SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W4328125304> ?p ?o ?g. }

Showing items 1 to 100 of ±144 with 100 items per page.

W4328125304 endingPage "5129" @default.
W4328125304 startingPage "5114" @default.
W4328125304 abstract "The enhancement in surfactant performance at downhole conditions in the presence of nanomaterials has fascinated researchers’ interest regarding the applications of nanoparticle-surfactant (NPS) fluids as novel enhanced oil recovery (EOR) techniques. However, the governing EOR mechanisms of hydrocarbon recovery using NPS solutions are not yet explicit. Pore-scale visualization experiments clarify the dominant EOR mechanisms of fluid displacement and trapped/residual oil mobilization using NPS solutions. In this study, the influence of multiwalled carbon nanotubes (MWCNTs), silicon dioxide (SiO2), and aluminum oxide (Al2O3) nanoparticles on the EOR properties of a conventional surfactant (sodium dodecyl benzene sulfonate, SDBS) was investigated via experimental and computational fluid dynamics (CFD) simulation approaches. Oil recovery was reduced with increased temperatures and micromodel heterogeneity. Adding nanoparticles to SDBS solutions decreases the fingering and channeling effect and increases the recovery factor. The simulation prediction results agreed with the experimental results, which demonstrated that the lowest amount of oil (37.84%) was retained with the micromodel after MWCNT-SDBS flooding. The oil within the micromodel after Al2O3-SDBS and SiO2-SDBS flooding was 58.48 and 43.42%, respectively. At 80 °C, the breakthrough times for MWCNT-SDBS, Al2O3-SDBS, and SiO2-SDBS displacing fluids were predicted as 32.4, 29.3, and 21 h, respectively, whereas the SDBS flooding and water injections at similar situations were at 12.2 and 6.9 h, respectively. The higher oil recovery and breakthrough time with MWCNTs could be attributed to their cylindrical shape, promoting the MWCNT-SDBS orientation at the liquid–liquid and solid–liquid interfaces to reduce the oil–water interfacial tension and contact angles significantly. The study highlights the prevailing EOR mechanisms of NPS." @default.
W4328125304 created "2023-03-22" @default.
W4328125304 creator A5008820196 @default.
W4328125304 creator A5041261982 @default.
W4328125304 creator A5055904438 @default.
W4328125304 creator A5059738250 @default.
W4328125304 creator A5067974945 @default.
W4328125304 creator A5086234953 @default.
W4328125304 date "2023-03-21" @default.
W4328125304 modified "2023-10-16" @default.
W4328125304 title "Experimental and Computational Fluid Dynamics Investigation of Mechanisms of Enhanced Oil Recovery via Nanoparticle-Surfactant Solutions" @default.
W4328125304 cites W2007012697 @default.
W4328125304 cites W2039056822 @default.
W4328125304 cites W2084151407 @default.
W4328125304 cites W2147195036 @default.
W4328125304 cites W2298034009 @default.
W4328125304 cites W2329473117 @default.
W4328125304 cites W2413162601 @default.
W4328125304 cites W2466619345 @default.
W4328125304 cites W2564313907 @default.
W4328125304 cites W2604165303 @default.
W4328125304 cites W2612589426 @default.
W4328125304 cites W2755634098 @default.
W4328125304 cites W2761572403 @default.
W4328125304 cites W2791936115 @default.
W4328125304 cites W2793342245 @default.
W4328125304 cites W2897827306 @default.
W4328125304 cites W2898290864 @default.
W4328125304 cites W2899158092 @default.
W4328125304 cites W2904430750 @default.
W4328125304 cites W2910871692 @default.
W4328125304 cites W2928275554 @default.
W4328125304 cites W2943556317 @default.
W4328125304 cites W2944259572 @default.
W4328125304 cites W2944635118 @default.
W4328125304 cites W2956445337 @default.
W4328125304 cites W2974378548 @default.
W4328125304 cites W2976843802 @default.
W4328125304 cites W2980497859 @default.
W4328125304 cites W2990069073 @default.
W4328125304 cites W2992897417 @default.
W4328125304 cites W3018277450 @default.
W4328125304 cites W3025035051 @default.
W4328125304 cites W3033805269 @default.
W4328125304 cites W3040487794 @default.
W4328125304 cites W3046671056 @default.
W4328125304 cites W3082689043 @default.
W4328125304 cites W3082819818 @default.
W4328125304 cites W3100943528 @default.
W4328125304 cites W3110923755 @default.
W4328125304 cites W3124884429 @default.
W4328125304 cites W3155693268 @default.
W4328125304 cites W3156317463 @default.
W4328125304 cites W3172004638 @default.
W4328125304 cites W3173142066 @default.
W4328125304 cites W3176386775 @default.
W4328125304 cites W3181333316 @default.
W4328125304 cites W3191386297 @default.
W4328125304 cites W3195440220 @default.
W4328125304 cites W3210063047 @default.
W4328125304 cites W4200096518 @default.
W4328125304 cites W4200392147 @default.
W4328125304 cites W4205462480 @default.
W4328125304 cites W4206471866 @default.
W4328125304 cites W4207034687 @default.
W4328125304 cites W4210581813 @default.
W4328125304 cites W4214823495 @default.
W4328125304 cites W4224213683 @default.
W4328125304 cites W4224282749 @default.
W4328125304 cites W4281770783 @default.
W4328125304 cites W4283259376 @default.
W4328125304 cites W4284677039 @default.
W4328125304 cites W4308454137 @default.
W4328125304 cites W4310117509 @default.
W4328125304 cites W4310135752 @default.
W4328125304 doi "https://doi.org/10.1021/acs.energyfuels.3c00136" @default.
W4328125304 hasPublicationYear "2023" @default.
W4328125304 type Work @default.
W4328125304 citedByCount "6" @default.
W4328125304 countsByYear W43281253042023 @default.
W4328125304 crossrefType "journal-article" @default.
W4328125304 hasAuthorship W4328125304A5008820196 @default.
W4328125304 hasAuthorship W4328125304A5041261982 @default.
W4328125304 hasAuthorship W4328125304A5055904438 @default.
W4328125304 hasAuthorship W4328125304A5059738250 @default.
W4328125304 hasAuthorship W4328125304A5067974945 @default.
W4328125304 hasAuthorship W4328125304A5086234953 @default.
W4328125304 hasBestOaLocation W43281253041 @default.
W4328125304 hasConcept C105569014 @default.
W4328125304 hasConcept C127413603 @default.
W4328125304 hasConcept C155672457 @default.
W4328125304 hasConcept C159985019 @default.
W4328125304 hasConcept C171250308 @default.
W4328125304 hasConcept C178790620 @default.
W4328125304 hasConcept C185592680 @default.
W4328125304 hasConcept C192562407 @default.
W4328125304 hasConcept C21946209 @default.
W4328125304 hasConcept C2776124570 @default.