Nanofluids have broad prospects in enhancing the oil recovery of reservoirs with low porosity, low permeability, high capillary pressure and low oil recovery. However, the modification effects of nanofluids on tight glutenite reservoirs remain unknown. In this paper, nanofluids with different proportions of silica nanoparticles and sodium dodecyl sulfate were prepared and characterized by zeta potential and particle size distribution. Then, the effects of nanofluids on interfacial tension and reservoir wettability were examined. Next, a computational fluid dynamics method was adopted to further investigate the effects of nanofluids and injection pressure on enhancing oil recovery of the Baikouquan Formation at the pore scale. The experimental results showed that all prepared nanofluids are stable systems with uniform dispersion. The interfacial tension between the nanofluids and oil was reduced by up to 8.01% compared with water, and the reservoir wettability was changed from intermediate-wet to strong hydrophilicity. The simulation results revealed that the water and nanofluid flooding processes could be divided into two stages: the initial channel establishment stage and the channel expansion stage. In the initial stage, the nanofluids hardly showed an enhanced oil recovery effect due to the faster and sharper migration fronts. In the channel expansion stage, the nanofluids clearly showed an enhanced oil recovery effect, as the nanofluids could displace the oil in the relative dead pores during water flooding. After 10 pore volume injection of displacement fluid at an injection pressure of 1 MPa, the oil recovery using NF5 was highest at 76.58%. In addition, a higher injection pressure led to the extraction of relative dead oil at a lower injection pressure near the inlet with a smaller sweep area near the outlet; the effect on recovery has both advantages and disadvantages.

Document Type: Original article

Cited as: Cao, X., Li, Q., Myers, M., Xu, L., Chen, Q., Tan, Y. Nanofluid impact on fluid interaction and migration characteristics for enhanced oil recovery in Baikouquan tight glutenite. Advances in Geo-Energy Research, 2023, 9(2): 94-105. https://doi.org/10.46690/ager.2023.08.03

Adil, M., Zaid, H. M., Raza, F., et al. Experimental evaluation of oil recovery mechanism using a variety of surface-modified silica nanoparticles: Role of in-situ surface-modification in oil-wet system. PLoS ONE, 2020, 15(7): 0236837.

Afekare, D., Garno, J., Rao, D. Enhancing oil recovery using silica nanoparticles: Nanoscale wettability alteration effects and implications for shale oil recovery. Journal of Petroleum Science and Engineering, 2021, 203: 108897.

Almahfood, M., Bai, B. The synergistic effects of nanoparticle-surfactant nanofluids in EOR applications. Journal of Petroleum Science and Engineering, 2018, 171: 196-210.

Bera, A., Vij, R. K., Shah, S. Impact of newly implemented enhanced oil and gas recovery screening policy on current oil production and future energy supply in India. Journal of Petroleum Science and Engineering, 2021, 207: 109196.

Chakraborty, S., Panigrahi, P. K. Stability of nanofluid: A review. Applied Thermal Engineering, 2020, 174: 115259.

Chauhan, A., Salehi, F., Jalalifar, S., et al. Two-phase modelling of the effects of pore-throat geometry on enhanced oil recovery. Applied Nanoscience, 2021, 13(1): 453-464.

Cheraghian, G., Hendraningrat, L. A review on applications of nanotechnology in the enhanced oil recovery part B: Effects of nanoparticles on flooding. International Nano Letters, 2016, 6(1): 1-10.

Chowdhury, S., Shrivastava, S., Kakati, A., et al. Comprehensive review on the role of surfactants in the chemical enhanced oil recovery process. Industrial & Engineering Chemistry Research, 2022, 61(1): 21-64.

Eltoum, H., Yang, Y. L., Hou, J. R. The effect of nanoparticles on reservoir wettability alteration: A critical review. Petroleum Science, 2021, 18(1): 136-153.

Gharibshahi, R., Jafari, A., Haghtalab, A., et al. Application of CFD to evaluate the pore morphology effect on nanofluid flooding for enhanced oil recovery. RSC Advances, 2015, 5(37): 28938-28949.

Goharzadeh, A., Fatt, Y. Y., Sangwai, J. S. Effect of TiO2-SiO2 hybrid nanofluids on enhanced oil recovery process under different wettability conditions. Capillarity, 2023, 8(1): 1-10.

Gysi, A. P., Stef´ansson, A. CO2-water-basalt interaction. Low temperature experiments and implications for CO2 sequestration into basalts. Geochimica et Cosmochimica Acta, 2012, 81: 129-152.

Hemmat Esfe, M., Esfandeh, S. 3D numerical simulation of the enhanced oil recovery process using nanoscale colloidal solution flooding. Journal of Molecular Liquids, 2020, 301: 112094.

Hendraningrat, L., Li, S. D., Torster, O. A coreflood investigation of nanofluid enhanced oil recovery. Journal of Petroleum Science and Engineering, 2013, 111: 128-138.

Joonaki, E., Ghanaatian, S. The application of nanofluids for enhanced oil recovery: Effects on interfacial tension and coreflooding process. Petroleum Science and Technology, 2014, 32(21): 2599-2607.

Kalam, S., Abu-Khamsin, S. A., Kamal, M. S., et al. A review on surfactant retention on rocks: Mechanisms, measurements, and influencing factors. Fuel, 2021, 293: 120459.

Kondiparty, K., Nikolov, A., Wu, S., et al. Wetting and spreading of nanofluids on solid surfaces driven by the structural disjoining pressure: Statics analysis and experiments. Langmuir, 2011, 27(7): 3324-3335.

Kumar, R. S., Chaturvedi, K. R., Iglauer, S., et al. Impact of anionic surfactant on stability, viscoelastic moduli, and oil recovery of silica nanofluid in saline environment. Journal of Petroleum Science and Engineering, 2020, 195: 107634.

Li, Y., Dai, C., Zhou, H., et al. Investigation of spontaneous imbibition by using a surfactant-free active silica water-based nanofluid for enhanced oil recovery. Energy & Fuels, 2018, 32(1): 287-293.

Lv, M., Wang, S. Pore-scale modeling of water/oil two-phase flow in hot water flooding for enhanced oil recovery. RSC Advances, 2015, 5(104): 85373-85382.

Miyasaka, K., Imai, Y., Tajima, K. Preparation of oil-in-water and water-in-oil emulsions with the same composition using hydrophilic nanoparticles by three-phase emulsification. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2023, 670: 131598.

Mmbuji, A., Cao, R., Zhu, Z., et al. A comprehensive review of recent advances on surfactant architectures and their applications for unconventional reservoirs. Journal of Petroleum Science and Engineering, 2021, 206: 109025.

Moradi, B., Pourafshary, P., Jalali, F., et al. Experimental study of water-based nanofluid alternating gas injection as a novel enhanced oil-recovery method in oil-wet carbonate reservoirs. Journal of Natural Gas Science and Engineering, 2015, 27: 64-73.

Mousavi, S. P., Hemmati-Sarapardeh, A., Norouzi-Apourvari, S., et al. Toward mechanistic understanding of wettability alteration in calcite and dolomite rocks: The effects of resin, asphaltene, anionic surfactant, and hydrophilic nano particles. Journal of Molecular Liquids, 2021, 321: 114672.

Muhamad, M. S., Salim, M. R., Lau, W. J. Surface modification of SiO2 nanoparticles and its impact on the properties of PES-based hollow fiber membrane. RSC Advances, 2015, 5(72): 58644-58654.

Nasr, M. S., Esmaeilnezhad, E., Choi, H. J. Effect of silicon-based nanoparticles on enhanced oil recovery: Review. Journal of the Taiwan Institution of Chemical Engineers, 2021, 122: 241-259.

Nikolov, A., Kondiparty, K., Wasan, D. Nanoparticle self-structuring in a nanofluid film spreading on a solid surface. Langmuir, 2010, 26(11): 7665-7670.

Pan, Y., Lu, X. C., Pan, G. S., et al. Performance of sodium dodecyl sulfate in slurry with glycine and hydrogen peroxide for copper-chemical mechanical polishing. Journal of the Electrochemical Society, 2010, 157(12): 1082-1087.

Rashidi, M., Kalantariasl, A., Saboori, R., et al. Performance of environmental friendly water-based calcium carbonate nanofluid as enhanced recovery agent for sandstone oil reservoirs. Journal of Petroleum Science and Engineering, 2021, 196: 107644.

Saien, J., Bahrami, M. Understanding the effect of different size silica nanoparticles and SDS surfactant mixtures on interfacial tension of n-hexane-water. Journal of Molecular Liquids, 2016, 224: 158-164.

Sidiq, H., Abdulsalam, V., Nabaz, Z. Reservoir simulation study of enhanced oil recovery by sequential polymer flooding method. Advances in Geo-Energy Research, 2019, 3(2): 115-121.

Wang, Y., Fan, D., Dong, S., et al. Domestic and international oil & gas resources situation analysis and outlook in 2022. China Mining, 2023, 32(1): 16-22. (in Chinese)

Xu, L., Li, Q., Myers, M., et al. Investigation of the enhanced oil recovery mechanism of CO2 synergistically with nanofluid in tight glutenite. Energy, 2023, 273: 127275.

Yekeen, N., Padmanabhan, E., Sevoo, T. A. L., et al. Wettability of rock/CO2/brine systems: A critical review of influencing parameters and recent advances. Journal of Industrial and Engineering Chemistry, 2020, 88: 1-28.

Yu, T., Li, Q., Hu, H., et al. Molecular dynamics simulation of the interfacial wetting behavior of brine/sandstone with different salinities. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2022, 632: 127807.

Zhang, C. J., Jin, X., Tao, J. P., et al. Comparison of nanomaterials for enhanced oil recovery in tight sandstone reservoir. Frontiers in Earth Science, 2021, 9: 746071.

Zhao, J., Wen, D. Pore-scale simulation of wettability and interfacial tension effects on flooding process for enhanced oil recovery. RSC Advances, 2017, 7(66): 41391-41398.

Zhao, J., Yao, G., Wen, D. Pore-scale simulation of water/oil displacement in a water-wet channel. Frontiers of Chemical Science and Engineering, 2019, 13(4): 803-814.

Zhou, H., Dai, C., Zhang, Q., et al. Interfacial rheology of novel functional silica nanoparticles adsorbed layers at oil-water interface and correlation with pickering emulsion stability. Journal of Molecular Liquids, 2019, 293: 111500.