Just add water: a recipe for the deformation of continental interiors. By integrating geochemical, geochronological and microstructural datasets, this project aims to provide a novel framework for fluid–rock systems in the lithosphere. Plate tectonics argues that continental interiors are usually stable, rigid and undeformable, yet mountain belts have formed in these locations. Their existence suggests that strong crust can be weakened to allow the accommodation of deforming forces, but the unde ....Just add water: a recipe for the deformation of continental interiors. By integrating geochemical, geochronological and microstructural datasets, this project aims to provide a novel framework for fluid–rock systems in the lithosphere. Plate tectonics argues that continental interiors are usually stable, rigid and undeformable, yet mountain belts have formed in these locations. Their existence suggests that strong crust can be weakened to allow the accommodation of deforming forces, but the underlying causes for this change in behaviour are not clear. This project aims to investigate the largely unexplored impact of fluid flow on the characteristics of intraplate deformation. This would improve our understanding of what modulates the strength of continental crust, including its susceptibility to seismic activity, and the ways in which fluids interact with the deep crust, including their mineralisation potential.Read moreRead less
Four dimensional lithospheric evolution and controls on mineral system distribution in Neoarchean to Paleoproterozoic terranes. This project will resolve important questions about the links between the evolution and preservation of continents and important mineral deposits in Australia and West Africa between 2.7 and 1.8 billion years ago. The results will improve the understanding of a key period of Earth history and make a major contribution to mineral exploration.
Discovery Early Career Researcher Award - Grant ID: DE140100553
Funder
Australian Research Council
Funding Amount
$392,570.00
Summary
Exploring links between climate change, ocean chemistry, and the rise of multicellular life: The Ediacaran sedimentary record of central Australia. For most of Earth’s history, single-celled organisms were the only forms of life on the planet. Not until roughly 600 million years ago do fossils of multicellular animals appear in the rock record. Explanations for the Ediacaran rise of multicellularity include extreme climate change, meteorite impact and oxygenation of the global ocean. Evaluation ....Exploring links between climate change, ocean chemistry, and the rise of multicellular life: The Ediacaran sedimentary record of central Australia. For most of Earth’s history, single-celled organisms were the only forms of life on the planet. Not until roughly 600 million years ago do fossils of multicellular animals appear in the rock record. Explanations for the Ediacaran rise of multicellularity include extreme climate change, meteorite impact and oxygenation of the global ocean. Evaluation of these hypotheses is complicated by the fact that stratigraphic records that span the appropriate time interval are rare. This project is focused on the carbon, oxygen, and zinc isotopic records preserved by Ediacaran marine rocks in the Amadeus Basin of central Australia. Results will contribute to a more complete record of fluctuations in ocean chemistry during a key interval of Earth history.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100095
Funder
Australian Research Council
Funding Amount
$700,000.00
Summary
Frontiers in integrated laser-sampled trace-element and isotopic geoanalysis. Until around 2005 Australia was a leader in the coupling of laser-ablation microprobes (LAM) with inductively-coupled-plasma mass spectrometers (ICPMS) for geochemical research. However, international developments in femtosecond LAM, sector field instruments and novel instrument coupling possibilities have leap-frogged these achievements. The proposed innovative facility will allow us to regain the leading edge in thi ....Frontiers in integrated laser-sampled trace-element and isotopic geoanalysis. Until around 2005 Australia was a leader in the coupling of laser-ablation microprobes (LAM) with inductively-coupled-plasma mass spectrometers (ICPMS) for geochemical research. However, international developments in femtosecond LAM, sector field instruments and novel instrument coupling possibilities have leap-frogged these achievements. The proposed innovative facility will allow us to regain the leading edge in this field, help maintain the high profile of Australian geoscience internationally, and to attract high-quality researchers and industry-related research funding. The research is relevant to the Deep Earth Resources National Priority and will include projects of direct relevance to mineral exploration and process technology.Read moreRead less
Tectonic geography of the world's oldest petroleum play, the McArthur Basin. This projects aims to develop a 4D tectonic geography framework to support the effective exploration of the McArthur Basin. This project will construct this by a) investigating the evolving tectonic setting, b) examining intra-basin correlations and trace the source to sink sediment provenance, c) unraveling the depositional geography using novel isotopic proxies, and, d) constructing the subsequent thermal history of ....Tectonic geography of the world's oldest petroleum play, the McArthur Basin. This projects aims to develop a 4D tectonic geography framework to support the effective exploration of the McArthur Basin. This project will construct this by a) investigating the evolving tectonic setting, b) examining intra-basin correlations and trace the source to sink sediment provenance, c) unraveling the depositional geography using novel isotopic proxies, and, d) constructing the subsequent thermal history of the basin. The techniques developed through this project will de-risk the exploration for petroleum in this basin, and be applicable in opening up Proterozoic petroleum elsewhere in Australia and internationally.Read moreRead less
Iron isotope variation in subduction magmas: Links to fluid flux and oxidation of the mantle wedge? The plates of the outer tectonic shell of our Earth are in ceaseless motion; their collisions create huge earthquakes and their collapse into the Earth introduces surface water to these hot regions at >150km depth, creating melting and volcanic eruption. This project will use iron isotopes to map this surface water as it is introduced to the mantle.
Australian Laureate Fellowships - Grant ID: FL160100168
Funder
Australian Research Council
Funding Amount
$2,851,557.00
Summary
The pulse of the earth. The pulse of the earth. This project aims to establish the origin and evolution of the continental crust and its role in the long term development of the Earth system. The continental crust hosts the resources on which we depend and its evolution controls the environment in which we live. The crust’s record (including resources) is episodic in space and time, but the origin of this periodicity is unresolved. Building on recent advances on crustal development, the fellowsh ....The pulse of the earth. The pulse of the earth. This project aims to establish the origin and evolution of the continental crust and its role in the long term development of the Earth system. The continental crust hosts the resources on which we depend and its evolution controls the environment in which we live. The crust’s record (including resources) is episodic in space and time, but the origin of this periodicity is unresolved. Building on recent advances on crustal development, the fellowship would work to resolve the origin of the episodic age pattern, which affects the distribution of mineral systems and their prospectivity.Read moreRead less
The origin of Australian Gondwana: using isotopic proxies for subduction to reconstruct ancient oceans. This project will, for the first time, include ancient ocean basins in Neoproterozoic plate tectonic reconstructions. It will provide new insights into the geography of Australia between 850 and 500 million years ago, a time of major climatic extremes, the origin of multi-cellular life and the accumulation of the first major petroleum deposits.
A detrital apatite archive to track crustal growth. This project will establish apatite as a new tool to study the evolution of the continental crust. The crust shaped the composition of the atmosphere and the oceans with consequences for the evolution of life through the availability of oxygen and nutrients. However, when and how the continental crust was generated remains a core question. Current models for continental crust development rely on the mineral zircon. However, zircons only record ....A detrital apatite archive to track crustal growth. This project will establish apatite as a new tool to study the evolution of the continental crust. The crust shaped the composition of the atmosphere and the oceans with consequences for the evolution of life through the availability of oxygen and nutrients. However, when and how the continental crust was generated remains a core question. Current models for continental crust development rely on the mineral zircon. However, zircons only record the history of evolved rocks. To address this bias we will use the mineral apatite which forms in less evolved rocks. We will develop a detrital apatite database of Pb-Nd (model) ages and integrate this with the zircon record to provide a more holistic description for how our planet developed.Read moreRead less