Effect of deep-sea drilling on sustainability of deep-sea ecosystems. Offshore oil and gas production makes a significant contribution to the Australian economy and enhances our energy security. Australia's vast deep-sea reserves of hydrocarbons lie on the NW Shelf and in Bass Strait, ecological 'hot spots' that are extremely vulnerable to the impact of exploration, extraction and production. Using deep-sea equipment, we will conduct the field experiments that are essential to understanding the ....Effect of deep-sea drilling on sustainability of deep-sea ecosystems. Offshore oil and gas production makes a significant contribution to the Australian economy and enhances our energy security. Australia's vast deep-sea reserves of hydrocarbons lie on the NW Shelf and in Bass Strait, ecological 'hot spots' that are extremely vulnerable to the impact of exploration, extraction and production. Using deep-sea equipment, we will conduct the field experiments that are essential to understanding these ecosystems and the impact of deep-sea structures. Our advances will produce data and develop methodologies that will make Australia a world leader in reconciling our deep-sea energy and environmental needs.Read moreRead less
Fish ear stones for monitoring changes in environmental conditions. The ear-stones (=otoliths) of territorial reef fish could provide environmental records over a great latitudinal range. Important environmental variation includes upwelling, riverine input, the southern oscillation and climate change. Laser mass-spectrometry will be used to resolve spatial and temporal variation in environmental conditions experienced in tropical and temperate waters over periods of up to 50 years. Experiments ....Fish ear stones for monitoring changes in environmental conditions. The ear-stones (=otoliths) of territorial reef fish could provide environmental records over a great latitudinal range. Important environmental variation includes upwelling, riverine input, the southern oscillation and climate change. Laser mass-spectrometry will be used to resolve spatial and temporal variation in environmental conditions experienced in tropical and temperate waters over periods of up to 50 years. Experiments will be done to determine the duration of events (ie changes in water chemistry) that are reliably recorded. Environmental variation is known to influence fish populations, including commercial species, but data on frequency and spatial extent of these impacts are few.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989608
Funder
Australian Research Council
Funding Amount
$190,000.00
Summary
The Heron Island Climate Change Observatory: An In-Situ Ocean Acidification and Carbonate Chemistry Monitoring Platform. Climate change and ocean acidification are widely recognized as key threats to Australia's natural ecosystems, yet we are currently ill-equipped to respond due to poor knowledge of the scale/nature of the impacts. The Heron Island Climate Change Observatory will establish key infrastructure that will rapidly improve our understanding of the impacts of ocean acidification whic ....The Heron Island Climate Change Observatory: An In-Situ Ocean Acidification and Carbonate Chemistry Monitoring Platform. Climate change and ocean acidification are widely recognized as key threats to Australia's natural ecosystems, yet we are currently ill-equipped to respond due to poor knowledge of the scale/nature of the impacts. The Heron Island Climate Change Observatory will establish key infrastructure that will rapidly improve our understanding of the impacts of ocean acidification which is important to local communities and the nation given that coral reefs support over $6 billion in revenue (and employ 60,000 people) each year. This critically important information is essential to the management and protection of Australia's coral reefs, including the Great Barrier Reef.
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The impact of ocean acidification on the fertilization, larval development and recruitment of key Australian marine organisms. This work will define the potential vulnerability for Australian marine ecosystems that arises from the rapid acidification of Australia's coastal environments by rising atmospheric carbon dioxide. Our preliminary data suggest that the early life history stages of a wide range of marine species are very sensitive to the impact of ocean acidification. At present, almost ....The impact of ocean acidification on the fertilization, larval development and recruitment of key Australian marine organisms. This work will define the potential vulnerability for Australian marine ecosystems that arises from the rapid acidification of Australia's coastal environments by rising atmospheric carbon dioxide. Our preliminary data suggest that the early life history stages of a wide range of marine species are very sensitive to the impact of ocean acidification. At present, almost nothing is known about the impacts and implications of these changes. Without this knowledge, however, we are in a poor position as a nation to respond and adapt to these changes. We plan to explore this vulnerability for Australian marine organisms and develop a detailed understanding of its implications for Australia's marine ecosystems and associated industries. Read moreRead less
Ocean currents and genetic connectedness in a complex archipelago. To what extent are marine coastal communities ?open?, i.e. how often do the oceans carry larvae far from their point of spawning, and what influence does such ocean transport have on the spread of genetic information? These are some of the most fundamental questions of biological oceanography; the project will provide new answers by using an extremely detailed genetic data set from the Houtman Abrolhos Islands off Western Austra ....Ocean currents and genetic connectedness in a complex archipelago. To what extent are marine coastal communities ?open?, i.e. how often do the oceans carry larvae far from their point of spawning, and what influence does such ocean transport have on the spread of genetic information? These are some of the most fundamental questions of biological oceanography; the project will provide new answers by using an extremely detailed genetic data set from the Houtman Abrolhos Islands off Western Australian together with an advanced numerical ocean model especially suited to that environment and developed in Australia.Read moreRead less
Prediction of fishery year-class-strengths from larval growth and zooplankton size structure. The abundance of young fish produced in the ocean each year is highly variable, and banks or managers need to prepare for these future changes when the fish reach market size. Therefore many nations conduct special trawl surveys of juvenile fish each year, but these are expensive, particularly when Australia has over 200 commercially harvested fish. We propose that the growth of fish larvae, recorded as ....Prediction of fishery year-class-strengths from larval growth and zooplankton size structure. The abundance of young fish produced in the ocean each year is highly variable, and banks or managers need to prepare for these future changes when the fish reach market size. Therefore many nations conduct special trawl surveys of juvenile fish each year, but these are expensive, particularly when Australia has over 200 commercially harvested fish. We propose that the growth of fish larvae, recorded as daily growth rings within the earstone of undersized fish from the fishery, could predict future abundance. We will link growth to a cost-effective assessment of their zooplankton prey in spawning areas that lead to Australia's South East Trawl region.Read moreRead less
Effects of river plumes on nearshore ecosystems: organic matter flows and food web consequences. River plumes may subsidize nearshore food webs by exporting land-derived material and by stimulating marine phytoplankton production via nutrient delivery. Whereas previous documentation of the biological responses to plumes has been mostly limited to large rivers and to primary production, this project targets small systems that discharge directly onto open coasts, and focuses on the fate of plume ....Effects of river plumes on nearshore ecosystems: organic matter flows and food web consequences. River plumes may subsidize nearshore food webs by exporting land-derived material and by stimulating marine phytoplankton production via nutrient delivery. Whereas previous documentation of the biological responses to plumes has been mostly limited to large rivers and to primary production, this project targets small systems that discharge directly onto open coasts, and focuses on the fate of plume material. Work on carbon pathways will centre on pelagic and benthic food chains associated with plumes, and will also test whether nearshore waters and sandy beaches are coupled via onshore advection of plume material.Read moreRead less
Ecological patterns in deep-sea macro- and microbiotic communities on Vailulu'u Seamount and Ta'u Island, American Samoa. Volcanoes are viewed as large mountains that occasionally spurt smoke and debris into the air. But terrestrial volcanoes are but a small fraction of the volcanos on our planet, most simmer unobserved underneath the sea. The interdependence of biosphere, hydrosphere and lithosphere at volcanoes is amongst the most exciting and important research topics that help us understand ....Ecological patterns in deep-sea macro- and microbiotic communities on Vailulu'u Seamount and Ta'u Island, American Samoa. Volcanoes are viewed as large mountains that occasionally spurt smoke and debris into the air. But terrestrial volcanoes are but a small fraction of the volcanos on our planet, most simmer unobserved underneath the sea. The interdependence of biosphere, hydrosphere and lithosphere at volcanoes is amongst the most exciting and important research topics that help us understand how our planet has evolved and works through time. This project will used manned submersibles and remotely operated vehicles to conduct experiments at a submarine volcano that will help us understand how complex biological systems can form under such extreme conditions.Read moreRead less
The role of pulsed water events in structuring marine benthic communities along the southern Australian coastline. Marked differences in benthic community structure have been observed that are associated with pulsed cold-water events, possibly driven by internal wave phenomena. Such events have the potential to act as very important controls on both regional and local patterns of benthic biodiversity. To date, however, their effects and mechanisms of action have never been examined in Australi ....The role of pulsed water events in structuring marine benthic communities along the southern Australian coastline. Marked differences in benthic community structure have been observed that are associated with pulsed cold-water events, possibly driven by internal wave phenomena. Such events have the potential to act as very important controls on both regional and local patterns of benthic biodiversity. To date, however, their effects and mechanisms of action have never been examined in Australia. The fundamental outcome from this project will be the first assessment of the occurrence, geographical extent and ecological consequences of pulsed water phenomena along the southern Australian coastline.Read moreRead less
Diatom silica production under future ocean conditions, genes to biomes. This project aims to quantify how ocean warming and acidification will alter natural diatom assemblages and silica production rates to predict changes in the cycling and transfer of carbon and silicon in the future ocean. This project expects to generate new knowledge of environmental controls on diatom silicification and their ocean-scale implications by integrating the disciplines of physiology, molecular biology and quan ....Diatom silica production under future ocean conditions, genes to biomes. This project aims to quantify how ocean warming and acidification will alter natural diatom assemblages and silica production rates to predict changes in the cycling and transfer of carbon and silicon in the future ocean. This project expects to generate new knowledge of environmental controls on diatom silicification and their ocean-scale implications by integrating the disciplines of physiology, molecular biology and quantitative modelling. Expected outcomes include essential advancements in future simulations of marine productivity and silicon cycling and a deeper understanding of threats to marine life from climate change. This should provide significant benefits such as improved valuations on the sustainability of ocean ecosystems.Read moreRead less