FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W1988210462> ?p ?o ?g. }

• W1988210462 endingPage "233" @default.
• W1988210462 startingPage "223" @default.
• W1988210462 abstract "In spite of the available literature on the evaluation of the drainage under the high- and low-interfacial tension (IFT) flow through porous media, distribution and the detailed topology and structure of the displacing non-wetting and the trapped wetting phases at the pore level, and some of the pore-scale phenomena have not been understood in a comprehensive manner. The aim of this study is to provide insight into the above-mentioned issues in a preferentially oil-wet porous medium partially filled with the heavy oil and connate water, which is flooded with the brine (simulating secondary drainage or high-IFT waterflooding) and with the surfactant solution (simulating tertiary drainage or low-IFT surfactant-enhanced waterflooding). This paper consists of two parts. The first part provides a detailed, comprehensive literature survey of the recent advances in the experimental study and modeling of the drainage process in porous media. In the second part, the authors present their experimental observations of the pore-level events and the displacement front configurations of drainage under the high- and low-IFT flow conditions in a one-quarter five-spot, etched glass micromodel. First, distribution, configuration, and topology of the trapped air in primary drainage (i.e., air displacement by brine or connate water) are depicted. Second, the detailed pore-scale topology, structure, distribution, and configuration of the displaced and displacing phases in primary imbibition (i.e., desaturation of the continuous non-wetting phase, or wetting process, which occurs during the displacement of brine in a preferentially oil-wet porous medium by heavy oil), secondary drainage (i.e., desaturation of the continuous wetting phase under the high-IFT flow condition, which occurs during the high-IFT waterflooding in a preferentially oil-wet porous medium), and tertiary drainage (i.e., mobilization of the discontinuous trapped wetting phase under the low-IFT flow condition, which occurs during the low-IFT surfactant-enhanced waterflooding in a preferentially oil-wet porous medium), are elucidated in detail. Third, the major pore-scale displacement phenomena in tertiary drainage under the low-IFT flow conditions are explained. Furthermore, the advance of the displacement front and the flow pattern configuration in the secondary and tertiary drainage are analyzed. Finally, the displacing non-wetting phase blob size distribution in the tertiary drainage is presented together with the values of the desaturated fraction of different phases at different stages of the displacement." @default.
• W1988210462 created "2016-06-24" @default.
• W1988210462 creator A5031918438 @default.
• W1988210462 creator A5047171612 @default.
• W1988210462 creator A5070883994 @default.
• W1988210462 date "2010-12-01" @default.
• W1988210462 modified "2023-09-24" @default.
• W1988210462 title "Pore-scale events in drainage process through porous media under high- and low-interfacial tension flow conditions" @default.
• W1988210462 cites W1541156702 @default.
• W1988210462 cites W1608087628 @default.
• W1988210462 cites W1967893242 @default.
• W1988210462 cites W1968841838 @default.
• W1988210462 cites W1969212530 @default.
• W1988210462 cites W1972575386 @default.
• W1988210462 cites W1973643900 @default.
• W1988210462 cites W1974732033 @default.
• W1988210462 cites W1978183608 @default.
• W1988210462 cites W1980118450 @default.
• W1988210462 cites W1982379865 @default.
• W1988210462 cites W1983040840 @default.
• W1988210462 cites W1985312933 @default.
• W1988210462 cites W1986587563 @default.
• W1988210462 cites W1992734096 @default.
• W1988210462 cites W1992951969 @default.
• W1988210462 cites W1998068803 @default.
• W1988210462 cites W2000264035 @default.
• W1988210462 cites W2002037341 @default.
• W1988210462 cites W2004736443 @default.
• W1988210462 cites W2005280512 @default.
• W1988210462 cites W2008915024 @default.
• W1988210462 cites W2008999549 @default.
• W1988210462 cites W2009337670 @default.
• W1988210462 cites W2012509006 @default.
• W1988210462 cites W2018120339 @default.
• W1988210462 cites W2020723778 @default.
• W1988210462 cites W2023028181 @default.
• W1988210462 cites W2025178267 @default.
• W1988210462 cites W2027719035 @default.
• W1988210462 cites W2030533076 @default.
• W1988210462 cites W2033656431 @default.
• W1988210462 cites W2034068258 @default.
• W1988210462 cites W2036708634 @default.
• W1988210462 cites W2041103534 @default.
• W1988210462 cites W2042435650 @default.
• W1988210462 cites W2042899385 @default.
• W1988210462 cites W2043558449 @default.
• W1988210462 cites W2048722040 @default.
• W1988210462 cites W2051125355 @default.
• W1988210462 cites W2051219662 @default.
• W1988210462 cites W2051333204 @default.
• W1988210462 cites W2055734556 @default.
• W1988210462 cites W2059818614 @default.
• W1988210462 cites W2065343286 @default.
• W1988210462 cites W2072857276 @default.
• W1988210462 cites W2075360234 @default.
• W1988210462 cites W2078097581 @default.
• W1988210462 cites W2079917635 @default.
• W1988210462 cites W2080692653 @default.
• W1988210462 cites W2081047757 @default.
• W1988210462 cites W2083872435 @default.
• W1988210462 cites W2085173122 @default.
• W1988210462 cites W2091179564 @default.
• W1988210462 cites W2092411808 @default.
• W1988210462 cites W2093604161 @default.
• W1988210462 cites W2094737014 @default.
• W1988210462 cites W2099456380 @default.
• W1988210462 cites W2107209710 @default.
• W1988210462 cites W2145550450 @default.
• W1988210462 cites W2484388735 @default.
• W1988210462 cites W2075715179 @default.
• W1988210462 doi "https://doi.org/10.1016/j.petrol.2010.11.006" @default.
• W1988210462 hasPublicationYear "2010" @default.
• W1988210462 type Work @default.
• W1988210462 sameAs 1988210462 @default.
• W1988210462 citedByCount "14" @default.
• W1988210462 countsByYear W19882104622012 @default.
• W1988210462 countsByYear W19882104622013 @default.
• W1988210462 countsByYear W19882104622014 @default.
• W1988210462 countsByYear W19882104622015 @default.
• W1988210462 countsByYear W19882104622017 @default.
• W1988210462 countsByYear W19882104622018 @default.
• W1988210462 countsByYear W19882104622020 @default.
• W1988210462 countsByYear W19882104622021 @default.
• W1988210462 countsByYear W19882104622022 @default.
• W1988210462 crossrefType "journal-article" @default.
• W1988210462 hasAuthorship W1988210462A5031918438 @default.
• W1988210462 hasAuthorship W1988210462A5047171612 @default.
• W1988210462 hasAuthorship W1988210462A5070883994 @default.
• W1988210462 hasConcept C100701293 @default.
• W1988210462 hasConcept C105569014 @default.
• W1988210462 hasConcept C107551265 @default.
• W1988210462 hasConcept C121332964 @default.
• W1988210462 hasConcept C127313418 @default.
• W1988210462 hasConcept C134514944 @default.
• W1988210462 hasConcept C15744967 @default.
• W1988210462 hasConcept C159985019 @default.
• W1988210462 hasConcept C178790620 @default.
• W1988210462 hasConcept C185592680 @default.

• next