Page 74 - 《精细化工》2022年第8期

P. 74

·1574· 精细化工 FINE CHEMICALS 第 39 卷

[37] LI Y (李原), DI Q F (狄勤丰), HUA S (华帅), et al. Research experiments[J]. Energy & Fuels, 2014, 28(5): 3002-3009.
progress of reservoirs wettability alteration by using nanofluids for [48] WU W P (吴伟鹏), HOU J R (侯吉瑞), QU M (屈鸣), et al. Microscopic
enhancing oil recovery[J]. Chemical Industry and Engineering Progress flooding mechanism experiment visualization of 2-D smart black
(化工进展), 2019, 38(8): 3612-3620. nano-card[J]. Oilfield Chemistry (油田化学), 2020, 37(1): 133-137.
[38] ALI J A, KOLO K, MANSHAD A K, et al. Recent advances in [49] YAO Y, WEI M, KANG W. A review of wettability alteration using
application of nanotechnology in chemical enhanced oil recovery: surfactants in carbonate reservoirs[J]. Advances in Colloid and
Effects of nanoparticles on wettability alteration, interfacial tension Interface Science, 2021, 294: 102477.
reduction, and flooding[J]. Egyptian Journal of Petroleum, 2018, [50] LIU R, DU D J, PU W F, et al. Enhanced oil recovery potential of
27(4): 1371-1383. alkyl alcohol polyoxyethylene ether sulfonate surfactants in
[39] AHMADI M A, SHADIZADEH S R. Nano-surfactant flooding in high-temperature and high-salinity reservoirs[J]. Energy & Fuels,
carbonate reservoirs: A mechanistic study[J]. The European Physical 2018, 32(12): 12128-12140.
Journal Plus, 2017, 132(6): 1-13. [51] ZHAO Y, YIN S, SERIGHT R S, et al. Enhancing heavy-oil-recovery
[40] HENDRANINGRAT L, LI S, TORSÆTER O. A coreflood investigation efficiency by combining low-salinity-water and polymer flooding[J].
of nanofluid enhanced oil recovery[J]. Journal of Petroleum Science SPE Journal, 2021, 26(3): 1535-1551.
and Engineering, 2013, 111: 128-138. [52] Al-ANSSARI S, WANG S B, BARIFCANI A, et al. Effect of
[41] CHERAGHIAN G, HENDRANINGRAT L. A review on applications temperature and SiO 2 nanoparticle size on wettability alteration of
of nanotechnology in the enhanced oil recovery part A: Effects of oil-wet calcite[J]. Fuel, 2017, 206: 34-42.
nanoparticles on interfacial tension[J]. International Nano Letters, [53] KAZEMZADEH Y, SHOJAEI S, RIAZI M, et al. Review on
2016, 6(2): 129-138. application of nanoparticles for EOR purposes: A critical review of
[42] ROUSTAEI A, MOGHADASI J, IRAN A, et al. An experimental the opportunities and challenges[J]. Chinese Journal of Chemical
investigation of polysilicon nanoparticles recovery efficiencies through Engineering, 2019, 27(2): 237-246.
changes in interfacial tension and wettability alteration[C]//SPE [54] LI S, DANIEL D, LAU H C, et al. Visualizing and quantifying
International Oilfield Nanotechnology Conference and Exhibition, wettability alteration by silica nanofluids[J]. ACS Applied Materials
Noordwijk, 2012, SPE-156976-MS. & Interfaces, 2021, 13(34): 41182-41189.
[43] JOONAKI E, GHANAATIAN S. The application of nanofluids for [55] RAJ I, QU M, XIAO L Z, et al. Ultralow concentration of
enhanced oil recovery: Effects on interfacial tension and coreflooding molybdenum disulfide nanosheets for enhanced oil recovery[J]. Fuel,
process[J]. Petroleum Science and Technology, 2014, 32(21): 2599-2607. 2019, 251: 514-522.
[44] ZHOU Y X, WU X, ZHONG X, et al. Surfactant-augmented functional [56] HENDRANINGRAT L, TORSÆTER O. Understanding fluid-fluid
silica nanoparticle based nanofluid for enhanced oil recovery at high and fluid-rock interactions in the presence of hydrophilic nanoparticles
temperature and salinity[J]. ACS Applied Materials & Interfaces, at various conditions [C]//SPE Asia Pacific Oil & Gas Conference
2019, 11(49): 45763-45775. and Exhibition, 2014, SPE-171407-MS.
[45] WASAN D T, NIKOLOV A D, KONDIPARTY K. The wetting and [57] MAGHZI A, KHARRAT R, MOHEBBI A, et al. The impact of silica
spreading of nanofluids on solids: Role of the structural disjoining nanoparticles on the performance of polymer solution in presence of
pressure[J]. Current Opinion in Colloid & Interface Science, 2011, salts in polymer flooding for heavy oil recovery[J]. Fuel, 2014, 123:
16(4): 344-349. 123-132.
[46] WASAN D T, NIKOLOV A D. Spreading of nanofluids on solids[J]. [58] LIU P, LI X, YU H, et al. Functional Janus-SiO 2 nanoparticles
Nature, 2003, 423(6936): 156-159. prepared by a novel “cut the gordian knot” method and their potential
[47] ZHANG H, NIKOLOV A, WASAN D. Enhanced oil recovery (EOR) application for enhanced oil recovery[J]. ACS Applied Materials &
using nanoparticle dispersions: Underlying mechanism and imbibition Interfaces, 2020, 12(21): 24201-24208.

（上接第 1565 页） 2016, 66: 178-184.
[40] PORANKI D, WHITENER W, HOWSE S, et al. Evaluation of skin [46] ZHAI M C, XU Y C, ZHOU B, et al. Keratin-chitosan/n-ZnO
regeneration after burns in vivo and rescue of cells after thermal nanocomposite hydrogel for antimicrobial treatment of burn wound
stress invitro following treatment with a keratin biomaterial[J]. healing: Characterization and biomedical application[J]. Journal of
Journal of Biomaterials Applications, 2013, 29(1): 26-35. Photochemistry and Photobiology B: Biology, 2018, 180: 253-258.
[41] RAJABI M, ALI A, MCCONNELL M, et al. Keratinous materials: [47] SADEGHI A, NOURMOHAMMADI J, GHAEE A, et al.
Structures and functions in biomedical applications[J]. Materials Carboxymethyl cellulose-human hair keratin hydrogel with controlled
Science and Engineering C, 2020, 110: 110612-110674. clindamycin release as antibacterial wound dressing[J]. International
[42] SUN Z, YI Z, ZHANG H Y, et al. Bio-responsive alginate-keratin Journal of Biological Macromolecules, 2020, 147: 1239-1247.
composite nanogels with enhanced drug loading efficiency for cancer [48] PARK M, KIM B S, SHIN H K, et al. Preparation and
therapy[J]. Carbohydrate Polymers, 2017, 175: 159-169. characterization of keratin-based biocomposite hydrogels prepared
[43] REN Y X, YU X Z, LI Z H, et al. Fabrication of pH-responsive by electron beam irradiation[J]. Materials Science & Engineering C:
TA-keratin bio-composited hydrogels encapsulated with Materials for Biological Applications, 2013, 33(8): 5051-5057.
photoluminescent GO quantum dots for improved bacterial inhibition [49] LEE C, PANT B, KIM B S, et al. Carbon quantum dots incorporated
and healing efficacy in wound care management: In vivo wound keratin/polyvinyl alcohol hydrogels: Preparation and photoluminescent
evaluations[J]. Journal of Photochemistry and Photobiology B: assessment[J]. Materials Letters, 2017, 207(15): 57-61.
Biology, 2019, 202: 1-31. [50] SHARIATINIA Z. Big family of nano- and microscale drug delivery
[44] ZHANG H F, PEI M L, LIU P. pH-activated surface charge-reversal systems ranging from inorganic materials to polymeric and stimuli-
double-crosslinked hyaluronic acid nanogels with feather keratin as responsive carriers as well as drug-conjugates[J]. Journal of Drug
multifunctional crosslinker for tumor-targeting DOX delivery[J]. Delivery Science and Technology, 2021, 66: 102790-102843.
International Journal of Biological Macromolecules, 2020, 150: [51] BAJESTANI M I, KADER S, MONAVARIAN M, et al. Material
1104-1112. properties and cell compatibility of poly(γ-glutamic acid)-keratin
[45] KAKKAR P, MADHAN B. Fabrication of keratin-silica hydrogel for hydrogels[J]. International Journal of Biological Macromolecules,
biomedical applications[J]. Materials Science & Engineering C, 2020, 142: 790-802.

69 70 71 72 73 74 75 76 77 78 79