve the understanding of environmental forcing of regional scale biological processes. This project will use ocean circulation hindcasts, ship-board measurements and laboratory studies to capture the dynamics of the zooplankton community, and in particular a fast-growing cla ....Quantifying the role of salps in marine food webs and organic carbon export. Australia has recently committed significant resources to the observation and forecasting of ocean temperature and circulation that will vastly improve the understanding of environmental forcing of regional scale biological processes. This project will use ocean circulation hindcasts, ship-board measurements and laboratory studies to capture the dynamics of the zooplankton community, and in particular a fast-growing class of gelatinous zooplankton, the salps, in the waters off southeast Australia. During bloom events, salps can alter the functioning of marine ecosystems. This project will quantify the impact of salp blooms on fish resources and ocean uptake of carbon in southeast Australian waters.Read moreRead less
Development of a coupled physical-biological model of size-structured biota in marine waters. The marine environment contains highly valued economic, social and environmental resources. Natural resource management in Australia is shifting from considering the value of a single resource, such as the South Eastern Trawl Fishery, to considering complete ecosystems with their multiple uses, such as the South East Australian coastal and shelf waters. With such a shift in perspective, Australia is a w ....Development of a coupled physical-biological model of size-structured biota in marine waters. The marine environment contains highly valued economic, social and environmental resources. Natural resource management in Australia is shifting from considering the value of a single resource, such as the South Eastern Trawl Fishery, to considering complete ecosystems with their multiple uses, such as the South East Australian coastal and shelf waters. With such a shift in perspective, Australia is a world leader. A new suite of tools is required to understand ecosystem dynamics and to formulate management strategies. By providing well-defined manageable outputs from a complex natural system the coupled physical-biological model to be developed will provide such a tool.Read moreRead less
Coastal Processes Driven by the East Australia Current. Coastal waters of Northern NSW are dominated by the East Australia Current (EAC). Through its strength, variability in space and time, and its proximity to the coast, the EAC directly controls not only the longshore currents, but also the cross-shelf transport of nutrients, plankton and other biota. A knowledge of EAC dynamics and ocean productivity will be achieved in this project by comparison of results from high resolution ocean models ....Coastal Processes Driven by the East Australia Current. Coastal waters of Northern NSW are dominated by the East Australia Current (EAC). Through its strength, variability in space and time, and its proximity to the coast, the EAC directly controls not only the longshore currents, but also the cross-shelf transport of nutrients, plankton and other biota. A knowledge of EAC dynamics and ocean productivity will be achieved in this project by comparison of results from high resolution ocean models (having additional biological modules) with data from Research Vessel Franklin cruises in 1998 and 1999.Read moreRead less