Movement, migration and social networks in wild shark populations. Sharks are vital components of marine ecosystems and contribute significantly to ecotourism and fisheries. Due to their slow rate of growth and reproduction, sharks are susceptible to over exploitation. A lack of knowledge regarding their behaviour and movement patterns is a key impediment to effective management. This project aims to examine social interactions and migration patterns of Port Jackson sharks using a unique combina ....Movement, migration and social networks in wild shark populations. Sharks are vital components of marine ecosystems and contribute significantly to ecotourism and fisheries. Due to their slow rate of growth and reproduction, sharks are susceptible to over exploitation. A lack of knowledge regarding their behaviour and movement patterns is a key impediment to effective management. This project aims to examine social interactions and migration patterns of Port Jackson sharks using a unique combination of genetic techniques, novel acoustic tag technology, behavioural manipulations and modern social network analysis. Once verified, the approach developed can be applied to other marine predators of particular management concern. The data generated will directly inform fisheries and conservation management policy.Read moreRead less
The impact of environmental change on larval energetics of molluscs on the southeast coast of Australia. This project will investigate the impact of environmental change on larval energetics of molluscs on the southeast (SE) coast of Australia. The SE coast of Australia is a climate hotspot characterised by rising ocean temperatures, fluctuations in salinity and we expect in the near future ocean acidification (OA). Mollusc larvae show extreme sensitivity to OA, but the impacts of other stressor ....The impact of environmental change on larval energetics of molluscs on the southeast coast of Australia. This project will investigate the impact of environmental change on larval energetics of molluscs on the southeast (SE) coast of Australia. The SE coast of Australia is a climate hotspot characterised by rising ocean temperatures, fluctuations in salinity and we expect in the near future ocean acidification (OA). Mollusc larvae show extreme sensitivity to OA, but the impacts of other stressors remains unknown. It is predicted that OA will reduce the capacity of larvae to cope with temperature and salinity, particularly when food supply is low and in populations which have had no previous exposure to OA. Understanding the response of mollusc larvae to environmental change will support ecologically and economically significant mollusc populations over this century.Read moreRead less
Lost oceans? Threats to Pacific Island maritime claims and response options. This project aims to examine the potential impacts of a recent and major evolution in the law of the sea on the capacity of islands to generate broad maritime claims, with particular reference to the Pacific Island countries. It is the first systematic geospatial/legal analysis of maritime claims from Pacific islands in light of the recent South China Sea landmark international judicial decision. Expected outcomes inc ....Lost oceans? Threats to Pacific Island maritime claims and response options. This project aims to examine the potential impacts of a recent and major evolution in the law of the sea on the capacity of islands to generate broad maritime claims, with particular reference to the Pacific Island countries. It is the first systematic geospatial/legal analysis of maritime claims from Pacific islands in light of the recent South China Sea landmark international judicial decision. Expected outcomes include a detailed risk assessment to inform local policy-makers and an enhanced capacity to protect rights over valuable marine resources, contributing to food and regional security.Read moreRead less
Rewiring marine food webs: Predicting consequences of species range shifts. This project aims to predict how changes in climate-driven species distributions affect shallow marine communities globally. Environmental change affects the structure, resilience and productivity of coastal marine ecosystems at regional and global scales. This project will combine global species distribution and trait databases, existing experimental data and targeted field sampling to develop, test and apply an integra ....Rewiring marine food webs: Predicting consequences of species range shifts. This project aims to predict how changes in climate-driven species distributions affect shallow marine communities globally. Environmental change affects the structure, resilience and productivity of coastal marine ecosystems at regional and global scales. This project will combine global species distribution and trait databases, existing experimental data and targeted field sampling to develop, test and apply an integrated modelling platform to predict how global warming-driven changes in species distributions and their interactions affect the structure and dynamics of shallow marine communities. This project addresses a knowledge gap on how species’ redistributions and trophic dynamics produce communities, and aims to forecast future species abundances for sustainable marine ecosystem management.Read moreRead less
Understanding the effect of small-scale ocean process on tuna populations – a new tool to forecast tuna distributions for use in fisheries management. The western and central Pacific Ocean supports the world’s largest tuna fishery with catches contributing up to 40 per cent of revenue for many Pacific communities. These nations are dependent on these fisheries for livelihoods and economic development. Continued sustainable management of this valuable resource in the face of rapid population grow ....Understanding the effect of small-scale ocean process on tuna populations – a new tool to forecast tuna distributions for use in fisheries management. The western and central Pacific Ocean supports the world’s largest tuna fishery with catches contributing up to 40 per cent of revenue for many Pacific communities. These nations are dependent on these fisheries for livelihoods and economic development. Continued sustainable management of this valuable resource in the face of rapid population growth and climate variability and change is a challenge. Using observationally derived information of skipjack tuna, the project aims to develop a novel tuna behavioural model. This is intended to be integrated into a state-of-the-art biophysical model at resolutions capable of reproducing critical meso-scale processes, providing projections of tuna distributions that aim to aid in developing sustainable management practices.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE160100086
Funder
Australian Research Council
Funding Amount
$850,000.00
Summary
A Single-Molecule Super-Resolution Microscopy Facility in Western Australia. A single-molecule super-resolution microscopy facility in Western Australia:
The project aims to establish a facility combining single-molecule imaging with super-resolution microscopy to enable biologists in Western Australia to resolve and directly observe interacting macromolecules in plants, animals and organisms, Interacting macromolecules form the basis of cell biology. Imaging and characterising such interaction ....A Single-Molecule Super-Resolution Microscopy Facility in Western Australia. A single-molecule super-resolution microscopy facility in Western Australia:
The project aims to establish a facility combining single-molecule imaging with super-resolution microscopy to enable biologists in Western Australia to resolve and directly observe interacting macromolecules in plants, animals and organisms, Interacting macromolecules form the basis of cell biology. Imaging and characterising such interactions in living cells and tissues has become possible with the latest molecular imaging techniques and super-resolution optical microscopy (with spatial resolutions of 20 nanometres or better). The facility seeks to advance science across diverse regional priorities in agriculture, environment, marine ecology, medicine and health.Read moreRead less
Can consistent individual differences in metabolic rate explain animal personality? Implications for fish and aquaculture in a warming climate. This project will determine if consistent individual differences in metabolic rate affect behaviour, growth, and reproduction in fish. If so, then we need to prepare for the fact that a warming climate will lead to reductions in fish growth and reproduction, because rising temperature directly increases metabolism and therefore maintenance costs.
Do marine reserve networks work? Larval connectivity, sustainable harvesting and ecological resilience. The Great Barrier Reef is a globally iconic marine ecosystem and benefits from the world's largest network of no-take reserves. While we know reserves contain more and bigger fish, several key questions about how reserves contribute to sustainable harvesting, protecting biodiversity and resisting climate change remain unanswered. Answers depend on a new understanding of the degree to which fis ....Do marine reserve networks work? Larval connectivity, sustainable harvesting and ecological resilience. The Great Barrier Reef is a globally iconic marine ecosystem and benefits from the world's largest network of no-take reserves. While we know reserves contain more and bigger fish, several key questions about how reserves contribute to sustainable harvesting, protecting biodiversity and resisting climate change remain unanswered. Answers depend on a new understanding of the degree to which fish population on different reefs are connected, and whether or not reserve networks help sustain these linkages. This project will use new technologies to measure the transport of fish larvae between reefs, to assess strengths and weaknesses of the reserve network, and examine ways to improve species protection and sustainable harvesting in a changing climate.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100055
Funder
Australian Research Council
Funding Amount
$290,000.00
Summary
A coupled liquid chromatography mass spectrometer as a core component of an Australian research facility for marine microbial biotoxins. A coupled liquid chromatography mass spectrometer as a core component of an Australian research facility for marine microbial biotoxins: This project will establish an Australian research facility for marine microbial biotoxins. The requested core instrument is a liquid chromatography mass spectrometer to analyse and quantify microbial toxins at ultra-trace qua ....A coupled liquid chromatography mass spectrometer as a core component of an Australian research facility for marine microbial biotoxins. A coupled liquid chromatography mass spectrometer as a core component of an Australian research facility for marine microbial biotoxins: This project will establish an Australian research facility for marine microbial biotoxins. The requested core instrument is a liquid chromatography mass spectrometer to analyse and quantify microbial toxins at ultra-trace quantities against complex sample backgrounds. Specialists in diverse areas of marine ecology and chemistry from three partner universities will team up to focus their research on novel biotoxins and marine natural products. This research is significant in developing a capability to swiftly respond to the emergence and outbreak of novel toxins. This facility will foster the collaboration with the partner organisation, the Cawthron Institute, a world leading research institute of marine biotoxins.Read moreRead less
Future fisheries under climate change: the missing role of zooplankton. This project aims to develop the first global ecosystem model with a more realistic representation of zooplankton. Fish are the main source of protein for 3 billion people, yet fish catches are declining. Current models of future fish biomass under climate change do not consider the complex role that zooplankton play in transferring energy from phytoplankton to fish. By resolving the link between phytoplankton and fish, this ....Future fisheries under climate change: the missing role of zooplankton. This project aims to develop the first global ecosystem model with a more realistic representation of zooplankton. Fish are the main source of protein for 3 billion people, yet fish catches are declining. Current models of future fish biomass under climate change do not consider the complex role that zooplankton play in transferring energy from phytoplankton to fish. By resolving the link between phytoplankton and fish, this project will vastly improve estimates of future global fisheries production and regional variation. Such knowledge is vital for future food security in Australia and globally, and also to understand the role of zooplankton in carbon export in the ocean.Read moreRead less