NanoSurfactant for EOR in Carbonate Reservoirs

Abdel‐Fattah, Amr I.; Mashat, Afnan; Alaskar, Mohammad; Gizzatov, Ayrat

doi:10.2118/188046-ms

Cited by 14 publications

(9 citation statements)

References 5 publications

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“…We first investigated the colloidal stability of Pure Sulf and Sulf+Coca formulations in deionized water and high salinity water (see the Experimental Section in Materials and Methods for the notations of the formulations). As has been identified, Pure Sulf solutions were unstable in high salinity water and precipitated immediately after preparation. − Figure shows the DLS measurements of Pure Sulf oil-swollen micelles in deionized water, Sulf+Coca oil-swollen micelles in deionized water, and Sulf+Coca oil-swollen micelles in high salinity water. As shown, Pure Sulf solution has the highest polydispersity with their measured hydrodynamic diameters ranged from 10 to 400 nm.…”

Section: Resultsmentioning

confidence: 88%

“…Two surfactant formulations were prepared: (i) “Pure Sulf” oil-swollen micelles with 0.1 wt % chemicals (95 wt % Sulf and 5 wt % Deca within the chemicals) and (ii) “Sulf+Coca” oil-swollen micelles with 0.2 wt % chemicals (43.2 wt % Sulf, 54.5 wt % Coca, and 2.3 wt % Deca within the chemicals). The particular compositions were chosen based on prior studies optimized for enhanced oil recovery operations. − Both formulations were prepared in deionized water or high salinity water for consecutive characterization experiments. Note for the formulations in high salinity water surfactants were first mixed in deionized water at higher concentration and then the high salinity water was added to reach the desired concentrations.…”

Section: Methodsmentioning

confidence: 99%

“…Alkylbenzene sulfonates are one of the most important synthetic surfactants considering their wide applicability, cost-effectiveness, and overall consumption levels, which accounts for roughly 75% of synthetic detergents and 25% of the total surfactant consumption in the major industrialized countries . Nevertheless, pure alkylbenzene sulfonates have low salt tolerance and may precipitate immediately in high salinity water, which limited their applications in many scenarios such as enhanced oil recovery in high salinity oil reservoirs. , Recently, new experiment results have suggested that adding zwitterionic cocamidopropyl hydroxysultaine cosurfactants and mineral oils (decane) may dramatically increase the high salinity tolerance of the alkylbenzene sulfonates. − In this work, we try to provide mechanistic understanding for the enhanced high salinity colloidal stability of these surfactant mixtures using dynamic light scattering (DLS) and nuclear magnetic resonance (NMR) experiments, and molecular dynamics (MD) simulations. We believe the molecular insights put forward in this study not only inform better designs of the high salt tolerance surfactant formulations but also further our understanding for the rich molecular assembly characteristics of surfactant mixtures in complex fluids.…”

Section: Introductionmentioning

confidence: 99%

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Molecular Assembly of Surfactant Mixtures in Oil-Swollen Micelles: Implications for High Salinity Colloidal Stability

2019

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Alkylbenzene sulfonates are one of the most important synthetic surfactant families, considering their wide applicability, cost-effectiveness, and overall consumption levels. Nevertheless, their low salt tolerance (especially divalent ion contents) prevented their wider applications such as enhanced oil recovery in high salinity reservoirs. Here, using experiments and atomistic molecular dynamics simulations, we demonstrated that the high salinity colloidal stability of alkylbenzene sulfonates can be dramatically increased by mixing with zwitterionic cosurfactants in oil-swollen micelles. By mixing with cosurfactants we had two important observations. (1) The polydispersity of surfactant mixture oil-swollen micelles were largely decreased due to the less rigid oil/water interfaces with mixed surfactants, which formed fewer but larger uniform micelles. (2) Strong dehydration of sulfonates due to the shielding from protruding more extended zwitterionic cosurfactants at the oil/water interfaces. Both observed molecular assembly characteristics triggered by the cosurfactants effectively reduced the total exposures of sulfonates to water phase that may form divalent ion bridging and large aggregates, and thus increased their high salinity colloidal stability. Lastly, it was observed that the dehydration of sulfonates was the highest at flat oil/water interfaces (very large oil-swollen micelles), which justified that adding trace amount of mineral oils may boost the high salinity colloidal stability even further.

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Section: Resultsmentioning

confidence: 88%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Molecular Assembly of Surfactant Mixtures in Oil-Swollen Micelles: Implications for High Salinity Colloidal Stability

2019

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“…Regardless of the adopted classification and division of secondary methods to support oil production, each case should be considered individually. Many examples can be found in the literature from laboratory tests through to computer simulations and test pilots, ending with the analysis of completed projects in specific fields [13][14][15][16][17][18][19]. The full cycle of preparation and implementation of an EOR project, from laboratory research to its implementation in an oil field and confirming its effectiveness, is typically complex, long-lasting and, thus, expensive.…”

Section: Introductionmentioning

confidence: 99%

“…The entry of engineering into the nanoscale has opened up many new areas previously inaccessible without the use of nanotechnology, as well as the possibility of modifying existing technological solutions (e.g., EOR processes). Examples of research projects or nanotechnology-based solutions have been cited repeatedly [8,14,16,[20][21][22][23][24][25][26]. These studies have shown that during EOR processes, rock wettability is particularly important in carbonate rocks.…”

Section: Introductionmentioning

confidence: 99%

Laboratory Testing of Novel Polyfraction Nanoemulsion for EOR Processes in Carbonate Formations

et al. 2020

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Nanoemulsions and polymers are widely used for increasing the efficiency of enhanced oil recovery (EOR) processes. The application of both these additives enables the synergistic use of several physical phenomena that are crucial to the process. One of the methods used for assessing these processes is laboratory core flooding tests using natural cores. In various experiments, carbonate rocks are subjected to oil displacement under high pressure and temperature. Polymer solutions and a newly developed polyfraction nanoemulsion are tested. The test results confirm the usefulness of these products for EOR processes and demonstrate their stability under high pressure, high temperature, and in the presence of H2S. Under these conditions the polymers maintain high efficiency in displacing crude oil from carbonate rocks, while the tested nanoemulsion improves the wettability of carbonate rocks and reduces interfacial tension, factors which increase the efficiency of oil displacement.The best result in the laboratory EOR simulation was obtained for polymer and nanoemulsion concentrations in dilute reservoir water of 0.05% and 1%, respectively. In this case, the measured oil recovery was 37.5% higher than that obtained when using water without additives.

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In Situ Wettability, Capillary Pressure, and Matrix–Fracture Interactions in Fractured Oil-Wet Carbonate: A Microscale Investigation

et al. 2022

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Naturally fractured oil-wet carbonate reservoirs host a considerable fraction of oil reserves worldwide. However, the recovery factor in these reservoirs is typically low due to the inherent oil-wet characteristics of the carbonate rock and the limited interactions usually established between the fracture and matrix domains during enhanced oil recovery processes. This study was conceived to develop an improved fundamental understanding of the pore-scale displacement mechanisms responsible for oil recovery from naturally fractured oil-wet carbonates during secondary waterflooding and tertiary surfactant injection. To achieve this objective, a state-of-the-art multiphase core-flooding system integrated with a high-resolution micro-CT imaging platform was utilized to perform a series of flow experiments on a miniature fractured oil-wet carbonate sample at elevated pressure and temperature conditions. The fluid occupancy maps generated during the flow experiments were used to characterize the in situ wettability and capillary pressure, and track fracture displacement events, fracture–matrix interactions, and oil mobilization patterns at the pore scale. The results revealed that the surfactant solution reversed the wettability of both rough fracture walls and pore surfaces from an initially oil-wet state to a neutral-wet condition. This was accompanied by an order-of-magnitude reduction in the oil–water interfacial tension (IFT). The synergistic effects of wettability reversal and IFT reduction induced by surfactant injection were pivotal to decreasing the threshold pressure required for additional oil displacement from the rock matrix adjacent to the fracture. Additionally, notable evidence of fracture storage and displacement events at the pore scale was obtained in the form of wetting oil pockets and bridging events. Fracture oil pockets and bridges formed on the rough fracture walls and narrow aperture regions may enhance fracture–matrix interactions during base waterflooding by restricting brine flow through the higher-conductivity fracture. The collapse of such fracture oil storage features during the succeeding surfactant injection contributed considerably to the ultimate oil recovery from the combined media.

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NanoSurfactant for EOR in Carbonate Reservoirs

Cited by 14 publications

References 5 publications

Molecular Assembly of Surfactant Mixtures in Oil-Swollen Micelles: Implications for High Salinity Colloidal Stability

Molecular Assembly of Surfactant Mixtures in Oil-Swollen Micelles: Implications for High Salinity Colloidal Stability

Laboratory Testing of Novel Polyfraction Nanoemulsion for EOR Processes in Carbonate Formations

In Situ Wettability, Capillary Pressure, and Matrix–Fracture Interactions in Fractured Oil-Wet Carbonate: A Microscale Investigation

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