Carbon dioxide-methane exchange in porous media for carbon-neutral energy production. This project aims to incorporate carbon capture and storage into natural gas production from energy reserves. Carbon sequestration could assist in achieving the goals of the Paris Climate Agreement. Injecting carbon dioxide into natural gas reservoirs or methane hydrate sands would be a nearly carbon-neutral means of energy production. However, this exchange of carbon dioxide for methane is poorly understood in ....Carbon dioxide-methane exchange in porous media for carbon-neutral energy production. This project aims to incorporate carbon capture and storage into natural gas production from energy reserves. Carbon sequestration could assist in achieving the goals of the Paris Climate Agreement. Injecting carbon dioxide into natural gas reservoirs or methane hydrate sands would be a nearly carbon-neutral means of energy production. However, this exchange of carbon dioxide for methane is poorly understood in both reservoirs and sands because multiple phases like water and sand affect mixing and recovery. This project will combine spatially-resolved Magnetic Resonance Imaging of high-pressure flooding and exchange experiments with multi-scale modelling. The expected outcome is simultaneous carbon dioxide sequestration with enhanced energy production.Read moreRead less
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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Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100095
Funder
Australian Research Council
Funding Amount
$620,000.00
Summary
High-resolution X-ray micro computed tomography supporting West Australian geo-, physical and biological science. An X-ray micro computed tomography facility will provide West Australian researchers with much needed access to cutting-edge instrumentation for high-resolution three-dimensional imaging. This facility will support major research programs in key disciplines, including minerals and mining, energy, medical and biological sciences.
Industrial Transformation Training Centres - Grant ID: IC150100019
Funder
Australian Research Council
Funding Amount
$4,571,797.00
Summary
ARC Training Centre for Liquefied Natural Gas Futures. ARC Training Centre for Liquefied Natural Gas Futures. This training centre aims to deliver projects and training to enable future Australian Liquefied Natural Gas (LNG) production from reserves in deep water, at small or remote on-shore locations, with greater efficiency, less environmental impact, and at lower cost than currently possible. This should be accomplished via research projects undertaken by the PhD students and research fellows ....ARC Training Centre for Liquefied Natural Gas Futures. ARC Training Centre for Liquefied Natural Gas Futures. This training centre aims to deliver projects and training to enable future Australian Liquefied Natural Gas (LNG) production from reserves in deep water, at small or remote on-shore locations, with greater efficiency, less environmental impact, and at lower cost than currently possible. This should be accomplished via research projects undertaken by the PhD students and research fellows with guidance from the centre’s industrial partners. The centre’s expected legacy is a unique research and training facility, designed for future integration into a microscale LNG plant. The anticipated research and training outcomes will help to ensure Australia plays a leading role in future global LNG developments.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE140101094
Funder
Australian Research Council
Funding Amount
$395,220.00
Summary
Precision Spectroscopy of CO2 Exchange in Hydrates for Clean Energy Production. Carbon dioxide capture and sequestration is a widely considered climate change mitigation strategy. Clathrate hydrates of natural gas, found in deep-water ocean sediments, represent a tremendous opportunity for simultaneous carbon dioxide sequestration and clean energy production. By injecting carbon dioxide into the hydrate reservoir, methane can be displaced and replaced by carbon dioxide. This project will use Ram ....Precision Spectroscopy of CO2 Exchange in Hydrates for Clean Energy Production. Carbon dioxide capture and sequestration is a widely considered climate change mitigation strategy. Clathrate hydrates of natural gas, found in deep-water ocean sediments, represent a tremendous opportunity for simultaneous carbon dioxide sequestration and clean energy production. By injecting carbon dioxide into the hydrate reservoir, methane can be displaced and replaced by carbon dioxide. This project will use Raman spectroscopy and nuclear magnetic resonance imaged core-flood experiments to develop a fundamental understanding of the exchange mechanisms governing the replacement of the methane molecule in the hydrate cage with carbon dioxide. This knowledge will be critical for future development of these resources to safely extract methane from sub-sea hydrates.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE130101533
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
A risk-based approach to natural gas hydrates in oil and gas production. Like a cholesterol for oil and gas pipelines, gas hydrates are ice-like deposits that completely block the flow during production and are expensive to prevent as well as dangerous to remove. This proposal provides a risk-based approach to hydrate management that will increase the viability of natural gas production from fields in deep water.
Controlling hydrate slurry flow to enable deepwater oil and gas production. This project aims to investigate the plugging of hydrate slurries in pipelines to determine under what conditions they will flow satisfactorily without forming a blockage. Hydrate blockages are expensive and hazardous occurrences in oil and gas operations, so current prevention systems aim to avoid hydrate formation altogether through over-design. These over-designed hydrate prevention systems are extremely expensive to ....Controlling hydrate slurry flow to enable deepwater oil and gas production. This project aims to investigate the plugging of hydrate slurries in pipelines to determine under what conditions they will flow satisfactorily without forming a blockage. Hydrate blockages are expensive and hazardous occurrences in oil and gas operations, so current prevention systems aim to avoid hydrate formation altogether through over-design. These over-designed hydrate prevention systems are extremely expensive to build and costly to run during the operations phase. The project intends to examine the behaviour of hydrate slurry flow as a function of the oil's properties, amount of water and degree of turbulence. Outcomes are intended to be a sophisticated approach to avoiding hydrate blockages that is safe but more efficient and less costly.Read moreRead less
Understanding the molecular structure and chemical behaviour of asphaltenes. This project will advance the science underpinning technologies for cost-effective use of heavy oil resources. Asphaltene aggregation and precipitation pose enormous challenges for extraction, transport, storage and refining of heavy oils. Understanding the physicochemical properties of asphaltenes is crucial to the future oil industry as light crudes become scarce. This project plans to develop and deploy an innovative ....Understanding the molecular structure and chemical behaviour of asphaltenes. This project will advance the science underpinning technologies for cost-effective use of heavy oil resources. Asphaltene aggregation and precipitation pose enormous challenges for extraction, transport, storage and refining of heavy oils. Understanding the physicochemical properties of asphaltenes is crucial to the future oil industry as light crudes become scarce. This project plans to develop and deploy an innovative molecular probe technique, combined with sequential thermal and solvent extraction and advanced tools for nanoscale characterisation, to reveal the molecular structure and chemical behaviour of asphaltenes. The resulting understanding of the mechanisms of asphaltene aggregation and dissociation may provide a scientific basis for controlling asphaltene precipitation to improve the stability and thus improve the use of heavy oils.Read moreRead less
Upscaling laws for hydraulic fracturing of tight formations using reproducible true tri-axial laboratory testing. Upscaling models for designing hydraulic fracture stimulation of gas reservoirs will be developed. Innovative laboratory methods of reproducing the field stress conditions and rock structure will be used. The results will advance the mechanics of hydraulic fracturing and increase efficiency of reservoir stimulation, especially in tight formations.
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.