Microscopic Scale Study of Individual Water Ion Interactions at Complex Crude Oil-Water Interface: A New SmartWater Flood Recovery Mechanism

Ayirala, Subhash C.; Saleh, Salah; Yousef, Ali

doi:10.2118/179590-ms

Cited by 6 publications

(3 citation statements)

References 32 publications

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“…As early as 2008, Saudi Aramco focused its research on how seawater can increase the production of carbonate reservoirs. Saudi Aramco's two recent technical papers show that the company has begun to consider how to improve water treatment systems to turn seawater into "smart water" and provide the latest progress in laboratory research to study how active substances in seawater affect oil production (Ayirala et al 2016). It is clear from these papers and other sources that Saudi Aramco's use of seawater as a cheap alternative to scarce freshwater can increase the amount of oil eventually recovered from the ground.…”

Section: Smart Water Floodingmentioning

confidence: 99%

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A review of development methods and EOR technologies for carbonate reservoirs

et al. 2020

Pet. Sci.

178

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Carbonate reservoirs worldwide are complex in structure, diverse in form, and highly heterogeneous. Based on these characteristics, the reservoir stimulation technologies and fluid flow characteristics of carbonate reservoirs are briefly described in this study. The development methods and EOR technologies of carbonate reservoirs are systematically summarized, the relevant mechanisms are analyzed, and the application status of oil fields is catalogued. The challenges in the development of carbonate reservoirs are discussed, and future research directions are explored. In the current development processes of carbonate reservoirs, water flooding and gas flooding remain the primary means but are often prone to channeling problems. Chemical flooding is an effective method of tertiary oil recovery, but the harsh formation conditions require high-performance chemical agents. The application of emerging technologies can enhance the oil recovery efficiency and environmental friendliness to a certain extent, which is welcome in hard-to-recover areas such as heavy oil reservoirs, but the economic cost is often high. In future research on EOR technologies, flow field control and flow channel plugging will be the potential directions of traditional development methods, and the application of nanoparticles will revolutionize the chemical EOR methods. On the basis of diversified reservoir stimulation, combined with a variety of modern data processing schemes, multichannel EOR technologies are being developed to realize the systematic, intelligent, and cost-effective development of carbonate reservoirs.

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Section: Smart Water Floodingmentioning

confidence: 99%

“…Fig.6Smart water flooding recovery mechanism using the combined effects from both fluid-fluid and rock-fluid interfaces. Adapted fromAyirala et al (2016) …”

mentioning

confidence: 99%

A review of development methods and EOR technologies for carbonate reservoirs

et al. 2020

Pet. Sci.

178

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“…Variations in the nature of confinement, such as soft (polymer and self-assembled monolayers) vs hard (zeolites and silica), and patterned (graphite and carbon nanotubes) vs random (hydrogels), lead to large changes in structure and dynamics of confined water. Changes in the organization and evolution of water aggregates and bound water have practical implications for membrane transport, − protein folding, − adhesion of biomacromolecules, − design of anti-icing surfaces, − selective organic remediation, − and oil recovery. − …”

Section: Introductionmentioning

confidence: 99%

Soft Templating of Water Aggregates Disrupts π–π Stacking in Crystalline Poly(3-hexylthiophene)

et al. 2017

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The π–π stacking robustness of the photoactive layer is key to maintaining efficiency of organic photovoltaics (OPVs). We show local disruption more than 2 Å on average in the π–π stack of crystalline poly(3-hexylthiophene) (P3HT), one of the most common materials used in OPVs, through formation of a chainlike water structure with limited growth and mostly pentameric cluster ends. In contrast, a 3D aggregated water cluster with constant growth is observed in amorphous P3HT. Dynamics of water molecules that form the largest aggregates in crystalline P3HT show the effect of limited mobility, when compared to amorphous P3HT, due to dual confinement from both alkyl side groups and thiophene backbone. We term this dual confinement soft templating and quantify its effect on nature, size, and hydrogen bond participation of water aggregates in crystalline and amorphous P3HT using all-atom molecular dynamics with in-house developed potentials that were previously shown to represent the interfacial and wetting behavior of P3HT systems in good agreement with experiments. Examination of disruption behavior presented for P3HT would allow smart molecular design of photoactive layers.

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Low-salinity (enhanced) waterflooding in carbonate reservoirs

Mahani

Thyne²

2023

Recovery Improvement

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Microscopic Scale Study of Individual Water Ion Interactions at Complex Crude Oil-Water Interface: A New SmartWater Flood Recovery Mechanism

Cited by 6 publications

References 32 publications

A review of development methods and EOR technologies for carbonate reservoirs

A review of development methods and EOR technologies for carbonate reservoirs

Soft Templating of Water Aggregates Disrupts π–π Stacking in Crystalline Poly(3-hexylthiophene)

Low-salinity (enhanced) waterflooding in carbonate reservoirs

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