CO2 Injection into Saline Carbonate Aquifer Formations II: Comparison of Numerical Simulations to Experiments

Izgec, Omer; Demiral, Birol; Bertin, Henri; Akın, Serhat

doi:10.1007/s11242-007-9160-1

Cited by 52 publications

(35 citation statements)

References 38 publications

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“…15. The details of the numerical model can be found elsewhere (Izgec et al 2007). In order to show that the model could be used to simulate the experiments a synthetic case similar to experiments 1 was used.…”

Section: Core-scale Numerical Modelmentioning

confidence: 99%

CO2 injection into saline carbonate aquifer formations I: laboratory investigation

et al. 2007

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Although there are a number of mathematical modeling studies for carbon dioxide (CO 2 ) injection into aquifer formations, experimental studies are limited and most studies focus on injection into sandstone reservoirs as opposed to carbonate ones. This study presents the results of computerized tomography (CT) monitored laboratory experiments to analyze permeability and porosity changes as well as to characterize relevant chemical reactions associated with injection and storage of CO 2 in carbonate formations. CT monitored experiments are designed to model fast near well bore flow and slow reservoir flows. Highly heterogeneous cores drilled from a carbonate aquifer formation located in South East Turkey were used during the experiments. Porosity changes along the core plugs and the corresponding permeability changes are reported for different CO 2 injection rates and different salt concentrations of formation water. It was observed that either a permeability increase or a permeability reduction can be obtained. The trend of change in rock properties is very case dependent because it is related to distribution of pores, brine composition and thermodynamic conditions. As the salt concentration decreases, porosity and the permeability decreases are less pronounced. Calcite deposition is mainly influenced by orientation, with horizontal flow resulting in larger calcite deposition compared to vertical flow.

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Section: Core-scale Numerical Modelmentioning

confidence: 99%

CO2 injection into saline carbonate aquifer formations I: laboratory investigation

et al. 2007

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“…CO 2 dissolution into reservoir fluids during EOR flooding mildly acidifies the resident brines and causes carbonate minerals to dissolve sometimes resulting in the formation of highly porous and conductive channels (often referred to in the petroleum acidizing literature as ''wormholes,'' e.g., [6]). Despite the large number of experimental and numerical studies devoted to understanding permeability evolution in carbonate rocks, only a few of them have made direct, comprehensive comparisons between predictive models and experimental data (e.g., [18][19]). The result is a lack of proper quantitative calibration, which limits the application of essential features of chemical fluid-rock interactions at laboratory or reservoir scales.…”

Section: Introductionmentioning

confidence: 99%

CO2-induced dissolution of low permeability carbonates. Part II: Numerical modeling of experiments

Smith

Sholokhova

et al. 2013

Advances in Water Resources

112

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“…Reactive transport modeling has been previously used to investigate geochemical reactions and their effects on permeability and porosity evolution [14,15,[23][24][25][26]. André et al [14] simulated CO 2 storage in the carbonate-rich Dogger aquifer in the Paris Basin (France) using the reactive transport simulator TOUGHREACT.…”

Section: Introductionmentioning

confidence: 99%

“…Some studies [25,26] also reported that geochemical reactions dissolved the host rock increasing porosity and permeability thereby affecting fluid flow through reactive transport modeling. On the other hand, Izgec et al [23] found that CO 2 injection into carbonate aquifers simulated using CMG's STARS could result in permeability reduction as well as improvement depending on the balance between mineral dissolution and precipitation. Furthermore, Sbai and Azaroual [24] found that CO 2 injection could in some circumstances cause particulates to clog reservoir pores leading to a permeability reduction and injectivity decline near the injection well.…”

Section: Introductionmentioning

confidence: 99%

Numerical Investigation into the Impact of CO₂-Water-Rock Interactions on CO₂ Injectivity at the Shenhua CCS Demonstration Project, China

Yang¹,

Li²,

Atrens³

et al. 2017

Geofluids

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A 100,000 t/year demonstration project for carbon dioxide (CO 2 ) capture and storage in the deep saline formations of the Ordos Basin, China, has been successfully completed. Field observations suggested that the injectivity increased nearly tenfold after CO 2 injection commenced without substantial pressure build-up. In order to evaluate whether this unique phenomenon could be attributed to geochemical changes, reactive transport modeling was conducted to investigate CO 2 -water-rock interactions and changes in porosity and permeability induced by CO 2 injection. The results indicated that using porosity-permeability relationships that include tortuosity, grain size, and percolation porosity, other than typical Kozeny-Carman porosity-permeability relationship, it is possible to explain the considerable injectivity increase as a consequence of mineral dissolution. These models might be justified in terms of selective dissolution along flow paths and by dissolution or migration of plugging fines. In terms of geochemical changes, dolomite dissolution is the largest source of porosity increase. Formation physical properties such as temperature, pressure, and brine salinity were found to have modest effects on mineral dissolution and precipitation. Results from this study could have practical implications for a successful CO 2 injection and enhanced oil/gas/geothermal production in low-permeability formations, potentially providing a new basis for screening of storage sites and reservoirs.

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CO2 Injection into Saline Carbonate Aquifer Formations II: Comparison of Numerical Simulations to Experiments

Cited by 52 publications

References 38 publications

CO2 injection into saline carbonate aquifer formations I: laboratory investigation

CO2 injection into saline carbonate aquifer formations I: laboratory investigation

CO2-induced dissolution of low permeability carbonates. Part II: Numerical modeling of experiments

Numerical Investigation into the Impact of CO₂-Water-Rock Interactions on CO₂ Injectivity at the Shenhua CCS Demonstration Project, China

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CO2 Injection into Saline Carbonate Aquifer Formations II: Comparison of Numerical Simulations to Experiments

Cited by 52 publications

References 38 publications

CO2 injection into saline carbonate aquifer formations I: laboratory investigation

CO2 injection into saline carbonate aquifer formations I: laboratory investigation

CO2-induced dissolution of low permeability carbonates. Part II: Numerical modeling of experiments

Numerical Investigation into the Impact of CO2-Water-Rock Interactions on CO2 Injectivity at the Shenhua CCS Demonstration Project, China

Contact Info

Product

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Numerical Investigation into the Impact of CO₂-Water-Rock Interactions on CO₂ Injectivity at the Shenhua CCS Demonstration Project, China