Industrial Transformation Research Hubs - Grant ID: IH140100012
Funder
Australian Research Council
Funding Amount
$4,997,672.00
Summary
ARC Research Hub for Offshore Floating Facilities. ARC Research Hub for Offshore Floating Facilities. This research hub aims to address the critical engineering challenges associated with Australia’s next generation of offshore oil and gas projects. These projects, in remote deep-water locations, will require innovative floating facilities. Using world-leading expertise in metocean, hydrodynamic, geotechnical and reliability engineering, the hub aims to develop the new technologies and analysis ....ARC Research Hub for Offshore Floating Facilities. ARC Research Hub for Offshore Floating Facilities. This research hub aims to address the critical engineering challenges associated with Australia’s next generation of offshore oil and gas projects. These projects, in remote deep-water locations, will require innovative floating facilities. Using world-leading expertise in metocean, hydrodynamic, geotechnical and reliability engineering, the hub aims to develop the new technologies and analysis methods that are required to make projects safe, efficient and cost-effective. This research will include wave and current forecasting, vessel motion and offloading analysis, riser and mooring longevity and novel anchoring and subsea foundations. This is expected to lead to safer, more economical projects and should develop Western Australia’s role as an oil and gas centre of excellence.Read moreRead less
Tracking water on planetary surfaces using data from the Curiosity rover, the laboratory, meteorites and Australian field sites. A fundamental question in science is why does Earth have so much liquid water, but other planets do not? This project will answer this question using the Curiosity rover on Mars, studying alteration minerals that record the action of water. The project will develop new methods to improve our understanding of alteration minerals in martian meteorites, under controlled ....Tracking water on planetary surfaces using data from the Curiosity rover, the laboratory, meteorites and Australian field sites. A fundamental question in science is why does Earth have so much liquid water, but other planets do not? This project will answer this question using the Curiosity rover on Mars, studying alteration minerals that record the action of water. The project will develop new methods to improve our understanding of alteration minerals in martian meteorites, under controlled environmental conditions and in field samples that are relevant for Mars. It aims to build expertise in the environmental aspects of planetary surfaces and in novel instrumentation. This research will improve methods to examine returned extraterrestrial samples, to evaluate land degradation and to search for energy and ore deposits.Read moreRead less
Detachments in evaporites and shales: their controls on fold-thrust belt style and wedge geometry. Deepwater fold-thrust belts comprise large structural traps, currently a major focus of Australian petroleum exploration. The structural style of a fold-thrust belt is controlled by its detachment and new field analogues will demonstrate the fundamental role of detachments.
Shale rock characterisation using Nuclear Magnetic Resonance. This project aims to assess the viability of potential shale oil and gas reserves, using Nuclear Magnetic Resonance (NMR) core analysis and well logging techniques to characterise shale samples. Shale oil and gas reserves have the potential to provide a rapidly dispatchable energy source, which could play a key role as a transition fuel to renewable energy. The project will develop techniques to deliver quantitative fluid typing, prod ....Shale rock characterisation using Nuclear Magnetic Resonance. This project aims to assess the viability of potential shale oil and gas reserves, using Nuclear Magnetic Resonance (NMR) core analysis and well logging techniques to characterise shale samples. Shale oil and gas reserves have the potential to provide a rapidly dispatchable energy source, which could play a key role as a transition fuel to renewable energy. The project will develop techniques to deliver quantitative fluid typing, producible porosity, pore sizes and permeability measurements for shale samples, which could be used in the shale gas and oil industry. These techniques will improve the predictability of shale field developments that better inform their economic and environmental impact.
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New Stratigraphy and Geostatistics for Gas and Water Resources . Management of gas and water resources is of significant importance to the Australian economy and society. Industry and government use digital modelling to assist in resources management. The first step in modelling is to correlate geological data and then use geostatistics to estimate properties in areas without data. This project aims to produce a new geological framework for the Surat Basin underpinned by new zircon ages and ages ....New Stratigraphy and Geostatistics for Gas and Water Resources . Management of gas and water resources is of significant importance to the Australian economy and society. Industry and government use digital modelling to assist in resources management. The first step in modelling is to correlate geological data and then use geostatistics to estimate properties in areas without data. This project aims to produce a new geological framework for the Surat Basin underpinned by new zircon ages and ages of fossils in sediments and a new geostatistical methodology to better represent flow properties in coal seams and aquifers. This is expected result in a more accurate modelling methodology that can be used by industry and government for modelling resources, including in other basins in Australia and worldwide.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100112
Funder
Australian Research Council
Funding Amount
$275,000.00
Summary
A Raman facility for advanced research supporting Australia’s natural gas, oil, coal and minerals industries. This modern Raman Spectroscopy facility will support the science and engineering that underpins the production and processing of Australia’s natural resources. Using high-pressure fibre optics, novel lasers and advanced imaging, the facility will enable the monitoring and improvement of processes and materials under extreme conditions.
Dynamic tomography: high-resolution, four-dimensional imaging of processes. This project will develop imaging technology that allows us to collect detailed, three dimensional movies of complex, microscopic processes in a laboratory. This technology will have applications in soil science, biology, oil extraction, and carbon sequestration.