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Observations of remarkable eastward flows in the South Indian Ocean. The Indian Ocean drives much of the variability of Australian weather and rainfall and is rapidly evolving. Innovative new observations of remarkable eastward flows in the South Indian Ocean will be combined with models to understand these circulations in a region that has significant economic value for Australia.
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
Pelagic symbioses: teasing apart phytoplankton-bacteria relationships. This project aims to decode the intricate relationships between populations of phytoplankton and marine bacteria and interpret their influence on ocean productivity and chemical cycling. While oceanographers typically consider the ecology of phytoplankton and bacteria in isolation, this project suggests that the lives of these organisms are inherently entwined in symbiosis. This project is anticipated to aid in management of ....Pelagic symbioses: teasing apart phytoplankton-bacteria relationships. This project aims to decode the intricate relationships between populations of phytoplankton and marine bacteria and interpret their influence on ocean productivity and chemical cycling. While oceanographers typically consider the ecology of phytoplankton and bacteria in isolation, this project suggests that the lives of these organisms are inherently entwined in symbiosis. This project is anticipated to aid in management of Australia’s valuable marine estate and the ecosystem services and food security it provides.Read moreRead less
Defining the Microbial-scale Processes Governing Ocean Health . This project aims to resolve the foundations of healthy ocean function by employing innovative approaches to uncover the links between marine chemistry and microbiology. While the importance of microbes in governing ocean health is unquestionable, they are often studied over inappropriately large-scales, leading to inaccurate interpretation of the oceanic processes that ultimately influence fishery production and climate control. W ....Defining the Microbial-scale Processes Governing Ocean Health . This project aims to resolve the foundations of healthy ocean function by employing innovative approaches to uncover the links between marine chemistry and microbiology. While the importance of microbes in governing ocean health is unquestionable, they are often studied over inappropriately large-scales, leading to inaccurate interpretation of the oceanic processes that ultimately influence fishery production and climate control. We will develop new oceanographic tools and analytical techniques to provide a unique "microbes-eye-view" of the sea. The project's outcomes are anticipated to deliver transformative new knowledge on the controls of ocean productivity and sustainability, helping to safeguard Australia’s valuable marine estate.Read moreRead less
IMPACTS OF RIVER NUTRIENTS ON THE GREAT BARRIER REEF LAGOON. While salinity was one of the first properties of the ocean to be studied, it is one of the last to be measured by remote sensing. A prototype air borne salinity mapper will be used in this project along with an airborne multi-spectral sampler to develop a new approach to the study of river plumes. The salinity and nutrient densities will be traced to determine the destination of river runoff. Outcomes will assist the management of ....IMPACTS OF RIVER NUTRIENTS ON THE GREAT BARRIER REEF LAGOON. While salinity was one of the first properties of the ocean to be studied, it is one of the last to be measured by remote sensing. A prototype air borne salinity mapper will be used in this project along with an airborne multi-spectral sampler to develop a new approach to the study of river plumes. The salinity and nutrient densities will be traced to determine the destination of river runoff. Outcomes will assist the management of the Great Barrier Reef Marine Park and land management near the coast, and will improve our understanding of the carbon sink in coastal waters.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE140100076
Funder
Australian Research Council
Funding Amount
$394,585.00
Summary
Mixing hot spots in the Southern Ocean: processes, parameterisations and climate impacts. The Southern Ocean plays a critical role in the uptake of heat and carbon dioxide from the atmosphere into the deep ocean. This uptake depends strongly on mixing processes due to ocean eddies, which are especially important in regions of steep topography, leading to localised mixing hot spots. These ocean eddies have scales of 10-100km and therefore can not be resolved in current global climate models. This ....Mixing hot spots in the Southern Ocean: processes, parameterisations and climate impacts. The Southern Ocean plays a critical role in the uptake of heat and carbon dioxide from the atmosphere into the deep ocean. This uptake depends strongly on mixing processes due to ocean eddies, which are especially important in regions of steep topography, leading to localised mixing hot spots. These ocean eddies have scales of 10-100km and therefore can not be resolved in current global climate models. This project will examine these mixing processes using a combination of observations and innovative modelling approaches. This knowledge will be used to improve the representation of eddy processes in state-of-the-art climate models, which will ultimately allow Australia to more effectively respond to the challenge of climate change.Read moreRead less
Australia's ocean microbiome: how the diversity and functionality of microbes influence key oceanographic provinces. Every millilitre of seawater contains millions of microbes that maintain the health of our planet, but their identity and function in Australian waters is undefined. This project will identify the microbes inhabiting Australian marine systems, elucidate the services they provide, and predict how they will be affected by future environmental changes
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.
How topography brakes the Antarctic Circumpolar Current. This project aims to observe and simulate the mechanisms that slow the Antarctic Circumpolar Current. The Southern Ocean winds have increased over the last two decades while the transport of the world’s largest current remains steady or slightly decreasing. A possible explanation is negative feedback mechanisms between the winds and transport of the Antarctic Circumpolar Current. This project will observe how eddies carry momentum from the ....How topography brakes the Antarctic Circumpolar Current. This project aims to observe and simulate the mechanisms that slow the Antarctic Circumpolar Current. The Southern Ocean winds have increased over the last two decades while the transport of the world’s largest current remains steady or slightly decreasing. A possible explanation is negative feedback mechanisms between the winds and transport of the Antarctic Circumpolar Current. This project will observe how eddies carry momentum from the wind down to the sea floor and accelerate the deep currents that drag against the rough bottom to put the brakes on this current. Since this current affects Australian rainfall patterns and agricultural output, findings could inform public policy.Read moreRead less
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