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Microplastic infiltration of food webs: cells to ecosystem consequences. Using trophic ecological theory as a framework, this project aims to provide the first comprehensive assessment of the fate and effects of microplastics. Plastic pollution is a persistent and increasing problem. Plastics are degraded into small particles, called microplastics, which are ingested by animals. The project aims to develop much-needed techniques to measure microplastics in biological tissue and apply these techn ....Microplastic infiltration of food webs: cells to ecosystem consequences. Using trophic ecological theory as a framework, this project aims to provide the first comprehensive assessment of the fate and effects of microplastics. Plastic pollution is a persistent and increasing problem. Plastics are degraded into small particles, called microplastics, which are ingested by animals. The project aims to develop much-needed techniques to measure microplastics in biological tissue and apply these techniques in food web studies to determine the capacity of microplastics to transfer from the environment into animals, and how microplastics move through a food web to affect biological diversity and animal health. This information will be used to complete the first risk assessment for microplastics in a major coastal habitat.Read moreRead less
Clothes, fibres and filters that reduce pollution by micro and nano debris. This project aims to provide scientifically verified methods to avoid, intercept and redesign products that cause the most abundant type of marine plastic pollution – clothing fibres - which has increased by over 450% in 60 years. It will determine how natural and plastic fibres, clothing brands and washing machine filters, alter fibre emissions and ecological impacts. This will enable protocols to improve products and t ....Clothes, fibres and filters that reduce pollution by micro and nano debris. This project aims to provide scientifically verified methods to avoid, intercept and redesign products that cause the most abundant type of marine plastic pollution – clothing fibres - which has increased by over 450% in 60 years. It will determine how natural and plastic fibres, clothing brands and washing machine filters, alter fibre emissions and ecological impacts. This will enable protocols to improve products and the environment, and reduce health risks that will benefit the public, government regulation and companies in designing "eco-friendly" products.Read moreRead less
The ecological impact of large carnivore restoration. This project aims to assess the ecological changes that have arisen due to the repatriation of estuarine crocodiles to Australian ecosystems. It is significant because the restoration provides a rare opportunity to empirically test changes in ecosystem processes under varying degrees of large carnivore predation pressure. Expected outcomes include improved understanding of the processes that govern the strength of predator-ecosystem interacti ....The ecological impact of large carnivore restoration. This project aims to assess the ecological changes that have arisen due to the repatriation of estuarine crocodiles to Australian ecosystems. It is significant because the restoration provides a rare opportunity to empirically test changes in ecosystem processes under varying degrees of large carnivore predation pressure. Expected outcomes include improved understanding of the processes that govern the strength of predator-ecosystem interactions and an ability to quantify the biomass, social structure, and behaviours of predators required to influence these processes. Benefits should include improvements in how the ecological role of large carnivores is measured, and when and where carnivore populations should be culled or conserved.Read moreRead less
Top-down rehydration: role of multiple water sources in mangrove function. This project aims to combine cutting-edge analytical and imaging techniques to assess contributions of atmospheric water sources to shoot-water balances, identify leaf traits associated with top-down rehydration, and determine the relative importance of different sources of water used by mangroves in maintenance of photosynthetic carbon assimilation along natural gradients in salinity and aridity. The capacity of shoots ....Top-down rehydration: role of multiple water sources in mangrove function. This project aims to combine cutting-edge analytical and imaging techniques to assess contributions of atmospheric water sources to shoot-water balances, identify leaf traits associated with top-down rehydration, and determine the relative importance of different sources of water used by mangroves in maintenance of photosynthetic carbon assimilation along natural gradients in salinity and aridity. The capacity of shoots to absorb atmospheric water could profoundly affect the diversity, survival and productivity of mangroves where high soil salinity limits water uptake by roots, particularly during hot, dry conditions.Read moreRead less
The contribution of human/marine herbivore interactions to reef degradation. This project aims to define how interactions between human society and herbivores influence marine ecosystem structure and function. It will analyse geographic patterns from recent systematic sampling of reef communities worldwide and study fish, macro-invertebrate and meso-grazer herbivory to identify herbivores’ role in the collapse and recovery of reef ecosystems. This project will examine the match between a critica ....The contribution of human/marine herbivore interactions to reef degradation. This project aims to define how interactions between human society and herbivores influence marine ecosystem structure and function. It will analyse geographic patterns from recent systematic sampling of reef communities worldwide and study fish, macro-invertebrate and meso-grazer herbivory to identify herbivores’ role in the collapse and recovery of reef ecosystems. This project will examine the match between a critical ecosystem function and community structure across local to global scales, including the identification of non-linearities and interactions involving human effects on this process. This research is expected to safeguard marine ecosystems from collapse.Read moreRead less
Utilising plant-sediment-feedbacks to enhance seagrass restoration. This project aims to investigate the role of sediment microbes in promoting the health of threatened seagrass species across Australia. This project expects to create new knowledge for enhancing restoration success for seagrasses by integrating macro and micro-ecology, environmental genomics, plant ecology and ecosystem function (e.g. nutrient and biogeochemistry cycling). Expected outcomes are new knowledge to enhance seagrass ....Utilising plant-sediment-feedbacks to enhance seagrass restoration. This project aims to investigate the role of sediment microbes in promoting the health of threatened seagrass species across Australia. This project expects to create new knowledge for enhancing restoration success for seagrasses by integrating macro and micro-ecology, environmental genomics, plant ecology and ecosystem function (e.g. nutrient and biogeochemistry cycling). Expected outcomes are new knowledge to enhance seagrass restoration utilising sediment microbes that can be integrated into management and policy. This project should provide significant benefits, such as the development of key strategic alliances to enhance management of seagrasses, and the ecosystem services, and economic and social benefits they provide.Read moreRead less
Uncovering the microbial ecology of Australia's coasts: Friends next-door or enemies at the gate? The health and function of coastal habitats is mediated by an abundant community of marine microbes, which perform essential ecosystem services. However, some microbes can periodically disrupt the biogeochemical balance of coastal habitats, while others are dangerous pathogens that cause human illness. Anthropogenic impacts may underpin episodic shifts in the balance of ‘good’ and ‘bad’ coastal micr ....Uncovering the microbial ecology of Australia's coasts: Friends next-door or enemies at the gate? The health and function of coastal habitats is mediated by an abundant community of marine microbes, which perform essential ecosystem services. However, some microbes can periodically disrupt the biogeochemical balance of coastal habitats, while others are dangerous pathogens that cause human illness. Anthropogenic impacts may underpin episodic shifts in the balance of ‘good’ and ‘bad’ coastal microbes, but the mechanisms and dynamics of these shifts are undefined. This project will unite cutting-edge analytical tools, including microfluidics and ecogenomics, to redefine our understanding of the microbiology of the Australian coast, providing transformative new insights for preserving our aquatic backyard and protecting our health.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE220100079
Funder
Australian Research Council
Funding Amount
$423,582.00
Summary
Redefining success in marine ecosystem restoration. This project aims to improve evaluations of marine ecosystem restoration through the measurement of key animal health metrics, and automated monitoring using artificial intelligence. This project expects to generate unique knowledge about why ecosystem restoration succeeds or fails, and improve our understanding of how animal data can better inform future restoration projects. The expected outcomes will enhance our capacity to use new and effic ....Redefining success in marine ecosystem restoration. This project aims to improve evaluations of marine ecosystem restoration through the measurement of key animal health metrics, and automated monitoring using artificial intelligence. This project expects to generate unique knowledge about why ecosystem restoration succeeds or fails, and improve our understanding of how animal data can better inform future restoration projects. The expected outcomes will enhance our capacity to use new and efficient techniques to monitor and evaluate ecosystem restoration in a more ecologically valid way. Benefits include more effective ecosystem restoration, wildlife conservation, and the enhancement of ecosystem services including sustainable fishing and eco-tourism.Read moreRead less
Genetic solution or dilution: can selective breeding future-proof oysters? This project aims to test whether the flow of beneficial genes from farmed oysters into wild oysters can make natural oyster beds and the ecological communities that they support more resilient to environmental change. Wild oysters are critical to the function of coastal ecosystems. However, wild oyster populations are threatened by environmental change in Australia and around the world. Selectively bred oysters bearing s ....Genetic solution or dilution: can selective breeding future-proof oysters? This project aims to test whether the flow of beneficial genes from farmed oysters into wild oysters can make natural oyster beds and the ecological communities that they support more resilient to environmental change. Wild oysters are critical to the function of coastal ecosystems. However, wild oyster populations are threatened by environmental change in Australia and around the world. Selectively bred oysters bearing stress resistance genotypes are now commercially farmed in many estuaries on Australia's east coast and may be used to bolster wild oyster populations. This project endeavours to develop novel genetic strategies to future-proof oysters. Thus, the outcome of this project has potential to benefit entire ecosystems that depend upon oysters.Read moreRead less
Genes to ecosystems: drivers of resilience in underwater marine forests. This project seeks to determine if population connectivity and thermal stress limits the ecological performance and capacity for biological adaptation of seaweed forests to environmental change. The rates of warming in Australia’s temperate marine environments are among the fastest in the world, threatening seaweed forests that support rich marine life and generate substantial socioeconomic values. By integrating studies of ....Genes to ecosystems: drivers of resilience in underwater marine forests. This project seeks to determine if population connectivity and thermal stress limits the ecological performance and capacity for biological adaptation of seaweed forests to environmental change. The rates of warming in Australia’s temperate marine environments are among the fastest in the world, threatening seaweed forests that support rich marine life and generate substantial socioeconomic values. By integrating studies of connectivity among seaweed forests along replicate coastlines on both sides of the Australian continent, with field and breeding experiments, this project expects to expose the role of genetic diversity in mediating ecological resilience to rapid environmental change.Read moreRead less