Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100064
Funder
Australian Research Council
Funding Amount
$450,000.00
Summary
A facility for sensitive and precise isotopic dating of the earth's and extraterrestrial rocks. SPIDE2R will be a new generation mass spectrometer for very precise and sensitive dating and forensics applications in earth and planetary sciences, hydrology, climate studies, and nuclear and archaeological fingerprinting. The unprecedented sensitivity of this unique instrument will provide enhanced capabilities for solving long-standing problems requiring precise geological time resolution, as well ....A facility for sensitive and precise isotopic dating of the earth's and extraterrestrial rocks. SPIDE2R will be a new generation mass spectrometer for very precise and sensitive dating and forensics applications in earth and planetary sciences, hydrology, climate studies, and nuclear and archaeological fingerprinting. The unprecedented sensitivity of this unique instrument will provide enhanced capabilities for solving long-standing problems requiring precise geological time resolution, as well as opening new areas of research. It will be the instrument of choice for analysing small, rare samples such as those returned by space missions. The Australian-built high sensitivity source and ion detection systems can be retrofitted onto other mass spectrometers, opening a new area of commercialisation.Read moreRead less
Spreading ridge sedimentation processes: a novel approach using Macquarie Island as a natural laboratory. This research will examine the south eastern tectonic plate boundary of Australia, providing analogues for seafloor spreading related crustal processes that relate to present plate boundaries and ancient examples now joined to the Australian continent. The scientific innovation represented by this project will help Australian scientists to better understand an important part of the plate tec ....Spreading ridge sedimentation processes: a novel approach using Macquarie Island as a natural laboratory. This research will examine the south eastern tectonic plate boundary of Australia, providing analogues for seafloor spreading related crustal processes that relate to present plate boundaries and ancient examples now joined to the Australian continent. The scientific innovation represented by this project will help Australian scientists to better understand an important part of the plate tectonic cycle. This project will be of direct relevance to the Australian minerals exploration industry and will provide better constraints on rift-related metallogenesis.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
Tectonic versus biological processes: What controls the long-term global carbon cycle? A major debate in Earth system analysis concerns two competing hypotheses on the driving forces behind dramatic changes in atmospheric CO2 over geological time. One hypothesis considers tectonic/geological processes to be the major driving force. The other argues that it is the competition between plants and animals that drives the long-term CO2 cycle. We propose to test these hypotheses using a novel set of g ....Tectonic versus biological processes: What controls the long-term global carbon cycle? A major debate in Earth system analysis concerns two competing hypotheses on the driving forces behind dramatic changes in atmospheric CO2 over geological time. One hypothesis considers tectonic/geological processes to be the major driving force. The other argues that it is the competition between plants and animals that drives the long-term CO2 cycle. We propose to test these hypotheses using a novel set of global oceanic palaeo-age grids and subduction models for the last 180 million years. This will allow us to appraise key tectonic carbon cycle components such as mantle degassing, seafloor weathering and sediment subduction.Read moreRead less
High-P partial melting and melt escape from the lower crust: the evolution of a Cretaceous Island Arc, Fiordland NZ. Partial melting, melt segregation and magma transport are the main processes controlling change on Earth. Though there is clear evidence that even small melt fractions can segregate into large igneous bodies, our inability to directly observe active magma ascent means that there is not agreement on the mechanisms by which melt initially segregates, pools and ascends. This project ....High-P partial melting and melt escape from the lower crust: the evolution of a Cretaceous Island Arc, Fiordland NZ. Partial melting, melt segregation and magma transport are the main processes controlling change on Earth. Though there is clear evidence that even small melt fractions can segregate into large igneous bodies, our inability to directly observe active magma ascent means that there is not agreement on the mechanisms by which melt initially segregates, pools and ascends. This project will study well-exposed lower crustal rocks from the root of a long-lived Mesozoic island arc to resolve the mechanisms that controlled melt escape from, and extensive magma transport through deep crustal environments.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE170101325
Funder
Australian Research Council
Funding Amount
$353,705.00
Summary
Opalised fossils and the evolution of Australia's dinosaurs. This project aims to study dinosaur evolution in Australia. Dinosaurs were one of Earth's most successful land vertebrates, but Australia’s perceived poor dinosaur fossil record has stymied significant advances in the field and promoted the view that it was an evolutionary dead-end. This project will challenge this perception by coupling an exceptional but under-valued fossil resource from Lightning Ridge, NSW, with new phylogenetic me ....Opalised fossils and the evolution of Australia's dinosaurs. This project aims to study dinosaur evolution in Australia. Dinosaurs were one of Earth's most successful land vertebrates, but Australia’s perceived poor dinosaur fossil record has stymied significant advances in the field and promoted the view that it was an evolutionary dead-end. This project will challenge this perception by coupling an exceptional but under-valued fossil resource from Lightning Ridge, NSW, with new phylogenetic methodology and synchrotron analyses. The expected result is better understanding of the diversity, biology, and evolutionary relationships of Australian dinosaurs in the context of global dinosaur evolution.Read moreRead less
Oceanic gateways: a primary control on global climate change? The opening and closing of oceanic gateways, narrow passageways facilitating exchange between ocean basins, has been linked to major changes in Earth’s climate. This project will link the disparate fields of geodynamics and palaeo-climatology, for the first time, through an innovative methodology that models the changing width and depth of ocean gateways through time. It will address the role of gateways in modulating Earth’s climate ....Oceanic gateways: a primary control on global climate change? The opening and closing of oceanic gateways, narrow passageways facilitating exchange between ocean basins, has been linked to major changes in Earth’s climate. This project will link the disparate fields of geodynamics and palaeo-climatology, for the first time, through an innovative methodology that models the changing width and depth of ocean gateways through time. It will address the role of gateways in modulating Earth’s climate at key periods during the planet’s transition from a “Greenhouse” to “Icehouse” World.Read moreRead less
Pleistocene evolutionary dynamics and past environments of Siberia: Reconstructions using luminescence dating of ancient DNA sedimentary archives. This study will yield critical new insights into faunal-environment interactions in Siberia and their long-term implications for the evolution and extinction of Siberia's biota. These fundamental issues are of relevance to Australian archaeology, palaeontology and biogeography, and so our discoveries are of direct interest to Australian researchers st ....Pleistocene evolutionary dynamics and past environments of Siberia: Reconstructions using luminescence dating of ancient DNA sedimentary archives. This study will yield critical new insights into faunal-environment interactions in Siberia and their long-term implications for the evolution and extinction of Siberia's biota. These fundamental issues are of relevance to Australian archaeology, palaeontology and biogeography, and so our discoveries are of direct interest to Australian researchers studying these disciplines. The methodological advancements in OSL dating and DNA techniques that will accompany this research will enhance Australia's international scientific standing and create new opportunities for collaborative initiatives in both cutting-edge scientific research and consulting activities.Read moreRead less
The behaviour of geochemical tracers during differentiation of the Earth. This project is aimed at providing fundamental data which Earth Scientists will use to understand the processes by which the Earth separated into its chemically-distinct layers (core, mantle, crust, atmosphere, oceans) and to determine the nature of the continuing interactions between the surface environment in which we live and the deep interior. It will provide training in modern high temperature-high pressure materials- ....The behaviour of geochemical tracers during differentiation of the Earth. This project is aimed at providing fundamental data which Earth Scientists will use to understand the processes by which the Earth separated into its chemically-distinct layers (core, mantle, crust, atmosphere, oceans) and to determine the nature of the continuing interactions between the surface environment in which we live and the deep interior. It will provide training in modern high temperature-high pressure materials-science techniques for Ph.D. students and postdoctoral researchers. This will provide Australia with Earth Scientists who have both traditional skills and the ability to work with Materials Scientists on the synthesis of novel materials under extreme conditions.Read moreRead less