References

  1. T.S. Mykkeltvedt, X. Raynaud, K.A. Lie, Fully implicit higher-order schemes applied to polymer flooding, Comput. Geosci., 21 (2017) 1245–1266.
  2. X. Kang, J. Zhang, F. Sun, F. Zhang, G. Feng, J. Yang, X. Zhang, W. Xiang, A review of polymer EOR on offshore heavy oil field in Bohai Bay, China. SPE Enhanced Oil Recovery Conference; Kuala Lumpur, Malaysia: Society of Petroleum Engineers, 2011.
  3. H. Chen, X. Zhang, Y. Chen, H. Tang, Y. Mei, B. Li, X. Shen, Study on pressure interval of near-miscible flooding by production gas re-injection in QHD offshore oilfield, J. Petrol. Sci. Eng., 157 (2017) 340–348.
  4. H.X. Chen, H.M. Tang, X.P. Gong, J.J. Wang, Y.G. Liu, M. Duan, F. Zhao, Effect of partially hydrolyzed polyacrylamide on emulsification stability of wastewater produced from polymer flooding, J. Petrol. Sci. Eng., 133 (2015) 431–439.
  5. H.X. Chen, H.M. Tang, M. Duan, Y.G. Liu, M. Liu, F. Zhao, Oil–water separation property of polymer-contained wastewater from polymer-flooding oilfields in Bohai Bay, China, Environ. Technol., 36 (2015) 1373–1380.
  6. Y. Liu, H. Tang, H. Chen, Y. Li, S. Wang, J. Gao, Study on produced water quality variation rule from polymer flooding and mechanism of formation damage, Offshore Oil, 30 (2010) 86–91 (in Chinese).
  7. J.J. Sheng, Formation damage in chemical enhanced oil recovery processes, Asia-Pac. J. Chem. Eng., 11 (2016) 826–835.
  8. H. Hoteit, D. Alexis, O.O. Adepoju, A. Chawathe, T. Malik, Numerical and experimental investigation of polymer-induced resistance to flow in reservoirs undergoing a chemical flood. In SPE Annual Technical Conference and Exhibition. Society of Petroleum Engineers, September 2016.
  9. M. Shoaib, Adsorption of EOR Polymers and Surfactants on Carbonate Minerals, Master’s thesis, University of Waterloo, 2014.
  10. Z.H. Liu, C.C. Zhou, L.H. Zhang, D.J. Dai, C.L. Li, L. Zhang, G.Q. Liu, Y.J. Shi, An innovative method to evaluate formation pore structure using NMR logging data. In 48th Annual Logging Symposium. Society of Petrophysicists and Well-Log Analysts, 2007.
  11. G. Layrac, C. Gerardin, D. Tichit, S. Harrisson, M. Destarac, Hybrid polyion complex micelles from poly (vinylphosphonic acid)-based double hydrophilic block copolymers and divalent transition metal ions, Polymer, 72 (2015) 292–300.
  12. A. Barhoum, L. Van Lokeren, H. Rahier, A. Dufresne, G. Van Assche, Roles of in situ surface modification in controlling the growth and crystallization of CaCO3 nanoparticles, and their dispersion in polymeric materials, J. Mater. Sci., 50 (2015) 7908– 7918.
  13. H. Vehkamäki, Classical Nucleation Theory in Multicomponent Systems. Springer, Berlin Heidelberg, 2006.
  14. S. Weiner, L. Addadi, Crystallization pathways in biomineralization, Annu. Rev. mater. Res., 41 (2011) 21–40.
  15. F. Manoli, S. Koutsopoulos, E. Dalas, Crystallization of calcite on chitin, J. Crystal Growth, 182 (1997) 116–124.
  16. K. Naka, S.C. Huang, Y. Chujo, Formation of stable vaterite with poly(acrylic acid) by the delayed addition method, Langmuir, 22 (2006) 7760–7767.
  17. Y.Y. Wang, Q.Z. Yao, H. Li, G.T. Zhou, Y.M. Sheng, Formation of vaterite mesocrystals in biomineral-like structures and implication for biomineralization, Crystal Growth Design, 15 (2015) 1714–1725.
  18. Y. Boyjoo, V.K. Pareek, J. Liu, Synthesis of micro and nanosized calcium carbonate particles and their applications, J. Mater. Chem., A 2 (2014) 14270–14288.
  19. S. Ouyang, W. Sun, H. Huang, Multi-method synergistic characterization of total pore structure of extra-low permeability sandstone reservoirs: case study of the Heshui area of Ordos Basin, Petrol. Geol. Experim., 40 (2018) 595–604.