Discovery Early Career Researcher Award - Grant ID: DE180100017
Funder
Australian Research Council
Funding Amount
$404,950.00
Summary
A pictorial and geochemical history of Great Barrier Reef changes. This project aims to determine the timing and associated drivers behind dramatic changes in coral communities on reef flat environments since European settlement. It will use Uranium-Thorium dating, palaeoecological and geochemical techniques, as well as spatial elevation surveys to determine the timing and cause of ecological transition for inshore coral communities. This project will contribute baseline knowledge on the timing ....A pictorial and geochemical history of Great Barrier Reef changes. This project aims to determine the timing and associated drivers behind dramatic changes in coral communities on reef flat environments since European settlement. It will use Uranium-Thorium dating, palaeoecological and geochemical techniques, as well as spatial elevation surveys to determine the timing and cause of ecological transition for inshore coral communities. This project will contribute baseline knowledge on the timing and mechanisms associated with dramatic declines in coral cover on inshore reefs of the world heritage listed Great Barrier Reef, and provide a robust scientific foundation for effective monitoring.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180100391
Funder
Australian Research Council
Funding Amount
$386,500.00
Summary
Island resilience to tropical cyclones and rising sea levels. This project aims to produce a dynamic model to address the global problem of low-lying island inundation following high-energy events, such as tropical cyclones and storm surges. These events threaten coastal habitats and biodiversity, and in worst cases, displace human populations. The model will identify islands at risk to inundation thereby enabling governments to adopt appropriate mitigation and/or adaptation strategies to impr ....Island resilience to tropical cyclones and rising sea levels. This project aims to produce a dynamic model to address the global problem of low-lying island inundation following high-energy events, such as tropical cyclones and storm surges. These events threaten coastal habitats and biodiversity, and in worst cases, displace human populations. The model will identify islands at risk to inundation thereby enabling governments to adopt appropriate mitigation and/or adaptation strategies to improve outcomes for island economic, societal and biological values.Read moreRead less
Size matters: evolution of body size of species in deep time. Global warming is predicted to form 'sick seas' and cause widespread stunted growth of taxa and ecosystem-wide dwarfism. Exactly how this works requires substantiation of both short-term empirical and experimental research as well as evidence from the deep-time fossil record. Using the high-resolution marine fossil record from the Permian-Triassic mass extinction ~252 million years ago, the most severe in the history of animals, this ....Size matters: evolution of body size of species in deep time. Global warming is predicted to form 'sick seas' and cause widespread stunted growth of taxa and ecosystem-wide dwarfism. Exactly how this works requires substantiation of both short-term empirical and experimental research as well as evidence from the deep-time fossil record. Using the high-resolution marine fossil record from the Permian-Triassic mass extinction ~252 million years ago, the most severe in the history of animals, this project will investigate how body size of marine species and communities evolved in response to the mass extinction and rapid global warming. It is expected that the project findings will help better understand the links between global warming, anoxia, hypercapnia, euxinia, ocean acidification, and species adaptation and evolution.Read moreRead less