A revolution in Earth History: Life and Environment in the Neoarchaean (2.5-2.8 Ga). This research will keep Australian scientists in the forefront of studies of early life on Earth. At a time when there is a great deal of interest in this topic because of the search for similar life elsewhere in the Solar System, this work will take a prominant place in international research. It will attract leading researchers from elsewhere, with consequent intellectual benefits, and will inspire students t ....A revolution in Earth History: Life and Environment in the Neoarchaean (2.5-2.8 Ga). This research will keep Australian scientists in the forefront of studies of early life on Earth. At a time when there is a great deal of interest in this topic because of the search for similar life elsewhere in the Solar System, this work will take a prominant place in international research. It will attract leading researchers from elsewhere, with consequent intellectual benefits, and will inspire students to careers in science.Read moreRead less
Origin and setting of Congolese-type Cu deposits. This project aims to understand the genesis of the giant sediment-hosted Cu ore deposits of the Congolese Copperbelt, and their relationship to the enclosing strata. We will use selected study areas within the correlative Neoproterozic basin successions in Australia, which are well exposed and covered by modern geoscientific datasets, as analogues for the poorly exposed Congolese system. Once this is achieved, we will combine the results with tho ....Origin and setting of Congolese-type Cu deposits. This project aims to understand the genesis of the giant sediment-hosted Cu ore deposits of the Congolese Copperbelt, and their relationship to the enclosing strata. We will use selected study areas within the correlative Neoproterozic basin successions in Australia, which are well exposed and covered by modern geoscientific datasets, as analogues for the poorly exposed Congolese system. Once this is achieved, we will combine the results with those of a previous ARC linkage project on the nearby Zambian Copperbelt, to provide the first integrated model of the worlds largest sedimentary Cu system.Read moreRead less
Palaeobiology of hydrothermal mineral deposits. Mineral deposits that formed at up to 150 degrees C record the history of micro-organisms referred to as hyperthermophiles. Current biological studies predict that such organisms are the most primitive known. Thus by studying these deposits we have the opportunity to uncover the earliest history of life on Earth, and to improve our understanding of ore deposition. Such deposits are also prime targets for the search for life and former life elsewher ....Palaeobiology of hydrothermal mineral deposits. Mineral deposits that formed at up to 150 degrees C record the history of micro-organisms referred to as hyperthermophiles. Current biological studies predict that such organisms are the most primitive known. Thus by studying these deposits we have the opportunity to uncover the earliest history of life on Earth, and to improve our understanding of ore deposition. Such deposits are also prime targets for the search for life and former life elsewhere in the Solar System, and the proposed research will contribute to that search.Read moreRead less
Earth's best-preserved Archean boninites: do they finally resolve the Archean mantle plume - plate tectonics controversy? Subduction typically starts on the modern Earth with the eruption of chemically distinctive rocks known as boninites. This project will study remarkably well preserved 2.85 billion year old boninites from Western Australia that may finally establish whether modern-style plate tectonics operated in the first half of Earth's history.
Links Between Modern and Fossil Microbes and the Evolution of Life in Earth's Extreme Early Environments. The quest to understand early and modern life in extreme environments tackles some of the most profound questions of humankind. The novel application of spectroscopic techniques to investigate modern and fossil microbes presents an unprecedented opportunity to establish the link between primitive living and fossil organisms, thus enriching our understanding of the early evolution of life and ....Links Between Modern and Fossil Microbes and the Evolution of Life in Earth's Extreme Early Environments. The quest to understand early and modern life in extreme environments tackles some of the most profound questions of humankind. The novel application of spectroscopic techniques to investigate modern and fossil microbes presents an unprecedented opportunity to establish the link between primitive living and fossil organisms, thus enriching our understanding of the early evolution of life and its interactions with Earth's early environments. The project links fundamental processes that shaped the Earth and thus fits into the National Research Priority 1: An Environmentally Sustainable Australia. Read moreRead less
Global Lithospheric Architecture Mapping II. The continents have been rifted, or broken up, and collided, or re-assembled, along major zones of weakness many times throughout Earth's history. Boundaries between such continental domains focus large-scale movements of fluids that can produce giant ore deposits. This study will provide new perspectives on the localisation of world-class economic deposits, the Earth resources on which society depends. Innovations in imaging the deep Earth beneath co ....Global Lithospheric Architecture Mapping II. The continents have been rifted, or broken up, and collided, or re-assembled, along major zones of weakness many times throughout Earth's history. Boundaries between such continental domains focus large-scale movements of fluids that can produce giant ore deposits. This study will provide new perspectives on the localisation of world-class economic deposits, the Earth resources on which society depends. Innovations in imaging the deep Earth beneath continents, and in numerical modelling, will maintain our high international profile in research relevant to National Priority 1.6 (Developing Deep Earth Resources). Unique 3D geological maps of regions down to 250km will make the composition of deep Earth regions newly accessible to geoscientists and all potential endusers.Read moreRead less
Crustal Growth in the Northern Tasmanides. The Australian and Queensland governments have invested over $3 million to undertake deep crustal seismic imaging in northern Queensland, providing an extensive new geophysical dataset capable of modelling crustal architecture and geological evolution to unprecedented levels. However, such models will remain untested unless the data is groundtruthed by analysis of rocks at the surface, providing a geological framework for extrapolation into the deep Ea ....Crustal Growth in the Northern Tasmanides. The Australian and Queensland governments have invested over $3 million to undertake deep crustal seismic imaging in northern Queensland, providing an extensive new geophysical dataset capable of modelling crustal architecture and geological evolution to unprecedented levels. However, such models will remain untested unless the data is groundtruthed by analysis of rocks at the surface, providing a geological framework for extrapolation into the deep Earth. The framework critically describes when and how crustal blocks were assembled, and the integrated information will generate evolutionary 3D models that will substantially improve mineral exploration targeting in the region.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0347677
Funder
Australian Research Council
Funding Amount
$750,000.00
Summary
An electron probe microanalysis system to replace an existing 14 year-old instrument. Compositional data determined on inorganic materials by electron microprobe analysis (EPMA) underpins a considerable amount research in Earth/planetary sciences. Spots down to 2/1000mm may be analysed quantitatively for major elements and some trace elements with an accuracy of <1%, and digital composition maps of the elemental spatial distribution can be generated. Increasing downtime on the 14 year-old UTasma ....An electron probe microanalysis system to replace an existing 14 year-old instrument. Compositional data determined on inorganic materials by electron microprobe analysis (EPMA) underpins a considerable amount research in Earth/planetary sciences. Spots down to 2/1000mm may be analysed quantitatively for major elements and some trace elements with an accuracy of <1%, and digital composition maps of the elemental spatial distribution can be generated. Increasing downtime on the 14 year-old UTasmania microprobe, coupled with diverse new and exciting applications in ore deposit research, environmental geoscience and geochronology force us to seek funds to replace the existing EPMA facility, which has logged ~101,000 hours of use involving ~250 researchers, and produced more than 500 refereed papers.Read moreRead less
Biosphere, hydrocarbon and ore fluid interactions in the Early Precambrian. Ore deposits and petroleum are important for economic and social areas of Australia's growth. New discoveries are needed to maintain Australia's wealth as mines reach the end of operations and petroleum supplies decrease. This project will demonstrate how ore fluids and hydrocarbons interact in the geological environment. It should, therefore greatly expand the conceptual framework in which to explore for both mineral an ....Biosphere, hydrocarbon and ore fluid interactions in the Early Precambrian. Ore deposits and petroleum are important for economic and social areas of Australia's growth. New discoveries are needed to maintain Australia's wealth as mines reach the end of operations and petroleum supplies decrease. This project will demonstrate how ore fluids and hydrocarbons interact in the geological environment. It should, therefore greatly expand the conceptual framework in which to explore for both mineral and hydrocarbon resources, particularly in old, deep and hot basins, which are considered to be the last frontiers of exploration. Outcomes concerning the nature of early life will be of global interest.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0561245
Funder
Australian Research Council
Funding Amount
$512,092.00
Summary
Scanning electron microscope with system for automated mineral mapping and textural analysis to support new geometallurgy research initiative. This project aims, through the purchase of a Scanning Electron Microscope, to re-establish an effective microscopy service to life science researchers and concurrently establish a novel research capability for geologists, providing each research group with adequate access.
Research projects using this facility have economic importance to the silvicultu ....Scanning electron microscope with system for automated mineral mapping and textural analysis to support new geometallurgy research initiative. This project aims, through the purchase of a Scanning Electron Microscope, to re-establish an effective microscopy service to life science researchers and concurrently establish a novel research capability for geologists, providing each research group with adequate access.
Research projects using this facility have economic importance to the silviculture, aquaculture and mining industries. Read moreRead less