A Mission to Very Early Earth: When Did Conditions Suitable for Life Emerge on Earth? A uniquely Australian resource - 4.4-4.1 Ga detrital zircons from the Jack Hills (WA) - represent the only tangible record of the Hadean Eon (4.5-4.0 Ga) and potentially contain information regarding the origin of the atmosphere, hydrosphere, continental lithosphere, geodynamo, and perhaps even life, during the earliest stages of Earth evolution. Following age characterization of 100,000 zircons, experiments in ....A Mission to Very Early Earth: When Did Conditions Suitable for Life Emerge on Earth? A uniquely Australian resource - 4.4-4.1 Ga detrital zircons from the Jack Hills (WA) - represent the only tangible record of the Hadean Eon (4.5-4.0 Ga) and potentially contain information regarding the origin of the atmosphere, hydrosphere, continental lithosphere, geodynamo, and perhaps even life, during the earliest stages of Earth evolution. Following age characterization of 100,000 zircons, experiments involving short-lived nuclear chronometers and tracers of continental evolution (Hf and O isotopes) will be undertaken on the most ancient zircons that could both radically our paradigm for early planetary evolution and permit assessment of whether life emerged during the Hadean Eon.Read moreRead less
Realising Australia’s rare earth resource potential. This project aims to reveal the potential for undiscovered economic deposits of rare earth elements within the Australian continent. Future supply of these elements underpins societies transition to clean energy and embrace of high-tech applications. The project expects to greatly enhance our knowledge of Australia’s endowment of rare earth element resources using an array of traditional and innovative geological research methods. Expected out ....Realising Australia’s rare earth resource potential. This project aims to reveal the potential for undiscovered economic deposits of rare earth elements within the Australian continent. Future supply of these elements underpins societies transition to clean energy and embrace of high-tech applications. The project expects to greatly enhance our knowledge of Australia’s endowment of rare earth element resources using an array of traditional and innovative geological research methods. Expected outcomes of this project include a greater understanding of how, where and when rare earth element orebodies form in the Earth's crust. This should provide significant benefits to exploring for––and discovering––new orebodies that are required to secure global critical metal supplies. Read moreRead less
The Rare Earth Potential of the Gascoyne Region of Western Australia. The Gascoyne Region of Western Australia is an emerging Neodymium-rich rare earth district in its early stages of development. The mineral occurrences of the region are complex and their geological distribution and source(s) remain unclear. With the support of all the active explorers in the region, a better understanding of the entire mineral system is sought to maximise exploration efficiency. This project aims to undertake ....The Rare Earth Potential of the Gascoyne Region of Western Australia. The Gascoyne Region of Western Australia is an emerging Neodymium-rich rare earth district in its early stages of development. The mineral occurrences of the region are complex and their geological distribution and source(s) remain unclear. With the support of all the active explorers in the region, a better understanding of the entire mineral system is sought to maximise exploration efficiency. This project aims to undertake a full assessment of the minerals, their processing and the environmental impact of production to determine the potential of the region. The expected outcome of the project is to develop a world-class rare earth mineral district in Australia, to ensure future supplies of these strategically important metals. Read moreRead less
An experimental study of trace element equilibria during metamorphism. The analytical methods and experimental data to be developed will enable an Australian team to become world leaders in determining pressures and temperatures of mineral growth that correspond to a range of depths and temperature gradients in the Earth tha t is wider than accessible previously. Obtaining this information from small zones within single grains will allow determination of rates of change, and give us a detailed p ....An experimental study of trace element equilibria during metamorphism. The analytical methods and experimental data to be developed will enable an Australian team to become world leaders in determining pressures and temperatures of mineral growth that correspond to a range of depths and temperature gradients in the Earth tha t is wider than accessible previously. Obtaining this information from small zones within single grains will allow determination of rates of change, and give us a detailed picture of how the host rock has evolved, even from very small samples. One application would be checking the origin of relatively common minerals for whether they could be associated with diamonds.Read moreRead less
Mapping mineral systems of deep Australia. We aim at enabling mineral resource discoveries by calibrating geophysical surveys using geochemical and petrophysical properties measured on mantle samples brought to the surface by recent volcanoes. National geophysical surveys deliver images of geophysical gradients in the deeper part of the Australian continent. The interpretation of these gradients in geological terms and in terms of economic mineral systems is the key to unlock deep exploration su ....Mapping mineral systems of deep Australia. We aim at enabling mineral resource discoveries by calibrating geophysical surveys using geochemical and petrophysical properties measured on mantle samples brought to the surface by recent volcanoes. National geophysical surveys deliver images of geophysical gradients in the deeper part of the Australian continent. The interpretation of these gradients in geological terms and in terms of economic mineral systems is the key to unlock deep exploration success. This project will turn Australia’s investment in National geophysical surveys into new discoveries of base metals. The benefit stems from enabling the transition to a clean economy which requires a much broader range of critical minerals and a larger quantity of base metals.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE180100070
Funder
Australian Research Council
Funding Amount
$966,283.00
Summary
Cutting-edge electron probe microanalysis driving Western Australia’s resource geosciences. This project aims to provide a new generation electron microprobe, with advances in trace element mapping and cathodoluminescence analysis to enable superior characterisation of a wide range of materials. The overwhelming demand for electron probe microanalysis from research groups in Western Australia requires renewal of over-subscribed, ageing facilities to drive innovation and alleviate bottlenecks in ....Cutting-edge electron probe microanalysis driving Western Australia’s resource geosciences. This project aims to provide a new generation electron microprobe, with advances in trace element mapping and cathodoluminescence analysis to enable superior characterisation of a wide range of materials. The overwhelming demand for electron probe microanalysis from research groups in Western Australia requires renewal of over-subscribed, ageing facilities to drive innovation and alleviate bottlenecks in advanced geosciences multi-capability workflows. The electron probe will drive underpinning geoscience, resources science and economic geology, as well as support a broad range of disciplines and diverse fields, such as nanotechnology, microelectronics and aquatic sciences.Read moreRead less
The carbonate geology of the critical metal niobium. This project aims to understand how pyrochlore, the major ore mineral of the critical metal niobium, forms in
Earth’s crust. Niobium is exclusively mined from carbonatite magma bodies in Brazil and Canada, despite proven
Australian resources. It is used in high strength steel alloys in the construction and transport industries. Expected
research outcomes include understanding how pyrochlore forms in carbonatites, development of exploration too ....The carbonate geology of the critical metal niobium. This project aims to understand how pyrochlore, the major ore mineral of the critical metal niobium, forms in
Earth’s crust. Niobium is exclusively mined from carbonatite magma bodies in Brazil and Canada, despite proven
Australian resources. It is used in high strength steel alloys in the construction and transport industries. Expected
research outcomes include understanding how pyrochlore forms in carbonatites, development of exploration tools
to locate niobium ore bodies which are unexposed at the surface, and investigation of environmentally and
economically sustainable technologies for metallurgical extraction of niobium from ore. The research is intended
to benefit Australia’s critical metals exploration and mining industries.Read moreRead less
The geochemistry of rare earth elements in carbonate melts. This project aims to determine why deposits of rare earth elements, which are critical for modern devices and technologies such as phones, tablets and plasma screens, are associated with carbonate magmas. The global supply of these critical metals is geopolitically unstable and, although Australia has significant reserves, there is very limited production. By improving our understanding of the geochemical behaviour of the rare earths th ....The geochemistry of rare earth elements in carbonate melts. This project aims to determine why deposits of rare earth elements, which are critical for modern devices and technologies such as phones, tablets and plasma screens, are associated with carbonate magmas. The global supply of these critical metals is geopolitically unstable and, although Australia has significant reserves, there is very limited production. By improving our understanding of the geochemical behaviour of the rare earths this project aims to develop new reverse-engineering methods for their extraction, which will improve the security of supply of these elements and enhance Australia's role in high-tech industries. The project will enhance the profitability of the Australian resources sector through improved extraction economics and will secure the supply of these critical metals for Australian high-tech industries and export. The outcomes will be targeted initially at junior resource companies that are not yet profitable.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