Pore-level Ostwald ripening of CO2 foams at reservoir pressure

Benali, Benyamine; Sæle, Aleksandra; Liu, Na; Fernø, Martin A.; Alcorn, Zachary Paul

doi:10.1007/s11242-023-02017-0

Transp Porous Med

2023

DOI: 10.1007/s11242-023-02017-0

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Pore-level Ostwald ripening of CO2 foams at reservoir pressure

Benyamine Benali,

Aleksandra Sæle,

Na Liu

et al.

Abstract: The success of foam to reduce CO2 mobility in CO2 enhanced oil recovery and CO2 storage operations depends on foam stability in the reservoir. Foams are thermodynamically unstable, and factors such as surfactant adsorption, the presence of oil, and harsh reservoir conditions can cause the foam to destabilize. Pore-level foam coarsening and anti-coarsening mechanisms are not, however, fully understood and characterized at reservoir pressure. Using lab-on-a-chip technology, we probe dense (liquid) phase CO2 foam… Show more

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2024

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Cited by 2 publications

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A Pore-Level Study of Dense-Phase CO2 Foam Stability in the Presence of Oil

Benali,

Fernø,

Halsøy

et al. 2024

Transp Porous Med

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The ability of foam to reduce CO2 mobility in CO2 sequestration and CO2 enhanced oil recovery processes relies on maintaining foam stability in the reservoir. Foams can destabilize in the presence of oil due to mechanisms impacting individual lamellae. Few attempts have been made to measure the stability of CO2 foams in the presence of oil in a realistic pore network at reservoir pressure. Utilizing lab-on-a-chip technology, the pore-level stability of dense-phase CO2 foam in the presence of a miscible and an immiscible oil was investigated. A secondary objective was to determine the impact of increasing surfactant concentration and nanoparticles on foam stability.In the absence of oil, all surfactant-based foaming solutions generated fine-textured and strong foam that was less stable both when increasing surfactant concentrations and when adding nanoparticles. Ostwald ripening was the primary destabilization mechanism both in the absence of oil and in the presence of immiscible oil. Moreover, foam was less stable in the presence of miscible oil, compared to immiscible oil, where the primary destabilization mechanism was lamellae rupture. Overall, direct pore-scale observations of dense-phase CO2 foam in realistic pore network revealed foam destabilization mechanisms at high-pressure conditions.

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A Pore-Level Study of Dense-Phase CO2 Foam Stability in the Presence of Oil

Benali,

Fernø,

Halsøy

et al. 2024

Transp Porous Med

View full text Add to dashboard Cite

show abstract

Impact of gas type on microfluidic drainage experiments and pore network modeling relevant for underground hydrogen storage

Lysyy,

Liu,

Landa-Marbán

et al. 2024

Journal of Energy Storage

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Pore-level Ostwald ripening of CO2 foams at reservoir pressure

Cited by 2 publications

References 57 publications

A Pore-Level Study of Dense-Phase CO2 Foam Stability in the Presence of Oil

A Pore-Level Study of Dense-Phase CO2 Foam Stability in the Presence of Oil

Impact of gas type on microfluidic drainage experiments and pore network modeling relevant for underground hydrogen storage

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