Experimental Investigation of the Geochemical Interactions between Supercritical CO<sub>2</sub> and Shale: Implications for CO<sub>2</sub> Storage in Gas-Bearing Shale Formations

Pan, Yi; Hui, Dong; Luo, Pingya; Zhang, Yan; Sun, Lijun; Wang, Ke

doi:10.1021/acs.energyfuels.7b03074

Cited by 107 publications

(99 citation statements)

References 86 publications

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“…These equations (Eqs. 10, 11 and 13) represent the fundamental equations for the modeling of storage of CO 2 in porous media (DePaolo et al 2019;Nghiem et al 2004;Pan et al 2018a). These equations could be coupled with geochemical reactions, geomechanical modules and other relevant physical phenomena.…”

Section: Physical Processes During Co 2 Storagementioning

confidence: 99%

A review of CO2 storage in geological formations emphasizing modeling, monitoring and capacity estimation approaches

2019

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The merits of CO 2 capture and storage to the environmental stability of our world should not be underestimated as emissions of greenhouse gases cause serious problems. It represents the only technology that might rid our atmosphere of the main anthropogenic gas while allowing for the continuous use of the fossil fuels which still power today's world. Underground storage of CO 2 involves the injection of CO 2 into suitable geological formations and the monitoring of the injected plume over time, to ensure containment. Over the last two or three decades, attention has been paid to technology developments of carbon capture and sequestration. Therefore, it is high time to look at the research done so far. In this regard, a high-level review article is required to provide an overview of the status of carbon capture and sequestration research. This article presents a review of CO 2 storage technologies which includes a background of essential concepts in storage, the physical processes involved, modeling procedures and simulators used, capacity estimation, measuring monitoring and verification techniques, risks and challenges involved and field-/pilot-scale projects. It is expected that the present review paper will help the researchers to gain a quick knowledge of CO 2 sequestration for future research in this field. Keywords CO 2 storage • Geological formation • Modeling for CO 2 storage • Mechanism of CO 2 storage • CO 2 storage projects Edited by Yan-Hua Sun

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Section: Physical Processes During Co 2 Storagementioning

confidence: 99%

A review of CO2 storage in geological formations emphasizing modeling, monitoring and capacity estimation approaches

2019

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“…In the long-term, formation brine will dissolve the injected CO 2 and causes reactions with the shale rock, leading to mineral precipitation and dissolution which may affect the shale storage capacity [1,38]. The CO 2 /shale interaction is a key factor for the efficiency of CCS in shale formations; it can significantly alter the shale properties, which in return affect the rock geometry, fluid transportation, and storage capacity [39,40]. The presence of organic and inorganic components in a heterogeneous porous medium such as shale permits the injected CO 2 to interact with clay minerals and organic matter through chemical dissolution [39].…”

Section: Ccs In Shalesmentioning

confidence: 99%

A Review on the Influence of CO2/Shale Interaction on Shale Properties: Implications of CCS in Shales

et al. 2020

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Carbon capture and storage (CCS) is a developed technology to minimize CO2 emissions and reduce global climate change. Currently, shale gas formations are considered as a suitable target for CO2 sequestration projects predominantly due to their wide availability. Compared to conventional geological formations including saline aquifers and coal seams, depleted shale formations provide larger storage potential due to the high adsorption capacity of CO2 compared to methane in the shale formation. However, the injected CO2 causes possible geochemical interactions with the shale formation during storage applications and CO2 enhanced shale gas recovery (ESGR) processes. The CO2/shale interaction is a key factor for the efficiency of CO2 storage in shale formations, as it can significantly alter the shale properties. The formation of carbonic acid from CO2 dissolution is the main cause for the alterations in the physical, chemical and mechanical properties of the shale, which in return affects the storage capacity, pore properties, and fluid transport. Therefore, in this paper, the effect of CO2 exposure on shale properties is comprehensively reviewed, to gain an in-depth understanding of the impact of CO2/shale interaction on shale properties. This paper reviews the current knowledge of the CO2/shale interactions and describes the results achieved to date. The pore structure is one of the most affected properties by CO2/shale interactions; several scholars indicated that the differences in mineral composition for shales would result in wide variations in pore structure system. A noticeable reduction in specific surface area of shales was observed after CO2 treatment, which in the long-term could decrease CO2 adsorption capacity, affecting the CO2 storage efficiency. Other factors including shale sedimentary, pressure and temperature can also alter the pore system and decrease the shale “caprock” seal efficiency. Similarly, the alteration in shales’ surface chemistry and functional species after CO2 treatment may increase the adsorption capacity of CO2, impacting the overall storage potential in shales. Furthermore, the injection of CO2 into shales may also influence the wetting behavior. Surface wettability is mainly affected by the presented minerals in shale, and less affected by brine salinity, temperature, organic content, and thermal maturity. Mainly, shales have strong water-wetting behavior in the presence of hydrocarbons, however, the alteration in shale’s wettability towards CO2-wet will significantly minimize CO2 storage capacities, and affect the sealing efficiency of caprock. The CO2/shale interactions were also found to cause noticeable degradation in shales’ mechanical properties. CO2 injection can weaken shale, decrease its brittleness and increases its plasticity and toughness. Various reductions in tri-axial compressive strength, tensile strength, and the elastic modulus of shales were observed after CO2 injection, due to the dissolution effect and adsorption strain within the pores. Based on this review, we conclude that CO2/shale interaction is a significant factor for the efficiency of CCS. However, due to the heterogeneity of shales, further studies are needed to include various shale formations and identify how different shales’ mineralogy could affect the CO2 storage capacity in the long-term.

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“…Gas adsorption-or desorption-induced swelling or shrinkage of shale can affect the pore structure and have an impact on gas transport in shale [74,75]. Recently, many studies focused on the change of physio-chemical properties of shale due to carbon dioxide (or other gases) injection.…”

Section: Physio-chemical Properties Measurementsmentioning

confidence: 99%

“…Recently, many studies focused on the change of physio-chemical properties of shale due to carbon dioxide (or other gases) injection. The adsorption capacities of different gases [74][75][76][77][78], adsorption-induced swelling strain and swelling rate [77,79,80], gas diffusion in shale [76,81], and physical and chemical structure change [82] have been investigated in different studies.…”

Section: Physio-chemical Properties Measurementsmentioning

confidence: 99%

A Review of Gas Injection in Shale Reservoirs: Enhanced Oil/Gas Recovery Approaches and Greenhouse Gas Control

Nojabaei

2019

Energies

107

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Shale oil and gas resources contribute significantly to the energy production in the U.S. Greenhouse gas emissions come from combustion of fossil fuels from potential sources of power plants, oil refineries, and flaring or venting of produced gas (primarily methane) in oilfields. Economic utilization of greenhouse gases in shale reservoirs not only increases oil or gas recovery, but also contributes to CO2 sequestration. In this paper, the feasibility and efficiency of gas injection approaches, including huff-n-puff injection and gas flooding in shale oil/gas/condensate reservoirs are discussed based on the results of in-situ pilots, and experimental and simulation studies. In each section, one type of shale reservoir is discussed, with the following aspects covered: (1) Experimental and simulation results for different gas injection approaches; (2) mechanisms of different gas injection approaches; and (3) field pilots for gas injection enhanced oil recovery (EOR) and enhanced gas recovery (EGR). Based on the experimental and simulation studies, as well as some successful field trials, gas injection is deemed as a potential approach for EOR and EGR in shale reservoirs. The enhanced recovery factor varies for different experiments with different rock/fluid properties or models incorporating different effects and shale complexities. Based on the simulation studies and successful field pilots, CO2 could be successfully captured in shale gas reservoirs through gas injection and huff-n-puff regimes. The status of flaring gas emissions in oilfields and the outlook of economic utilization of greenhouse gases for enhanced oil or gas recovery and CO2 storage were given in the last section. The storage capacity varies in different simulation studies and is associated with well design, gas injection scheme and operation parameters, gas adsorption, molecular diffusion, and the modelling approaches.

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Experimental Investigation of the Geochemical Interactions between Supercritical CO₂ and Shale: Implications for CO₂ Storage in Gas-Bearing Shale Formations

Cited by 107 publications

References 86 publications

A review of CO2 storage in geological formations emphasizing modeling, monitoring and capacity estimation approaches

A review of CO2 storage in geological formations emphasizing modeling, monitoring and capacity estimation approaches

A Review on the Influence of CO2/Shale Interaction on Shale Properties: Implications of CCS in Shales

A Review of Gas Injection in Shale Reservoirs: Enhanced Oil/Gas Recovery Approaches and Greenhouse Gas Control

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Experimental Investigation of the Geochemical Interactions between Supercritical CO2 and Shale: Implications for CO2 Storage in Gas-Bearing Shale Formations

Cited by 107 publications

References 86 publications

A review of CO2 storage in geological formations emphasizing modeling, monitoring and capacity estimation approaches

A review of CO2 storage in geological formations emphasizing modeling, monitoring and capacity estimation approaches

A Review on the Influence of CO2/Shale Interaction on Shale Properties: Implications of CCS in Shales

A Review of Gas Injection in Shale Reservoirs: Enhanced Oil/Gas Recovery Approaches and Greenhouse Gas Control

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Experimental Investigation of the Geochemical Interactions between Supercritical CO₂ and Shale: Implications for CO₂ Storage in Gas-Bearing Shale Formations