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• W3096231805 abstract "Abstract To fully understand the flow mechanisms in oil reservoirs, analysis at pore-scale is required, as it is the length scale at which capillary-trapped oil is mobilized. In particular, analysis at this length scale would help in developing efficient recovery methods to achieve the best possible oil recovery. In this paper, we use a novel geomaterial microfluidics device that couples the surface chemistry and mimics a real sandstone rock to analyze Alkaline Surfactant Polymer (ASP) flooding at the pore scale. An experimental micro-scale approach was developed utilizing geomaterial micromodels for analyzing oil recovery. The geomaterial micromodel is fabricated using soft lithography and polydimethylsiloxane (PDMS) as the main material. Then, to functionalize the PDMS devices, the relevant minerals for sandstone (Quartz and Kaolinite) are added to create the geomaterial micromodel device. To study the effect of minerals presence on oil recovery during ASP flooding, oil recovery is measured using geomaterial microfluidics, as well as plain PDMS microfluidics device that has the same porous media pattern. The results show the different displacement patterns and oil recovery achieved by waterflooding and followed by ASP flooding, which is the typical practice in any enhanced oil recovery method. Results showed oil recovery of 65 % followed by 69 % for waterflood and ASP, respectively in a geomaterial device. In the plain PDMS microfluidics device, an oil recovery of 75 % followed by 80 % for waterflood and ASP, respectively. The geomaterial microfluidics chip provided a more realistic oil recovery values compared to the plain PDMS chip. Therefore, using this novel geomaterial microfluidics fabrication method creates an ideal visualization platform to study the pore scale of any given flood, as it captures the surface chemistry, roughness, and pore networks present in actual rocks. This would ultimately help develop and optimize oil recovery mechanisms." @default.
• W3096231805 created "2020-11-09" @default.
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• W3096231805 date "2020-11-09" @default.
• W3096231805 modified "2023-10-14" @default.
• W3096231805 title "Geomaterial Microfluidics for the Visualization of Alkaline Surfactant Polymer Flooding" @default.
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• W3096231805 doi "https://doi.org/10.2118/203403-ms" @default.
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