Linkage Infrastructure, Equipment And Facilities - Grant ID: LE240100039
Funder
Australian Research Council
Funding Amount
$470,000.00
Summary
Advanced HR-ICP-MS facility for marine, Antarctic and environmental samples. This proposal seeks support for a shared High Resolution Inductively Coupled Plasma Mass Spectrometry facility for Tasmanian researchers. The existing UTAS instrument is approaching end-of-life and is becoming increasingly unreliable. Access to enhanced capabilities embodied in a rejuvenated facility, along with a renewed lifespan, is essential for continued analysis of ultra-trace elements and isotopes in challenging s ....Advanced HR-ICP-MS facility for marine, Antarctic and environmental samples. This proposal seeks support for a shared High Resolution Inductively Coupled Plasma Mass Spectrometry facility for Tasmanian researchers. The existing UTAS instrument is approaching end-of-life and is becoming increasingly unreliable. Access to enhanced capabilities embodied in a rejuvenated facility, along with a renewed lifespan, is essential for continued analysis of ultra-trace elements and isotopes in challenging samples from southern environments. The new instrument will allow TAS researchers and their (inter)national collaborators to undertake world-leading research, enhancing competitive profiles in a diverse range of research areas (oceanography, analytical chemistry, Antarctic studies, environmental assessment, geochemistry). Read moreRead less
Zooplankton and ocean productivity in a changing climate. The scarcity of iron in the Southern Ocean limits biological productivity and carbon uptake. There is currently very little Information on zooplankton iron content, yet available data points to high variability. This variability is leading to poor predictive outcomes for models of Southern Ocean iron and carbon cycling. Our project addresses this knowledge gap by quantifying zooplankton iron content and examining its biogeochemical and ec ....Zooplankton and ocean productivity in a changing climate. The scarcity of iron in the Southern Ocean limits biological productivity and carbon uptake. There is currently very little Information on zooplankton iron content, yet available data points to high variability. This variability is leading to poor predictive outcomes for models of Southern Ocean iron and carbon cycling. Our project addresses this knowledge gap by quantifying zooplankton iron content and examining its biogeochemical and ecological impact on Southern Ocean productivity. Developing an understanding of how iron is cycled through zooplankton will provide significant benefits including improved global models used to quantify current and future patterns of ocean productivity critical for environmental and economic predictions.Read moreRead less
Understanding multi-scale dynamics of eddies in the East Australian Current. This project aims to provide the first rigorous quantification of the complex dynamics of rotating eddies (the weather systems of the ocean) and fronts on scales ranging from metres to 100s of kilometres and hours to weeks in the East Australian Current System. This project is at the frontier of oceanographic research and will provide significant new understanding of the physical and biogeochemical dynamics of eddies an ....Understanding multi-scale dynamics of eddies in the East Australian Current. This project aims to provide the first rigorous quantification of the complex dynamics of rotating eddies (the weather systems of the ocean) and fronts on scales ranging from metres to 100s of kilometres and hours to weeks in the East Australian Current System. This project is at the frontier of oceanographic research and will provide significant new understanding of the physical and biogeochemical dynamics of eddies and their interactions across multiple spatio-temporal scales, revealing their impacts on productivity along Australia’s most populous coastline. This will provide significant benefits such as improved ocean forecasting and sustainable management of Australian marine industries and seafood sector, supporting economic growth. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100115
Funder
Australian Research Council
Funding Amount
$451,697.00
Summary
Evaluating the Impact and Efficiency of Engineering the Ocean to Remove CO2. This project aims to evaluate the viability of engineering the ocean to remove carbon dioxide from the atmosphere by simulating a suite of climate intervention and baseline scenarios. To better predict changes in marine carbon cycling, I will first make novel observations of zooplankton grazing dynamics, then use them to improve, validate and constrain a new marine biogeochemical model. Using this model, coupled to an o ....Evaluating the Impact and Efficiency of Engineering the Ocean to Remove CO2. This project aims to evaluate the viability of engineering the ocean to remove carbon dioxide from the atmosphere by simulating a suite of climate intervention and baseline scenarios. To better predict changes in marine carbon cycling, I will first make novel observations of zooplankton grazing dynamics, then use them to improve, validate and constrain a new marine biogeochemical model. Using this model, coupled to an ocean, atmosphere and fisheries model, I will quantify the long-term efficiency with which marine carbon dioxide removal strategies sequester carbon along with their impact on fisheries catch. These projections will help scientists, policy-makers, and industry leaders decide if, when, and how we should geoengineer the ocean. Read moreRead less