Pore scale characterisation of the wettability of petroleum reservoir core material: Towards optimised recovery of hydrocarbon reserves. In most oil reservoirs more than 50% of original oil in place remains unrecovered. A major factor contributing to suboptimal recovery is insufficient knowledge of the rock wettability. Even a small improvement in recovery will have substantial economic benefit. The proposed project aims to characterise wettability in hydrocarbon bearing rocks using advanced 3D ....Pore scale characterisation of the wettability of petroleum reservoir core material: Towards optimised recovery of hydrocarbon reserves. In most oil reservoirs more than 50% of original oil in place remains unrecovered. A major factor contributing to suboptimal recovery is insufficient knowledge of the rock wettability. Even a small improvement in recovery will have substantial economic benefit. The proposed project aims to characterise wettability in hydrocarbon bearing rocks using advanced 3D imaging hardware and understand implications to oil displacement and recovery via state-of-the-art computational tools. Scientifically, this will be a leading edge research achievement enhancing Australian competitiveness in petroleum engineering research and will help Australia become a world leader in the export-oriented petroleum research services industry.Read moreRead less
Core-scale geodynamic rock-typing of reservoir rock. This project aims to develop a robust classification method for reservoir rock incorporating static, dynamic and mechanical attributes via multiscale digital core analysis using the concept of regional measures. Rock-types are used to populate reservoir models in a sophisticated routine of geological classification, spatial modelling and uncertainty analysis. Introducing high-resolution rock-types incorporating hydraulic properties and compact ....Core-scale geodynamic rock-typing of reservoir rock. This project aims to develop a robust classification method for reservoir rock incorporating static, dynamic and mechanical attributes via multiscale digital core analysis using the concept of regional measures. Rock-types are used to populate reservoir models in a sophisticated routine of geological classification, spatial modelling and uncertainty analysis. Introducing high-resolution rock-types incorporating hydraulic properties and compaction allows the development of a new generation of reservoir simulators. The project aims to derive a consistent high-resolution definition of rock-types incorporating compaction for petrophysical, geological and reservoir engineering purposes. This would greatly enhance our capacity to develop thinly layered reservoirs with direct applications in 4-D seismic reservoir characterisation and the development of unconventional reservoirs.Read moreRead less
Doped metal perovskites for electrocatalysis. This project aims to discover and design perovskite metal-oxide electrocatalyst materials and develop electrocatalytic methods for efficiently driving the oxygen evolution reaction and the oxygen reduction reaction. These are the two most crucial reactions in sustainable energy cycles involving water, hydrogen and oxygen. The project’s anticipated advances in electrocatalysis efficiency for these two reactions will benefit sustainable energy technolo ....Doped metal perovskites for electrocatalysis. This project aims to discover and design perovskite metal-oxide electrocatalyst materials and develop electrocatalytic methods for efficiently driving the oxygen evolution reaction and the oxygen reduction reaction. These are the two most crucial reactions in sustainable energy cycles involving water, hydrogen and oxygen. The project’s anticipated advances in electrocatalysis efficiency for these two reactions will benefit sustainable energy technologies such as fuel cells, metal air batteries and water splitting.Read moreRead less
Transport properties from Nuclear Magnetic Resonance. Australia is embarking on the development of major gas fields offshore western Australia. These developments are very costly (~1Billion) and tools to manage the risk in development are well sought after. NMR response is the only tool offering a good correlation to permeability, one of the major factors whether oil/gas recovery is economical. The actual rocks studied will be selected to make the results of the study of immediate value to Austr ....Transport properties from Nuclear Magnetic Resonance. Australia is embarking on the development of major gas fields offshore western Australia. These developments are very costly (~1Billion) and tools to manage the risk in development are well sought after. NMR response is the only tool offering a good correlation to permeability, one of the major factors whether oil/gas recovery is economical. The actual rocks studied will be selected to make the results of the study of immediate value to Australian oil and gas producers.
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Rock Physics: A study of micromechanics of rocks and granulated materials. This proposal will provide an understanding of the micro mechanics of granular materials and of changes at the grain scale when a granular pack undergoes mechanical stress or compaction. Sedimentary rocks, as a natural form of compact granular materials, are abundant in nature and often provide the bed for underground hydrocarbon reserves. This project will answer some of the fundamental questions in petroleum engineering ....Rock Physics: A study of micromechanics of rocks and granulated materials. This proposal will provide an understanding of the micro mechanics of granular materials and of changes at the grain scale when a granular pack undergoes mechanical stress or compaction. Sedimentary rocks, as a natural form of compact granular materials, are abundant in nature and often provide the bed for underground hydrocarbon reserves. This project will answer some of the fundamental questions in petroleum engineering, explaining how and why a sedimentary oil reservoir compacts during oil extraction. The knowledge gained from this project has also important applications in the construction industries and ground water management.Read moreRead less
A dynamic pore-network model for fluid displacements in porous media. The project will have a major impact on the up-stream oil and gas industry nationally and worldwide. It will allow data crucial to the development and optimization of oil and gas fields to be obtained from reservoir fragments and unconsolidated core, greatly reducing the levels of uncertainty associated with field developments. This has great commercial and strategic significance for Australia, where future potential reserve ....A dynamic pore-network model for fluid displacements in porous media. The project will have a major impact on the up-stream oil and gas industry nationally and worldwide. It will allow data crucial to the development and optimization of oil and gas fields to be obtained from reservoir fragments and unconsolidated core, greatly reducing the levels of uncertainty associated with field developments. This has great commercial and strategic significance for Australia, where future potential reserves are located in remote offshore deep water areas where technological uncertainties are a major obstacle to timely development.Read moreRead less
Assessing reservoir performance for carbon storage in saline aquifers. This project aims to develop a multiscale framework of site characterisation for carbon storage in deep saline aquifers and calculate measures of injectivity, storage capacity and containment. Carbon capture and storage could reduce carbon emissions within two decades. Carbon dioxide emissions are the most important drivers of climate change, with detrimental effects on humans and their environment, including water security, ....Assessing reservoir performance for carbon storage in saline aquifers. This project aims to develop a multiscale framework of site characterisation for carbon storage in deep saline aquifers and calculate measures of injectivity, storage capacity and containment. Carbon capture and storage could reduce carbon emissions within two decades. Carbon dioxide emissions are the most important drivers of climate change, with detrimental effects on humans and their environment, including water security, agriculture, coastal communities, and infrastructure. This project will improve assessment of reservoir performance for carbon storage in saline aquifers, and help reduce carbon emissions.Read moreRead less
Multiscale modelling of multiphase interactions in shale gas reservoirs. As conventional oil and gas become depleted in most of the producing basins, extraction of unconventional gas trapped in shale formations needs to become more viable. Since Australian shales have different characteristics from North American ones, the existing knowledge cannot be directly applied. We aim to develop a novel multiscale framework for deep understanding of the complex multiphase interactions in shale gas reserv ....Multiscale modelling of multiphase interactions in shale gas reservoirs. As conventional oil and gas become depleted in most of the producing basins, extraction of unconventional gas trapped in shale formations needs to become more viable. Since Australian shales have different characteristics from North American ones, the existing knowledge cannot be directly applied. We aim to develop a novel multiscale framework for deep understanding of the complex multiphase interactions in shale gas reservoirs. The outcomes will not only enable us to effectively assess the viability of gas extraction from Australian shale reservoirs with accurate long-term production forecasting, but help to develop strategies to effectively extract this relatively low carbon-emitting fossil fuel in the transition to a renewable economy.Read moreRead less
X-ray imaging and magnetic resonance approach for enhanced oil recovery. This project aims to develop an efficient multi-scale modelling capability to quantify the effect of two-phase fluid flow within porous material by modelling rock wettability heterogeneity and alteration on two-phase flow performance for heterogeneous rock. Super-resolution methods combined with a deep learning approach will be used to determine a digital representation of reservoir rock, achieving an unprecedented combinat ....X-ray imaging and magnetic resonance approach for enhanced oil recovery. This project aims to develop an efficient multi-scale modelling capability to quantify the effect of two-phase fluid flow within porous material by modelling rock wettability heterogeneity and alteration on two-phase flow performance for heterogeneous rock. Super-resolution methods combined with a deep learning approach will be used to determine a digital representation of reservoir rock, achieving an unprecedented combination of resolution necessary to resolve small-scale fluid connectivity and field of view required to capture heterogeneity. The project expects to develop a workflow to populate a high-resolution model with wettability parameters by combining micro-CT imaging with nuclear magnetic resonance measurements. This improved understanding should provide significant benefits by enhancing our capability to optimise enhanced oil and gas recovery programs.Read moreRead less
Geological sequestration of carbon dioxide in deep saline aquifers: coupled flow-mechanical considerations. Deep saline aquifers have been routinely proposed as sites for long-term, large-scale storage of carbon dioxide (CO2) emissions, as an option to assist the abatement of global warming. This project investigates expected engineering behaviour of deep saline aquifer reservoirs and their stability following CO2 sequestration.