Injectivity and quantification of capillary trapping for CO 2 storage: A review of influencing parameters

Raza, Arshad; Rezaee, Reza; Gholami, Raoof; Rasouli, Vamegh; Bing, Chua Han; Nagarajan, R.; Hamid, Mohamed Ali

doi:10.1016/j.jngse.2015.06.046

Cited by 65 publications

(47 citation statements)

References 81 publications

(123 reference statements)

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“…Heterogeneity may have impacts on the multiphase flow of CO 2 ‐brine and can be expressed in terms of permeability variation . The storage capacity is linked to heterogeneities and porosity, whereas injectivity is related to petrophysical properties such as permeability . To analyze the effect of permeability, numerical simulation was run by considering the channel permeability of 400 mD by considering reduction factor in the base cases (dry, wet, and condensate).…”

Section: Sensitivity Analysismentioning

confidence: 99%

“…28 The storage capacity is linked to heterogeneities and porosity, whereas injectivity is related to petrophysical properties such as permeability. 58 To analyze the effect of permeability, numerical simulation was run by considering the channel permeability of 400 mD by considering reduction factor in the base cases (dry, wet, and condensate). The results obtained, which are shown in Fig.…”

Section: Heterogeneitymentioning

confidence: 99%

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Suitability of depleted gas reservoirs for geological CO₂ storage: A simulation study

et al. 2018

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Hydrocarbon reservoirs, particularly depleted gas formations, are promising geological sites for CO2 storage. Although there have been many studies on the storage aspects of gas reservoirs, the suitability of these formations in terms of fluid types such as dry, wet, and condensate gas has not been properly addressed at the reservoir level. In this study, an attempt was made to evaluate different gas reservoirs in order to provide an insight into their storage capabilities. A dynamic numerical simulation was carried out to simulate CO2 injection in a synthetic but realistic model of a geologic formation having dry, wet, or condensate gas. The results obtained under particular conditions revealed that the condensate gas medium offers a good storage potential, favorable injectivity, and reasonable pressure buildup over a long period of time, whereas dry gas formations were found to be the least favorable sites for storage among gas reservoirs. A sensitivity analysis was done to evaluate the injection rate and the permeability variation of different media during and after the storage. It indicated that the storage behavior of gas reservoirs is sensitive to the injection rate, and selection of an optimum injection rate might help to achieve a good storage capacity in condensate gas systems. The results also highlighted that CO2 immobilization in gas reservoirs after injection is enhanced due to the reduction of permeability, whereas no heterogeneity effect was observed under different permeability realizations. © 2018 Society of Chemical Industry and John Wiley & Sons, Ltd.

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Section: Sensitivity Analysismentioning

confidence: 99%

Section: Heterogeneitymentioning

confidence: 99%

Suitability of depleted gas reservoirs for geological CO₂ storage: A simulation study

et al. 2018

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“…Geomechanical issues may also rise during and after CO 2 injection due to the pressure buildup, which may induce irreversible geomechanical changes such as vertical uplift, fault reactivations, and fractures generation within the reservoir and caprock . As such, geomechanical alterations in the presence of chemical interactions and pressure buildup must be analyzed very carefully when it comes to CO 2 storage sites …”

Section: Introductionmentioning

confidence: 99%

“…[6][7][8] As such, geomechanical alterations in the presence of chemical interactions and pressure buildup must be analyzed very carefully when it comes to CO 2 storage sites. 9,10 Many coupled fluid flow and geomechanical studies have been done in the past decade to simulate the vertical ground movement, caprock fracturing, and fault reactivation in aquifers upon CO 2 injection. [11][12][13][14][15][16][17][18] There have also been many numerical 2,19-21 and experimental 22-26 studies addressing the time-dependent geomechanical integrity of sandstone aquifers.…”

Section: Introductionmentioning

confidence: 99%

Impact of geochemical and geomechanical changes on CO₂ sequestration potential in sandstone and limestone aquifers

et al. 2019

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CO2 storage in different geological formations has been recognized as one of the promising mitigation approaches to reduce the emission of CO2 into the atmosphere. There are many complex hydro‐chemo‐mechanical interactions (effective stress changes, water acidification, and mineral dissolution) that may take place in a storage site during or after injection, reducing the integrity of formations in the short or long term. Although there have been several studies carried out in the past to assess the feasibility of sandstones and limestone formations as a safe CO2 storage site, the effect of hydrological, mechanical, and chemical processes on the storage site integrity has not been deeply addressed. The aim of this study is to couple thermo‐hydro‐chemo‐mechanical processes upon CO2 injection and assess their impact on the key storage aspects of quartz‐rich sandstone and calcite‐rich limestone. A numerical model was built to simulate CO2 flooding into a saline aquifer with sandstone and limestone composition for 500 years. The results obtained indicated that geochemical activity and CO2 dissolution are significantly higher in limestone and may increase the porosity by ∼16%. During injection, a decrease in the reservoir strength was observed in both rock types upon exposure to CO2. A remarkable variation in the geomechanical characteristics was also revealed in the sandstone after injection. However, ground displacements (subsidence) of 0.0017 and 0.033 m were, respectively, observed in sandstone and limestone aquifers, at the end of 500 years. It is recommended to consider a high‐strength reservoir for carbon capture and storage (CCS) projects in order to reduce the likelihood of compaction. It was also found that both rock types have a good storage capacity, injectivity, and trapping potentials (the structural and dissolution trappings) to capture and hold CO2 in place. © 2019 Society of Chemical Industry and John Wiley & Sons, Ltd.

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“…CO 2 is stored in the geological formations by four main mechanisms: (i) structure and stratigraphic trapping; (ii) residual trapping; (iii) solubility trapping; and (iv) mineral trapping (Broseta, Tonnet, & Shah, 2012). Residual or capillary trapping is one of the most important mechanisms of gas trapping during CO 2 sequestration in subsurface formations (Al-Menhali & Krevor, 2016;Herring, Andersson, & Wildenschild, 2016;Juanes, Spiteri, Orr, & Blunt, 2006;Raza et al, 2015;Suekane, Nobuso, Hirai, & Kiyota, 2008). This trapping occurs when underground water tries to displace injected CO 2 leaving behind a trail of residual CO 2 .…”

Section: Introductionmentioning

confidence: 99%

Improving Gas Sequestration by Surfactant‐Alternating‐Gas Injection: A Comparative Evaluation of the Surfactant Type and Concentration

Kamal

Adebayo

Fogang

et al. 2018

J Surfact & Detergents

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Gas injection into porous subsurface geological formations for geological storage is currently considered the most preferable and practicable means of reducing greenhouse gases due to the huge capacity of deep saline aquifers. Residual trapping of gas plays an important role in immobilization of injected gas into an aquifer. Surfactant‐alternating‐gas (SAG) injection can be used as a mobility control method in gas sequestration and several simulation studies explained different aspects of residual‐gas trapping. However, research in this field is inconclusive and needs more attention to develop a better understanding. In this work, we used 3 different surfactants from different classes at various concentrations to assess gas‐sequestration efficiency using SAG methods in carbonate and sandstone rocks. This work is the first of its kind on the comparative performance of different surfactants for gas sequestration in different rocks. The surfactants were hydrocarbon zwitterionic, fluorinated zwitterionic, and nonionic. It was found that residual‐gas saturation increases by increasing the surfactant concentration. The increase in residual trapping with surfactant concentration also depends on the type of surfactant and rock. In both rock types considered, the best performance was achieved using fluorinated zwitterionic surfactants followed by hydrocarbon zwitterionic surfactants. In addition, a synergetic effect between hydrocarbon and fluorinated surfactants further improves the residual‐gas saturation. The residual‐gas trapping was higher in the tight sample compared to highly permeable samples. This will help in developing an understanding of surfactant optimization and selection for gas sequestration using the SAG method.

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Injectivity and quantification of capillary trapping for CO 2 storage: A review of influencing parameters

Cited by 65 publications

References 81 publications

Suitability of depleted gas reservoirs for geological CO₂ storage: A simulation study

Suitability of depleted gas reservoirs for geological CO₂ storage: A simulation study

Impact of geochemical and geomechanical changes on CO₂ sequestration potential in sandstone and limestone aquifers

Improving Gas Sequestration by Surfactant‐Alternating‐Gas Injection: A Comparative Evaluation of the Surfactant Type and Concentration

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Injectivity and quantification of capillary trapping for CO 2 storage: A review of influencing parameters

Cited by 65 publications

References 81 publications

Suitability of depleted gas reservoirs for geological CO2 storage: A simulation study

Suitability of depleted gas reservoirs for geological CO2 storage: A simulation study

Impact of geochemical and geomechanical changes on CO2 sequestration potential in sandstone and limestone aquifers

Improving Gas Sequestration by Surfactant‐Alternating‐Gas Injection: A Comparative Evaluation of the Surfactant Type and Concentration

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Product

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Suitability of depleted gas reservoirs for geological CO₂ storage: A simulation study

Suitability of depleted gas reservoirs for geological CO₂ storage: A simulation study

Impact of geochemical and geomechanical changes on CO₂ sequestration potential in sandstone and limestone aquifers