Carbonated Water Injection in Oil-Wet Carbonate Rock Samples: A Pore-Scale Experimental Investigation of the Effect of Brine Composition

Akindipe, Dayo; Saraji, Soheil; Piri, Mohammad

doi:10.1021/acs.energyfuels.2c00326

Cited by 7 publications

(8 citation statements)

References 104 publications

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Section: Enhanced Carbonated Water Injectionmentioning

confidence: 99%

“…Akindipe et al calculated and compared the interfacial curvature of high salinity water injection and CLSW injection, utilizing oil-wet carbonates and incorporating core analysis and micro-CT imaging. They discovered that changes in wettability resulted in reduced water–oil capillary pressure at the interface, which subsequently increased the pore-scale displacement efficiency of CW, thus enhancing oil recovery (Figure ).…”

Section: Enhanced Carbonated Water Injectionmentioning

confidence: 99%

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Enhanced Oil Recovery and CO₂ Storage by Enhanced Carbonated Water Injection: A Mini-Review

Yu,

Tang,

Han

et al. 2024

Energy Fuels

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Carbonated water (CW) injection refers to a development method that involves dissolving CO 2 in water under specific temperatures and pressures, followed by its injection into reservoirs for oil recovery. This technique can simultaneously enhance oil recovery and facilitate CO 2 storage, although its effectiveness requires further improvement. To address this, an advanced approach known as enhanced carbonated water (ECW) injection has been proposed. This approach involves the addition of other fluids to CW, including polymers, nanofluids, surfactants, and low salinity water, to serve as displacement media during oil recovery. It aims to leverage the advantages of various technologies to further enhance oil recovery and CO 2 storage effectiveness. Although ECW injection exhibits significant application potential, a systematic summary of its research progress is still lacking. Therefore, this article aims to fill this gap by systematically summarizing the latest research on ECW injection, detailing the mechanisms and performance in enhancing oil recovery and achieving CO 2 storage. The method effectively exploits the synergistic benefits of CW and various displacement agents. Its primary mechanisms include increasing the dissolution of CO 2 and prolonging the duration of CO 2 retention in the water, reducing interfacial tension, and altering wettability. Both laboratory experiments and numerical simulations have demonstrated that ECW injection can significantly boost recovery and offer promising results in CO 2 storage, presenting it as a highly prospective method for reservoir development. In addition, this paper discusses the main challenges facing this technology and explores potential future research directions, aiming to provide robust guidance for the research and application of this technology.

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Section: Enhanced Carbonated Water Injectionmentioning

confidence: 99%

Section: Enhanced Carbonated Water Injectionmentioning

confidence: 99%

Enhanced Oil Recovery and CO₂ Storage by Enhanced Carbonated Water Injection: A Mini-Review

Yu,

Tang,

Han

et al. 2024

Energy Fuels

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“…Injecting low-salinity water (LSW) disturbs the chemical equilibrium at the mineral/formation water interface, leading to wettability reversal by adsorption/desorption of polar molecules. Meanwhile, dissolving carbon dioxide into the brine solution has proven to improve oil mobility in porous media by changing the relative permeabilities, wettability, and bulk oil viscosity. − …”

Section: Introductionmentioning

confidence: 99%

Salinity-Driven Structural and Viscosity Modulation of Confined Polar Oil Phases by Carbonated Brine Films: Novel Insights from Molecular Dynamics

Dastjerdi,

Kharrat,

Niasar

et al. 2024

J. Phys. Chem. B

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The structural and dynamic properties of fluids under confinement in a porous medium differ from their bulk properties. This study delves into the surface structuring and hydrodynamic characteristics of oil/thin film carbonated brine twophase within a calcite channel upon salinity variation. To this end, both equilibrium and non-equilibrium molecular dynamics simulations are utilized to unveil the effect of the carboxylic acid component (benzoic acid) in a simple model oil (decane) confined between two thin films of carbonated brine on the oil−brine− calcite characteristics. The salinity effect was scrutinized under four saline carbonated waters, deionized carbonated water (DCW), carbonated low-salinity brine (CLSB, 30,000 ppm), carbonated seawater (CSW, 60,000 ppm), and carbonated high-salinity brine (CHSB, 180,000 ppm). An electrical double layer (EDL) is observed at varying salinities, comprising a Stern-like positive layer (formed by Na + ions) followed by a negative one (formed by Cl − ions primarily residing on top of the adsorbed sodium cations). By lowering the salinity, the Na + ions cover the interface regions (brine−calcite and brine−oil), depleting within the brine bulk region. The lowest positive surface charge on the rock surface was found in salinity corresponding to seawater. Two distinct Na + peaks at the oleic phase interface have been observed in the carbonated high-salinity brine system, enhancing the adsorption of polar molecules at the thin brine film interfaces. There is a pronounced EDL formation at the oleic phase interface in the case of CSW, resulting in a strong interface region containing ions and functional fractions. Likewise, the oil region confined by CSW exhibited the lowest apparent viscosity, attributed to the optimized salinity distribution and inclination of benzoic acid fractions uniformly at the brine− oil interface, acting as a slippery surface. Moreover, the results reveal that the presence of polar fractions could increase the oil phase's apparent viscosity, and introducing ions to this system reduces the polar molecules' destructive effect on the apparent viscosity of the oil region. Therefore, the fluidity of confined systems is modulated by both composition of the brine and oil phases.

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“…The injection of carbonated brine however promoted this undesirable effect . Reaction-induced porosity and permeability evolution are also essential in optimizing CWI in oil reservoirs and saline aquifers and have garnered substantial attention in recent decades. − …”

Section: Introductionmentioning

confidence: 99%

Carbonated Water Injection for Enhanced Oil Recovery and CO₂ Geosequestration in Different CO₂ Repositories: A Review of Physicochemical Processes and Recent Advances

Turkson,

Md Yusof,

Fjelde

et al. 2024

Energy Fuels

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With increasing global energy demand and the urgency to reduce carbon emissions, carbonated water injection has been proposed to tackle these pressing concerns. Carbonated water injection (CWI) in oil formations enhances oil production to support the global energy mix and tackle the issues of energy security, energy equity, and environmental sustainability. However, CWI in oil reservoirs and saline aquifers initiates multiple chemical reactions that promote carbon mineralization, cause formation damage problems, sea-bed subsidence, and reservoir compaction, increase the injection pressure requirement, and consequently affect the practicality of CWI for enhanced oil recovery (EOR) and CO 2 storage. We therefore extensively reviewed the performance of CWI for EOR and CO 2 storage and the implications of these interactions on EOR and CO 2 storage. The analysis covered recent advancements in CWI, including its synergy with various EOR techniques where it was identified that combining CWI with surfactants, polymers, mutual solvents, and nanomaterials significantly improved oil recovery in tight formations (37− 65%) compared to standalone CWI (35−36%), but the CO 2 storage potential of the hybrid technique remains unexplored. Additionally, the complex geochemical interactions that occur during CWI, the influencing variables of these interactions, and their consequence on EOR and CO 2 storage were discussed. The rigorous analysis revealed that the existing literature lacks consensus on the effects of CWI on pore structure. Geochemical interactions caused a −12% to +95% porosity change and a −96% to +417% alteration in permeability. Primarily, economic challenges including CO 2 capture and transportation costs, carbonated water preparation, etc., and corrosion concerns hinder the large-scale implementation of CWI. Notwithstanding, the findings from the life cycle assessment of CWI suggested the economic viability of CWI and highlighted the importance of adopting the innovative CWI technique to achieve dual objectives of maximizing oil recovery and minimizing environmental footprints in the oil and gas industry. Multiple areas that require further investigation such as investigating the influence of condensable and incondensable contaminants on well integrity and safe CO 2 storage among others were presented.

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Carbonated Water Injection in Oil-Wet Carbonate Rock Samples: A Pore-Scale Experimental Investigation of the Effect of Brine Composition

Cited by 7 publications

References 104 publications

Enhanced Oil Recovery and CO₂ Storage by Enhanced Carbonated Water Injection: A Mini-Review

Enhanced Oil Recovery and CO₂ Storage by Enhanced Carbonated Water Injection: A Mini-Review

Salinity-Driven Structural and Viscosity Modulation of Confined Polar Oil Phases by Carbonated Brine Films: Novel Insights from Molecular Dynamics

Carbonated Water Injection for Enhanced Oil Recovery and CO₂ Geosequestration in Different CO₂ Repositories: A Review of Physicochemical Processes and Recent Advances

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Carbonated Water Injection in Oil-Wet Carbonate Rock Samples: A Pore-Scale Experimental Investigation of the Effect of Brine Composition

Cited by 7 publications

References 104 publications

Enhanced Oil Recovery and CO2 Storage by Enhanced Carbonated Water Injection: A Mini-Review

Enhanced Oil Recovery and CO2 Storage by Enhanced Carbonated Water Injection: A Mini-Review

Salinity-Driven Structural and Viscosity Modulation of Confined Polar Oil Phases by Carbonated Brine Films: Novel Insights from Molecular Dynamics

Carbonated Water Injection for Enhanced Oil Recovery and CO2 Geosequestration in Different CO2 Repositories: A Review of Physicochemical Processes and Recent Advances

Contact Info

Product

Resources

About

Enhanced Oil Recovery and CO₂ Storage by Enhanced Carbonated Water Injection: A Mini-Review

Enhanced Oil Recovery and CO₂ Storage by Enhanced Carbonated Water Injection: A Mini-Review

Carbonated Water Injection for Enhanced Oil Recovery and CO₂ Geosequestration in Different CO₂ Repositories: A Review of Physicochemical Processes and Recent Advances