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Journal of Nanoparticle Research
Erschienen in: Journal of Nanoparticle Research 9/2017

01.09.2017 | Research Paper

Wettability alteration of sandstones by silica nanoparticle dispersions in light and heavy crude oil

verfasst von: Britta M. J. Huibers, Ashley R. Pales, Lingyun Bai, Chunyan Li, Linlin Mu, David Ladner, Hugh Daigle, Christophe J. G. Darnault

Erschienen in: Journal of Nanoparticle Research | Ausgabe 9/2017

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Abstract

Unlike conventional oil production methods, enhanced oil recovery (EOR) processes can recover most oil products from the reservoir. One method, known as wettability alteration, changes the hydrophilicity of the reservoir rock via decreased surface interactions with crude oils. The mitigation of these attractive forces enhances petroleum extraction and increases the accessibility of previously inaccessible rock deposits. In this work, silica nanoparticles (NPs) have been used to alter the wettability of two sandstone surfaces, Berea and Boise. Changes in wettability were assessed by measuring the contact angle and interfacial tension of different systems. The silica NPs were suspended in brine and a combined solution of brine and the Tween®20 nonionic surfactant at concentrations of 0, 0.001, and 0.01 wt% NP with both light and heavy crude oil. The stability of the different nanofluids was characterized by the size, zeta potential, and sedimentation of the particles in suspension. Unlike the NPs, the surfactant had a greater effect on the interfacial tension by influencing the liquid-liquid interactions. The introduction of the surfactant decreased the interfacial tension by 57 and 43% for light and heavy crude oil samples, respectively. Imaging and measurements of the contact angle were used to assess the surface-liquid interactions and to characterize the wettability of the different systems. The images reflect that the contact angle increased with the addition of NPs for both sandstone and oil types. The contact angle in the light crude oil sample was most affected by the addition of 0.001 wt% NP, which altered both sandstones’ wettability. Increases in contact angle approached 101.6% between 0 and 0.001 wt% NPs with light oil on the Berea sandstone. The contact angle however remained relatively unaffected by addition of higher NP concentrations, thus indicating that low NP concentrations can effectively be used for enhancing crude oil recovery. While the contact angle of the light crude oil plateaued, the heavy crude oil continued to increase with an increase in NP concentration; therefore indicating that a maximum contact angle in heavy crude oil was not yet achieved. The introduction of NPs in light and heavy crude oil samples altered both the Berea and Boise sandstone systems’ wettability, which in turn indicated the efficacy of the silica NPs and surfactants in generating a more water-wet reservoir. Consequently, silica NPs and surfactants are most promising for EOR across the range of oil types.
Vorheriger Artikel Asymmetric capacitors based on TiO2 and mesoporous MnO2 electrodes using neutral aqueous electrolyte
Nächster Artikel Development of polymethacrylate nanospheres as targeted delivery systems for catechin within the gastrointestinal tract

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Literatur
Abdallah W, Buckley JS, Carnegie A, Edwards J, Herold B, Fordham E, Graue A, Habashy T, Seleznev N, Signer C (1986) Fundamentals of wettability. Technol Innovation 38:268
Al-Anssari S, Barifcani A, Wang S, Maxim L, Iglauer S (2016) Wettability alteration of oil-wet carbonate by silica nanofluid. J Colloid Interface Sci 461:435–442CrossRef
Chengara A, Nikolov AD, Wasan DT, Trokhymchuk A, Henderson D (2004) Spreading of nanofluids driven by the structural disjoining pressure gradient. J Colloid Interface Sci 280:192–201CrossRef
Chilingar GV, Yen TF (1983) Some notes on wettability and relative permeabilities of carbonate reservoir rocks, II. Energy Sources 7:67–75CrossRef
Cieśliński JT, Krygier KA (2014) Sessile droplet contact angle of water–Al2O3, water–TiO2 and water–Cu nanofluids. Exp Thermal Fluid Sci 59:258–263CrossRef
Ehtesabi H, Ahadian MM, Taghikhani V, Ghazanfari MH (2013) Enhanced heavy oil recovery in sandstone cores using TiO2 nanofluids. Energy Fuel 28:423–430CrossRef
Ershadi M, Alaei M, Rashidi A, Ramazani A, Khosravani S (2015) Carbonate and sandstone reservoirs wettability improvement without using surfactants for Chemical Enhanced Oil Recovery (C-EOR). Fuel 153:408–415CrossRef
Ganguly S, Chakraborty S (2011) Sedimentation of nanoparticles in nanoscale colloidal suspensions. Phys Lett A 375:2394–2399CrossRef
Giraldo J, Benjumea P, Lopera S, Cortés FB, Ruiz MA (2013) Wettability alteration of sandstone cores by alumina-based nanofluids. Energy Fuel 27:3659–3665CrossRef
Godinez IG, Darnault CJ (2011) Aggregation and transport of nano-TiO2 in saturated porous media: effects of pH, surfactants and flow velocity. Water Res 45:839–851CrossRef
Godinez IG, Darnault CJ, Khodadoust AP, Bogdan D (2013) Deposition and release kinetics of nano-TiO2 in saturated porous media: effects of solution ionic strength and surfactants. Environ Pollut 174:106–113CrossRef
Gong H, Li Y, Dong M, Ma S, Liu W (2016) Effect of wettability alteration on enhanced heavy oil recovery by alkaline flooding. Colloids Surf A Physicochem Eng Asp 488:28–35CrossRef
Hendraningrat L, Torsæter O (2014) Effects of the initial rock wettability on silica-based nanofluid-enhanced oil recovery processes at reservoir temperatures. Energy Fuel 28:6228–6241CrossRef
Hendraningrat L, Torsæter O (2015) Metal oxide-based nanoparticles: revealing their potential to enhance oil recovery in different wettability systems. App Nanoscience 5:181–199CrossRef
Hu Z, Azmi SM, Raza G, Glover PW, Wen D (2016) Nanoparticle-assisted water-flooding in Berea sandstones. Energy Fuel 30:2791–2804CrossRef
Ju B, Fan T (2009) Experimental study and mathematical model of nanoparticle transport in porous media. Powder Technol 192:195–202CrossRef
Ju B, Fan T, Ma M (2006) Enhanced oil recovery by flooding with hydrophilic nanoparticles. China Particuol 4:41–46CrossRef
Karimi A, Fakhroueian Z, Bahramian A, Pour Khiabani N, Darabad JB, Azin R, Arya S (2012) Wettability alteration in carbonates using zirconium oxide nanofluids: EOR implications. Energy Fuel 26:1028–1036CrossRef
Kondiparty K, Nikolov A, Wu S, Wasan D (2011) Wetting and spreading of nanofluids on solid surfaces driven by the structural disjoining pressure: statics analysis and experiments. Langmuir 27:3324–3335CrossRef
Kondiparty K, Nikolov AD, Wasan D, Liu K (2012) Dynamic spreading of nanofluids on solids. Part I: experimental. Langmuir 28:14618–14623CrossRef
Lim S, Horiuchi H, Nikolov AD, Wasan D (2015) Nanofluids alter the surface wettability of solids. Langmuir 31:5827–5835CrossRef
Lim S, Zhang H, Wu P, Nikolov A, Wasan D (2016) The dynamic spreading of nanofluids on solid surfaces—role of the nanofilm structural disjoining pressure. J Colloid Interface Sci 470:22–30CrossRef
Liu K, Kondiparty K, Nikolov AD, Wasan D (2012) Dynamic spreading of nanofluids on solids part II: modeling. Langmuir 28:16274–16284CrossRef
Mohammed M, Babadagli T (2015) Wettability alteration: a comprehensive review of materials/methods and testing the selected ones on heavy-oil containing oil-wet systems. Adv Colloid Interf Sci 220:54–77CrossRef
Nikolov A, Kondiparty K, Wasan D (2010) Nanoparticle self-structuring in a nanofluid film spreading on a solid surface. Langmuir 26:7665–7670CrossRef
Pales AR, Kinsey EN, Li C, Mu L, Bai L, Clifford HM, Darnault CJG (2017) Rheological properties of silica nanoparticles in brine and brine-surfactant systems. J Nanofluids 6:795–803CrossRef
Rostami Ravari R, Strand S, Austad T (2011) Combined surfactant-enhanced gravity drainage (SEGD) of oil and the wettability alteration in carbonates: the effect of rock permeability and interfacial tension (IFT). Energy Fuel 25:2083–2088CrossRef
Roustaei A, Bagherzadeh H (2015) Experimental investigation of SiO2 nanoparticles on enhanced oil recovery of carbonate reservoirs. J Pet Explor Prod Technol 5:27–33CrossRef
Roustaei A, Saffarzadeh S, Mohammadi M (2013) An evaluation of modified silica nanoparticles’ efficiency in enhancing oil recovery of light and intermediate oil reservoirs. Egypt J Pet 22:427–433CrossRef
Somasundaran P, Zhang L (2006) Adsorption of surfactants on minerals for wettability control in improved oil recovery processes. J Pet Explor Prod Technol 52:198–212
Standnes DC, Austad T (2003) Wettability alteration in carbonates: interaction between cationic surfactant and carboxylates as a key factor in wettability alteration from oil-wet to water-wet conditions. Colloids Surf., A 216:243–259CrossRef
Suleimanov BA, Ismailov FS, Veliyev EF (2011) Nanofluid for enhanced oil recovery. J Pet Sci Eng 78:431–437CrossRef
Thomas S (2008) Enhanced oil recovery—an overview. Oil Gas Sci Technol 63:9–19CrossRef
Uyusur B, Darnault CJG, Snee PT, Kokën E, Jacobson AR, Wells RR (2010) Coupled effects of solution chemistry and hydrodynamics on the mobility and transport of quantum dot nanomaterials in the vadose zone. J Contam Hydrol 118:184–198CrossRef
Wasan D, Nikolov A, Kondiparty K (2011) The wetting and spreading of nanofluids on solids: Role of the structural disjoining pressure. Curr Opin Colloid Interface Sci 16:344–349
Yu H, Yoon K, Neilson B, Bagaria H, Worthen A, Lee J, Cheng V, Bielawski C, Johnston K, Bryant S (2014) Transport and retention of aqueous dispersions of superparamagnetic nanoparticles in sandstone. J Pet Sci Eng 116:115–123CrossRef
Yuan C, Pu W, Wang X, Sun L, Zhang Y, Cheng S (2015) Effects of interfacial tension, emulsification, and surfactant concentration on oil recovery in surfactant flooding process for high temperature and high salinity reservoirs. Energy Fuel 29:6165–6176CrossRef
Zargartalebi M, Barati N, Kharrat R (2014) Influences of hydrophilic and hydrophobic silica nanoparticles on anionic surfactant properties: interfacial and adsorption behaviors. J Pet Sci Eng 119:36–43CrossRef
Zhang H, Nikolov A, Wasan D (2014) Enhanced oil recovery (EOR) using nanoparticle dispersions: underlying mechanism and imbibition experiments. Energy Fuels 28:3002–3009CrossRef
Metadaten
Titel
Wettability alteration of sandstones by silica nanoparticle dispersions in light and heavy crude oil
verfasst von
Britta M. J. Huibers
Ashley R. Pales
Lingyun Bai
Chunyan Li
Linlin Mu
David Ladner
Hugh Daigle
Christophe J. G. Darnault
Publikationsdatum
01.09.2017
Verlag
Springer Netherlands
Erschienen in
Journal of Nanoparticle Research / Ausgabe 9/2017
Print ISSN: 1388-0764
Elektronische ISSN: 1572-896X
DOI
https://doi.org/10.1007/s11051-017-4011-7

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