What drives recruitment variability in Snapper? Application of a novel theoretical and empirical approach to predict fluctuations in fisheries. This research will contribute to the sustainable management of the snapper resource to both protect the population and also provide long-term sustainability in terms of the ecosystem goods and services provided by the fishery, and associated social and economic benefits. Results will have broad applicability, as the critical environmental factors identif ....What drives recruitment variability in Snapper? Application of a novel theoretical and empirical approach to predict fluctuations in fisheries. This research will contribute to the sustainable management of the snapper resource to both protect the population and also provide long-term sustainability in terms of the ecosystem goods and services provided by the fishery, and associated social and economic benefits. Results will have broad applicability, as the critical environmental factors identified are likely to influence other species as well. Understanding the environmental factors underpinning recruitment variation in snapper will allow better predictions of impacts on recruitment levels resulting from climatic variability in the short term, and also longer-term effects of climate change on the population, for incorporation into future management assessments.Read moreRead less
Interactions between small scale cyclones and sea ice and their role in the Southern Ocean climate system. The Southern Ocean cyclone belt has a strong influence on Australian weather and climate. This project will allow improvements in the understanding of intense small scale cyclones in the region. Importantly, the research will highlight key sensitivities in the coupling between these atmospheric circulations and the underlying sea ice. Further, the compilation of an updated Southern Ocean cy ....Interactions between small scale cyclones and sea ice and their role in the Southern Ocean climate system. The Southern Ocean cyclone belt has a strong influence on Australian weather and climate. This project will allow improvements in the understanding of intense small scale cyclones in the region. Importantly, the research will highlight key sensitivities in the coupling between these atmospheric circulations and the underlying sea ice. Further, the compilation of an updated Southern Ocean cyclone climatology will provide a basis for evaluating future changes in cyclone distribution and frequency of occurrence in the Antarctic region. Finally, by leading this unique international collaboration with German and US scientists, the profile of Australian scientists in Antarctic atmospheric research will be strongly enhanced.Read moreRead less
Australian climate extremes and predictability in a changing CO2 world: the unique role of the Southern Hemisphere extratropical ocean-atmosphere. Australia's climate is extreme, with harsh droughts, severe bushfire seasons, climate change, soil loss, and salinity all posing potentially enormous socio-economic challenges over the next fifty years. Research into climate variability, extremes, and predictability is thus highly significant for Australia, and will underpin efforts to protect our bio ....Australian climate extremes and predictability in a changing CO2 world: the unique role of the Southern Hemisphere extratropical ocean-atmosphere. Australia's climate is extreme, with harsh droughts, severe bushfire seasons, climate change, soil loss, and salinity all posing potentially enormous socio-economic challenges over the next fifty years. Research into climate variability, extremes, and predictability is thus highly significant for Australia, and will underpin efforts to protect our biodiversity and ensure the nation's environmental sustainability. We propose to launch a major new initiative in extratropical climate analysis. This work will have significant benefits for the many sectors of society reliant on interseasonal-interannual climate prediction. Prominent examples include agriculture, energy, freshwater supply, bushfire control, air quality, health, and tourism.Read moreRead less
Scientific basis for improved climate predictions on seasonal and climate-change timescales. This project would lead to improved accuracy of Australian climate predictions, leading to benefits in many sectors. Increasing the accuracy of seasonal climate predictions across March-May, a crucial time for decision-making in Australian agriculture but a time when the forecasts exhibit little skill, would lead to large economic/societal benefits. Separating the factors influencing tropical cyclones is ....Scientific basis for improved climate predictions on seasonal and climate-change timescales. This project would lead to improved accuracy of Australian climate predictions, leading to benefits in many sectors. Increasing the accuracy of seasonal climate predictions across March-May, a crucial time for decision-making in Australian agriculture but a time when the forecasts exhibit little skill, would lead to large economic/societal benefits. Separating the factors influencing tropical cyclones is essential to determine whether global warming is changing Australian tropical cyclones, a crucial climate change question. Separating the influences of atmospheric circulation variations and other factors on climate changes and impacts should improve climate impact predictions, leading to enhanced economic benefits.
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Wave-Induced Upper-Ocean Mixing. The wave-induced mixing is of principal importance for air-sea interaction models since heat capacity of 2-3m of the ocean water is equal to the capacity of the entire atmosphere. This project will study and implement such mixing, including the newly described physical phenomenon of wave-induced turbulence, into a variety of models. As a result, wave models and global climate models will be coupled. It is believed that such coupling will enhance our ability to pr ....Wave-Induced Upper-Ocean Mixing. The wave-induced mixing is of principal importance for air-sea interaction models since heat capacity of 2-3m of the ocean water is equal to the capacity of the entire atmosphere. This project will study and implement such mixing, including the newly described physical phenomenon of wave-induced turbulence, into a variety of models. As a result, wave models and global climate models will be coupled. It is believed that such coupling will enhance our ability to predict the impact of global climate change. As part of the project, predictions of changes to the global wave climate will be developed. Such predictions are important to a nation such as Australia where significant population and economic assets are located close to the coast.Read moreRead less
Physical mechanisms responsible for stable isotope ratios in precipitation over southeast Australia. The project will identify the physical mechanisms which determine the stable isotopic content (specifically of 18O and deuterium) in southeast Australian precipitation events. An aim is to deduce, in a physically-based manner, relevant weather and climate information from the isotopic signals. The research will be founded on a comprehensive analysis of the three dimensional atmospheric structure ....Physical mechanisms responsible for stable isotope ratios in precipitation over southeast Australia. The project will identify the physical mechanisms which determine the stable isotopic content (specifically of 18O and deuterium) in southeast Australian precipitation events. An aim is to deduce, in a physically-based manner, relevant weather and climate information from the isotopic signals. The research will be founded on a comprehensive analysis of the three dimensional atmospheric structure in the period leading up to the precipitation events, and on the innovative use of a coupled atmosphere-ocean model which can account for much of the physical complexity of the relevant processes.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100041
Funder
Australian Research Council
Funding Amount
$100,000.00
Summary
A high-resolution isotope facility for low cost analysis of water, plant, and soil/sediment samples to understand environmental change. The most significant environmental challenges facing Australia include ensuring sustainable management of our water resources and conservation of both terrestrial and marine biodiversity, particularly in the face of our changing climate and land-use. The new instruments will accelerate progress across a number of projects aimed at understanding the developme ....A high-resolution isotope facility for low cost analysis of water, plant, and soil/sediment samples to understand environmental change. The most significant environmental challenges facing Australia include ensuring sustainable management of our water resources and conservation of both terrestrial and marine biodiversity, particularly in the face of our changing climate and land-use. The new instruments will accelerate progress across a number of projects aimed at understanding the development of groundwater resources, the relative dependency of ecosystems on groundwater versus soil and surface water, and an assessment of the likely impacts of altered hydrology, especially dewatering and salinisation, on ecosystems. In addition, they will also be used to extend our knowledge of climate variability in the recent past and increase understanding of critical marine resources.Read moreRead less