Cooper Basin REM gas shales after CO2 storage or acid reactions: Metal mobilisation and methane accessible pore changes
暂无分享,去创建一个
D. Paterson | V. Rudolph | Y. Melnichenko | G. Southam | J. Pearce | G. Dawson | S. Golding | T. Blach | J. Bahadur
[1] S. Marathe,et al. Nano-scale synchrotron imaging of shale swelling in the presence of water , 2023, Fuel.
[2] N. Harris,et al. The Effects of Jurassic Igneous Intrusions on the Generation and Retention of Gas Shale in the Lower Permian Source-Reservoir Shales of Karoo Basin, South Africa , 2023, SSRN Electronic Journal.
[3] J. Esterle,et al. Reservoir lithofacies study of the Toolebuc formation, Eromanga basin, Australia as a potential unconventional target , 2022, International Journal of Coal Geology.
[4] H. Hofmann,et al. Methane in aquifers and alluvium overlying a coal seam gas region: Gas concentrations and isotopic differentiation. , 2022, The Science of the total environment.
[5] Zhongwei Huang,et al. Changes in microstructure and mechanical properties of shales exposed to supercritical CO2 and brine , 2022, International Journal of Rock Mechanics and Mining Sciences.
[6] J. Pearce,et al. Co2 and Nox Reactions with Co2 Storage Reservoir Core: Nox Dissolution Products and Mineral Reactions , 2022, SSRN Electronic Journal.
[7] Jiang Liu,et al. Comprehensive Review of Property Alterations Induced by CO2–Shale Interaction: Implications for CO2 Sequestration in Shale , 2022, Energy & Fuels.
[8] D. Kirste,et al. Metal Mobilization From CO2 Storage Cap-Rocks: Experimental Reactions With Pure CO2 or CO2 SO2 NO , 2022, Frontiers in Energy Research.
[9] A. Kalinichev,et al. Molecular-level understanding of metal ion retention in clay-rich materials , 2022, Nature Reviews Earth & Environment.
[10] A. Kalinowski,et al. The search for new oil and CO , 2022, The APPEA Journal.
[11] T. Palu,et al. Petroleum supersystems in the greater McArthur Basin, Northern Territory, Australia: prospectivity of the world’s oldest stacked systems with emphasis on the McArthur Supersystem , 2022, The APPEA Journal.
[12] J. Owen,et al. Techno-economic evaluation of blue hydrogen production with carbon capture and storage for onshore Eastern Australia , 2022, The APPEA Journal.
[13] B. Rostron,et al. Unlocking the potential of hydraulic fracturing flowback and produced water for CO2 removal via mineral carbonation , 2022, Applied Geochemistry.
[14] S. Raza,et al. Unconventional CO2 Storage: CO2 Mineral Trapping Predicted in Characterized Shales, Sandstones, and Coal Seam Interburden , 2022, SPE Journal.
[15] D. Paterson,et al. Predicted CO2 water rock reactions in naturally altered CO2 storage reservoir sandstones, with interbedded cemented and coaly mudstone seals , 2022, International Journal of Coal Geology.
[16] V. Rudolph,et al. Geological storage of CO2 and acid gases dissolved at surface in production water , 2022, Journal of Petroleum Science and Engineering.
[17] A. Estublier,et al. Dissolved trace elements dynamics during a rich-CO2-water leakage in a near-surface carbonate freshwater aquifer , 2022, International Journal of Greenhouse Gas Control.
[18] L. Stalker,et al. Communicating leakage risk in the hydrogen economy: Lessons already learned from geoenergy industries , 2019, Frontiers in Energy Research.
[19] D. Paterson,et al. Core characterisation and predicted CO2 reactivity of sandstones and mudstones from an Australian oil field , 2021, International Journal of Coal Geology.
[20] J. Kaszuba,et al. Ionic Strength and pH Effects on WaterRock Interaction in an Unconventional Siliceous Reservoir: On the Use of Formation Water in Hydraulic Fracturing , 2021, Energy & Fuels.
[21] S. Sommacal,et al. Micro CT and Experimental Study of Carbonate Precipitation from CO2 and Produced Water Co-Injection into Sandstone , 2021, Energies.
[22] P. Ranjith,et al. Comparison of fracturing unconventional gas reservoirs using CO2 and water: An experimental study , 2021 .
[23] B. Mayer,et al. Potential Impacts of Shale Gas Development on Inorganic Groundwater Chemistry: Implications for Environmental Baseline Assessment in Shallow Aquifers. , 2021, Environmental science & technology.
[24] J. Kaszuba,et al. Geochemical reactions and alteration of pore architecture in saturated shale after injection of stimulation fluid , 2021 .
[25] A. L. La Croix,et al. CO2 mineral trapping comparison in different regions: predicted geochemical reactivity of the Precipice Sandstone reservoir and overlying Evergreen Formation , 2021, Petroleum Geoscience.
[26] G. Cui,et al. Geochemical reactions and their influence on petrophysical properties of ultra-low permeability oil reservoirs during water and CO2 flooding , 2021 .
[27] L. Beckingham,et al. The impact of mineral reactive surface area variation on simulated mineral reactions and reaction rates , 2021 .
[28] M. D. de Jonge,et al. The XFM beamline at the Australian Synchrotron. , 2020, Journal of synchrotron radiation.
[29] A. L. La Croix,et al. Long term reactivity of CO2 in a low salinity reservoir-seal complex , 2020 .
[30] Sandra Ó. Snæbjörnsdóttir,et al. Carbon dioxide storage through mineral carbonation , 2020, Nature Reviews Earth & Environment.
[31] B. Mayer,et al. Hydro-biogeochemical impacts of fugitive methane on a shallow unconfined aquifer. , 2019, The Science of the total environment.
[32] D. Kirste,et al. Geochemical modelling of experimental O2–SO2–CO2 reactions of reservoir, cap-rock, and overlying cores , 2019, Applied Geochemistry.
[33] S. Barakat,et al. An Australian first initiative to re-develop the first commercial onshore oilfield into a CO2 miscible-EOR project , 2019, The APPEA Journal.
[34] A. Bell,et al. Structural controls on the location and distribution of CO2 emission at a natural CO2 spring in Daylesford, Australia , 2019, International Journal of Greenhouse Gas Control.
[35] D. Kirste,et al. Trace element mobility during CO2 storage: application of reactive transport modelling , 2019, E3S Web of Conferences.
[36] S. Sommacal,et al. A combined geochemical and μCT study on the CO2 reactivity of Surat Basin reservoir and cap-rock cores: Porosity changes, mineral dissolution and fines migration , 2019, International Journal of Greenhouse Gas Control.
[37] S. Inan,et al. Formation and occurrence of organic matter-hosted porosity in shales , 2018, International Journal of Coal Geology.
[38] L. Connell,et al. Controls on methane sorption capacity of Mesoproterozoic gas shales from the Beetaloo Sub-basin, Australia and global shales , 2018, International Journal of Coal Geology.
[39] J. Hakala,et al. Role of water−rock interaction in the geochemical evolution of Marcellus Shale produced waters , 2018 .
[40] J. Bahadur,et al. Porosity of the Marcellus Shale: A contrast matching small-angle neutron scattering study , 2018 .
[41] J. Pearce,et al. Experimental and predicted geochemical shale-water reactions: Roseneath and Murteree shales of the Cooper Basin , 2018 .
[42] Y. Melnichenko,et al. Pore structure characterization of organic-rich Niutitang shale from China: Small angle neutron scattering (SANS) study , 2018 .
[43] M. Bickle,et al. A siltstone reaction front related to CO2- and sulfur-bearing fluids: Integrating quantitative elemental mapping with reactive transport modeling , 2018 .
[44] T. Blach,et al. Impure CO2 reaction of feldspar, clay, and organic matter rich cap-rocks: Decreases in the fraction of accessible mesopores measured by SANS , 2018 .
[45] Li Ning,et al. Effects of CO 2 –brine–rock interaction on porosity/permeability and mechanical properties during supercritical-CO 2 fracturing in shale reservoirs , 2018 .
[46] J. Kaszuba,et al. Reactivity of supercritical sulfur dioxide and carbon dioxide in a carbonate reservoir: An experimental investigation of supercritical fluid-brine-rock interactions relevant to the Madison Limestone of Southwest Wyoming , 2017 .
[47] J. Hakala,et al. Mineral Reactions in Shale Gas Reservoirs: Barite Scale Formation from Reusing Produced Water As Hydraulic Fracturing Fluid. , 2017, Environmental science & technology.
[48] A. Harrison,et al. Element release and reaction-induced porosity alteration during shale-hydraulic fracturing fluid interactions , 2017 .
[49] A. Harrison,et al. Impact of Organics and Carbonates on the Oxidation and Precipitation of Iron during Hydraulic Fracturing of Shale , 2017 .
[50] C. Lopano,et al. Experimental insights into geochemical changes in hydraulically fractured Marcellus Shale , 2017 .
[51] D. Kirste,et al. Parameterizing Geochemical Models: Do Kinetics of Calcite Matter? , 2017 .
[52] Xiaoran Ming,et al. Bleached mudstone, iron concretions, and calcite veins: a natural analogue for the effects of reducing CO2‐bearing fluids on migration and mineralization of iron, sealing properties, and composition of mudstone cap rocks , 2016 .
[53] Ramesh K. Agarwal,et al. Numerical simulation of long-term storage of CO2 in Yanchang shale reservoir of the Ordos basin in China , 2016 .
[54] Ali Saeedi,et al. Flood characteristic and fluid rock interactions of a supercritical CO2, brine, rock system: South West Hub, Western Australia , 2016 .
[55] R. S. MillerQuin,et al. Experimental Study of Porosity Changes in Shale Caprocks Exposed to CO2-Saturated Brines I: Evolution of Mineralogy, Pore Connectivity, Pore Size Distribution, and Surface Area , 2016 .
[56] K. Sugawara,et al. Effect of NO2 in exhaust gas from an oxyfuel combustion system on the cap rock of a proposed CO2 injection site , 2016 .
[57] I. Cozzarelli,et al. Wastewater Disposal from Unconventional Oil and Gas Development Degrades Stream Quality at a West Virginia Injection Facility. , 2016, Environmental science & technology.
[58] A. Hendriks,et al. Environmental contamination due to shale gas development. , 2016, The Science of the total environment.
[59] T. Blenkinsop,et al. Mineralogical modelling and petrophysical parameters in Permian gas shales from the Roseneath and Murteree formations, Cooper Basin, Australia , 2016 .
[60] J. Fortner,et al. Element mobilization from Bakken shales as a function of water chemistry. , 2016, Chemosphere.
[61] J. Landis,et al. Reductive weathering of black shale and release of barium during hydraulic fracturing , 2016 .
[62] T. Blenkinsop,et al. Organic petrography and thermal maturity of the Permian Roseneath and Murteree shales in the Cooper Basin, Australia , 2016 .
[63] J. Erzinger,et al. Induced mobility of inorganic and organic solutes from black shales using water extraction: Implications for shale gas exploitation , 2015 .
[64] J. Kaszuba,et al. Carbon dioxide–brine–rock interactions in a carbonate reservoir capped by shale: Experimental insights regarding the evolution of trace metals , 2015 .
[65] S. Golding,et al. SO2–CO2 and pure CO2 reactivity of ferroan carbonates at carbon storage conditions , 2015 .
[66] J. Toro,et al. Trace metal distribution and mobility in drill cuttings and produced waters from Marcellus Shale gas extraction: Uranium, arsenic, barium , 2015 .
[67] Jason D. Johnson,et al. Fingerprinting Marcellus Shale waste products from Pb isotope and trace metal perspectives , 2015 .
[68] S. Talman. Subsurface geochemical fate and effects of impurities contained in a CO2 stream injected into a deep saline aquifer: What is known , 2015 .
[69] Suzanne D. Golding,et al. Microbial controls on the origin and evolution of coal seam gases and production waters of the Walloon Subgroup; Surat Basin, Australia , 2015 .
[70] M. Pourkashanian,et al. The range and level of impurities in CO2 streams from different carbon capture sources , 2015 .
[71] D. Kirste,et al. SO2 impurity impacts on experimental and simulated CO2–water–reservoir rock reactions at carbon storage conditions , 2015 .
[72] S. Sommacal,et al. A fresh approach to investigating CO2 storage: Experimental CO2-water-rock interactions in a low-salinity reservoir system , 2015 .
[73] Wanglin,et al. Impact of Water Chemistry on Element Mobilization from Eagle Ford Shale , 2015 .
[74] Weiwei Wu,et al. Acid Fracturing Shales: Effect of Dilute Acid on Properties and Pore Structure of Shale , 2015 .
[75] A. Schimmelmann,et al. Small-Angle and Ultrasmall-Angle Neutron Scattering (SANS/USANS) Study of New Albany Shale: A Treatise on Microporosity , 2015 .
[76] H. Shao,et al. Mobilization of metals from Eau Claire siltstone and the impact of oxygen under geological carbon dioxide sequestration conditions , 2014 .
[77] D. P. Siddons,et al. Maia X-ray fluorescence imaging: Capturing detail in complex natural samples , 2014 .
[78] Fugang Wang,et al. A numerical study of mineral alteration and self-sealing efficiency of a caprock for CO2 geological storage , 2014 .
[79] A. Navarre‐Sitchler,et al. Porosity and surface area evolution during weathering of two igneous rocks , 2013 .
[80] J. Fitts,et al. Dissolution-Driven Permeability Reduction of a Fractured Carbonate Caprock. , 2013, Environmental engineering science.
[81] Sheila M. Olmstead,et al. Shale gas development impacts on surface water quality in Pennsylvania , 2013, Proceedings of the National Academy of Sciences.
[82] Vincent Lagneau,et al. Assessing the potential consequences of CO2 leakage to freshwater resources: A batch-reaction experiment towards an isotopic tracing tool , 2013 .
[83] Lilin He,et al. A USANS/SANS Study of the Accessibility of Pores in the Barnett Shale to Methane and Water , 2013 .
[84] S. Carroll,et al. Evaporite caprock integrity: an experimental study of reactive mineralogy and pore-scale heterogeneity during brine-CO2 exposure. , 2013, Environmental science & technology.
[85] V. Urban,et al. The 40 m general purpose small-angle neutron scattering instrument at Oak Ridge National Laboratory , 2012 .
[86] Hari S. Viswanathan,et al. Developing a robust geochemical and reactive transport model to evaluate possible sources of arsenic at the CO2 sequestration natural analog site in Chimayo, New Mexico , 2012 .
[87] Benoît Dubacq,et al. Fluid-mineral reactions and trace metal mobilization in an exhumed natural CO2 reservoir, Green River, Utah , 2012 .
[88] K. Schroeder,et al. Geochemical and strontium isotope characterization of produced waters from Marcellus Shale natural gas extraction. , 2012, Environmental science & technology.
[89] Maria Mastalerz,et al. Accessibility of pores in coal to methane and carbon dioxide , 2012 .
[90] C. Ryan,et al. The X-ray Fluorescence Microscopy Beamline at the Australian Synchrotron , 2011 .
[91] D. Dzombak,et al. Water Management Challenges Associated with the Production of Shale Gas by Hydraulic Fracturing , 2011 .
[92] R. Jackson,et al. Methane contamination of drinking water accompanying gas-well drilling and hydraulic fracturing , 2011, Proceedings of the National Academy of Sciences.
[93] D. P. Siddons,et al. The new Maia detector system : Methods for High Definition Trace Element Imaging of natural material , 2010 .
[94] M. Curtis,et al. Structural Characterization of Gas Shales on the Micro- and Nano-Scales , 2010 .
[95] R. Marc Bustin,et al. The importance of shale composition and pore structure upon gas storage potential of shale gas reservoirs , 2009 .
[96] A. Love,et al. Sr isotopes in natural waters: Applications to source characterisation and water–rock interaction in contrasting landscapes , 2009 .
[97] Andreas Busch,et al. Carbon dioxide storage potential of shales , 2008 .
[98] Carl I. Steefel,et al. Scale dependence of mineral dissolution rates within single pores and fractures , 2008 .
[99] Jan M. Nordbotten,et al. Evaluation of the spread of acid-gas plumes injected in deep saline aquifers in western Canada as an analogue for CO2 injection into continental sedimentary basins , 2005 .