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Discovery Early Career Researcher Award - Grant ID: DE190101307
Funder
Australian Research Council
Funding Amount
$421,824.00
Summary
A new nano-geochronology approach to global Earth processes. This project aims to develop a new nano-geochronology tool. Geochronology is the science of determining the ages of rocks and geological events, and is key to answering fundamental questions of planetary evolution, the geological processes that shaped our Earth, and evolution of life and past climates. Many valuable mineral phases are too small to be dated by conventional methods. The potential that nano-geochronology has to unlock inf ....A new nano-geochronology approach to global Earth processes. This project aims to develop a new nano-geochronology tool. Geochronology is the science of determining the ages of rocks and geological events, and is key to answering fundamental questions of planetary evolution, the geological processes that shaped our Earth, and evolution of life and past climates. Many valuable mineral phases are too small to be dated by conventional methods. The potential that nano-geochronology has to unlock information otherwise untraceable remains largely unexplored. The development and application of nano-geochronology will improve our understanding of the Australian crust and the field of geological mapping, which largely supports mineral exploration.Read moreRead less
Predation as a major ecological driver of early animal evolution. This project aims to address one of the biggest questions about the early evolutionary history of complex life: was predation a driving force behind the major diversification of animals over 500 million years ago? This innovative study will extend the application of computational biomechanics and use extensive fossil collections to quantify the performance of predators and the evolutionary responses of prey species. Anticipated ou ....Predation as a major ecological driver of early animal evolution. This project aims to address one of the biggest questions about the early evolutionary history of complex life: was predation a driving force behind the major diversification of animals over 500 million years ago? This innovative study will extend the application of computational biomechanics and use extensive fossil collections to quantify the performance of predators and the evolutionary responses of prey species. Anticipated outcomes and benefits include a paradigm shift in knowledge of how predator-prey dynamics shaped the first animal ecosystems, new approaches for studying the functional morphology and microevolutionary patterns of extinct invertebrates, and highlighting the international significance of Australia’s natural heritage.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE220101558
Funder
Australian Research Council
Funding Amount
$386,762.00
Summary
Exploring the nexus between global palaeogeography and the rise of animals. The Ediacaran–Cambrian periods (635–485 million years ago) capture one of the most critical events in the history of life, but are rarely the focus of global-scale palaeogeographic modelling. By employing a holistic, multi-proxy approach that synthesises vast fossil and geological datasets, this project aims to reconstruct continental positions to determine how shifting landmasses influenced the evolution of the first co ....Exploring the nexus between global palaeogeography and the rise of animals. The Ediacaran–Cambrian periods (635–485 million years ago) capture one of the most critical events in the history of life, but are rarely the focus of global-scale palaeogeographic modelling. By employing a holistic, multi-proxy approach that synthesises vast fossil and geological datasets, this project aims to reconstruct continental positions to determine how shifting landmasses influenced the evolution of the first complex animals. Expected outcomes and benefits include a new, animated global model of continental evolution that can be used across a broad range of fields, particularly for studies investigating the development of Earth System processes and the biosphere in deep time, with potential applications in resource exploration.Read moreRead less
Early Palaeozoic radiolarian evolution. This project will apply a new transformative technology, X-ray micro computed tomography, to the study of Early Palaeozoic (530-300 million year old) radiolarian microfossils. It is expected that this will allow, for the first time, non-destructive examination to elucidate the internal skeletal architecture of these fossils that is critical to understanding their evolution. Computer reconstruction of three-dimensional images will reveal details upon which ....Early Palaeozoic radiolarian evolution. This project will apply a new transformative technology, X-ray micro computed tomography, to the study of Early Palaeozoic (530-300 million year old) radiolarian microfossils. It is expected that this will allow, for the first time, non-destructive examination to elucidate the internal skeletal architecture of these fossils that is critical to understanding their evolution. Computer reconstruction of three-dimensional images will reveal details upon which an understanding of early phylogenetic relationships within this phylum can be developed. This in turn will allow realisation of the full biostratigraphic potential of this important long-ranging group of marine protozoans that commonly occur in great abundance in deep marine sedimentary rocks.Read moreRead less
The reptile-mammal jaw transition as revealed by 3D imaging, embryology, and computational biomechanics: new approaches to some age old questions. The extraordinary transformation of the mammalian middle ear through biomechanical 're-tooling' of the ancestral reptilian jaw joint, also recapitulated in mammalian development, yielded the greatly improved feeding and hearing efficiency that are key to the mammalian success story. Building on recent methodological advances, this project will employ ....The reptile-mammal jaw transition as revealed by 3D imaging, embryology, and computational biomechanics: new approaches to some age old questions. The extraordinary transformation of the mammalian middle ear through biomechanical 're-tooling' of the ancestral reptilian jaw joint, also recapitulated in mammalian development, yielded the greatly improved feeding and hearing efficiency that are key to the mammalian success story. Building on recent methodological advances, this project will employ cutting-edge two-dimensional protocols to explain these mechanical details of this transition. This includes integration of the first undistorted embryological soft-tissue evidence for muscular arrangements in the transitioning jaw. Through vastly improving on conventional two-dimensional approaches, the project will maintain Australia's leading position in the fast developing field of virtual biomechanics.Read moreRead less
Microbially induced calcium carbonate precipitation in different substrates. Carbonates in the form of limestone represent an important reservoir of carbon on earth. They are recorded in several natural geological formations as corals, stromatolites, beach rocks. Microbes play an important role in the formation as well as dissolution of carbonates during microbially induced calcium carbonate precipitation (MICP) reactions on different substrates in natural and built environments. Much of our kno ....Microbially induced calcium carbonate precipitation in different substrates. Carbonates in the form of limestone represent an important reservoir of carbon on earth. They are recorded in several natural geological formations as corals, stromatolites, beach rocks. Microbes play an important role in the formation as well as dissolution of carbonates during microbially induced calcium carbonate precipitation (MICP) reactions on different substrates in natural and built environments. Much of our knowledge on MICP is limited due to poor understanding of the reaction kinetics at a molecular level. This project will develop new methods to enable and advance the knowledge of MICP process with profound implications for understanding natural geological formations as well as widen the scope of current engineering applications.Read moreRead less
Wave-ice models of Antarctic sea ice. This project aims to design and execute autonomous observations above (unmanned aerial vehicles), below (autonomous underwater vehicles) and within (wave-ice interaction buoys) sea ice on international Antarctic research voyages. The project intends to advance the parameterisation of wave-ice interaction, critical to the seasonal advance and retreat of Antarctic sea ice, in climate models that do not reproduce the observed trends in regional Antarctic sea ic ....Wave-ice models of Antarctic sea ice. This project aims to design and execute autonomous observations above (unmanned aerial vehicles), below (autonomous underwater vehicles) and within (wave-ice interaction buoys) sea ice on international Antarctic research voyages. The project intends to advance the parameterisation of wave-ice interaction, critical to the seasonal advance and retreat of Antarctic sea ice, in climate models that do not reproduce the observed trends in regional Antarctic sea ice extent. The project expects to improve prediction of sea ice’s responses and feedbacks to changes in ocean and atmospheric forcing around the Southern Ocean. This work should place Australia at the forefront of polar climate research. Greater accuracy in climate projections will help to optimise the balance between human populations, economic growth and environmental protection in an uncertain future.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE190101423
Funder
Australian Research Council
Funding Amount
$370,000.00
Summary
Revealing the diets of dinosaurs through the complexity and shape of teeth. This project aims to reveal the role of diet in the spread and subsequent dominance of Mesozoic dinosaurs. Previous research has revealed much about dinosaur anatomy and diversity, but their diets remain broadly classified into two categories, herbivores and carnivores. This project will use 3D scans of dinosaur teeth to calculate anatomical indicators of diet, and interpret diet as a continuous variable which will permi ....Revealing the diets of dinosaurs through the complexity and shape of teeth. This project aims to reveal the role of diet in the spread and subsequent dominance of Mesozoic dinosaurs. Previous research has revealed much about dinosaur anatomy and diversity, but their diets remain broadly classified into two categories, herbivores and carnivores. This project will use 3D scans of dinosaur teeth to calculate anatomical indicators of diet, and interpret diet as a continuous variable which will permit unprecedented evolutionary analyses of dinosaur ecology. Anticipated outcomes include an innovative framework with which to reconstruct the ecological diversity of dinosaurs from Australia and around the world and understand the processes that led to their success for over 150 million years.Read moreRead less
Reading the past to predict future biodiversity: a deep-time perspective. The extent of human-moderated impact on ecosystems is rapidly increasing. To date, most current research in this field is based on short-term observations or experiments. By examining the characteristics of species and ecosystem response to climate change from a major geological Ice Age ~320-265 million years ago in eastern Australia, this study will investigate how marine species and ecological communities evolved in resp ....Reading the past to predict future biodiversity: a deep-time perspective. The extent of human-moderated impact on ecosystems is rapidly increasing. To date, most current research in this field is based on short-term observations or experiments. By examining the characteristics of species and ecosystem response to climate change from a major geological Ice Age ~320-265 million years ago in eastern Australia, this study will investigate how marine species and ecological communities evolved in response to repeated glacial/interglacial cycles and associated warming/cooling climate changes. Expected findings will help to better understand the long-term links between global warming/cooling climate regimes, sea levels, changing sea-water temperature and chemistry, and species and ecosystem responses to these drivers.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE180100160
Funder
Australian Research Council
Funding Amount
$297,463.00
Summary
Femtosecond laser micropyrolysis gas chromatograph-mass spectrometer. This project aims to build a femtosecond-laser, micropyrolysis gas-chromatographmass spectrometer. The facility will have the capability to selectively analyse very small petrographically-recognisable organic components, hence bridging the analytical gap between organic petrography and organic geochemistry. The project aims to understand the early evolution of life, the response of the biosphere to mass extinction, the migrati ....Femtosecond laser micropyrolysis gas chromatograph-mass spectrometer. This project aims to build a femtosecond-laser, micropyrolysis gas-chromatographmass spectrometer. The facility will have the capability to selectively analyse very small petrographically-recognisable organic components, hence bridging the analytical gap between organic petrography and organic geochemistry. The project aims to understand the early evolution of life, the response of the biosphere to mass extinction, the migration of fluids in petroleum reservoirs, the heterogeneity of organic matter in shale gas reservoirs, and the composition of macromolecules in biominerals and macerals. The facility will contribute to a broad range of Australia’s theoretical and applied problems in geoscience and geobiology.Read moreRead less