References

1. N. Chaouch, M. Chaouki, Water treatment processes applied at the deoiling stations at Hassi Messaoud (efficiency and professional risks), Mater. Biomater. Sci., 1 (2018) 29–34.
2. M. Han, Y. Chen, F. He, L. Yu, Treatment of oily wastewater with WPO and CWO, J. Korean Chem. Soc., 1 (2014) 68–71.
3. L. Yu, M. Han, F. He, A review of treating oily wastewater, Arab. J. Chem., 10 (2017) S1913–S1922.
4. S. Hossain, F. Omar, A.J. Asis, R.T. Bachmann, M.Z.I. Sarker, M.O. Ab Kadir, Effective treatment of palm oil mill effluent using FeSO₄·7H₂O waste from titanium oxide industry: coagulation adsorption isotherm and kinetics studies, J. Cleaner Prod., 219 (2019) 86–98.
5. Y. Abu Zahrim, Z.D. Dexter, G.J. Collin, N. Hilal, Effective coagulation–flocculation treatment of highly polluted palm oil mill biogas plant wastewater using dual coagulants: decolourisation, kinetics and phytotoxicity studies, J. Water Process Eng., 16 (2017) 258–269.
6. S. Zhao, B. Gao, Q. Yue, Y. Wang, Effect of Enteromorpha polysaccharides on coagulation performance and kinetics for dye, Colloids Surf., A, 456 (2014) 253–260.
7. N. Precious Sibiya, S. Rathilal, E. Kweinor Tetteh, Coagulation treatment of wastewater: kinetics and natural coagulant evaluation, Molecules, 26 (2021) 698, doi: 10.3390/ molecules26030698.
8. J. Gregory, Particles in Water: Properties and Processes, CRC Press Taylor & Francis, London, 2005.
9. D.J. Pernitsky, J.K. Edzwald, Selection of alum and polyaluminum coagulants: principles and applications,
   J. Water Supply Res. Technol. AQUA, 55 (2006) 121–141.
10. K. Abuhasel, M. Kchaou, M. Alquraish, Y. Munusamy, T.J. Jeng, Oily wastewater treatment: overview of conventional and modern methods, challenges, and future opportunities, Water, 13 (2021) 980, doi:10.3390/w13070980.
11. J.P. Beaudry, Traitement des eaux, Le Griffon d’Argil, Québec, 1984.
12. J. Bratby, Coagulation and Flocculation with an Emphasis on Water and Wastewater Treatment, Uplands Press, Croydon, UK, 1980.
13. R. Desjardins, Le traitement des eaux (2eme édition), Tec et Doc Lavoisier, Paris, 1990.
14. J. Sánchez-Martín, J. Beltrán-Heredia, JA. Peres, Improvement of the flocculation process in water treatment by using Moringa oleifera seeds extract, Braz. J. Chem. Eng., 29 (2012) 495–502.
15. O.P. Sahu, P.K. Chaudhari, Review on chemical treatment of industrial waste water, J. Appl. Sci. Environ. Manage., 2 (2013) 241–257.
16. D. Zogo, L.M. Bawa, H.H. Soclo, D. Atchekpe, Élimination de la couleur et de la turbidité d’une eau de surface par coagulationfloculation au sulfate d’aluminium: cas de la retenue d’eau de l’Okpara en République du Bénin, Int. J. Biol. Chem. Sci., 5 (2010) 1667–1675.
17. J. Rodier, B. Legube, N. Merlet, L’analyse de l’eau: contrôle et interprétation, Dunod, Paris, 2016.
18. S. Maurya, A. Daverey, Evaluation of plant-based natural coagulants for municipal wastewater treatment, 3 Biotech, 8 (2018) 77, doi: 10.1007/s13205-018-1103-8.
19. M.H. Sellami, F. Benhabireche, H. Frouhat, Chemical treatment process and reuse of oily-waters arising from petroleum field of HBK/Algeria, Int. J. Waste Resour., 6 (2016) 2–6.
20. V. Saritha, N. Srinivas, N.V. Srikanth Vuppala, Analysis and optimization of coagulation and flocculation process, Appl. Water Sci., 7 (2017) 451–460.
21. H. Patel, R.T. Vashi, Comparison of naturally prepared coagulants for removal of COD and color from textile wastewater, Global Nest J., 15 (2013) 522–528.
22. O.S. Amuda, I.A. Amoo, O.O. Ajayi, Performance optimization of coagulant/flocculant in the treatment of wastewater from a beverage industry, J. Hazard. Mater., 129 (2006) 69–72.
23. F. Renaut, B. Sancey, P.M. Badot, G. Crini, Chitosan for coagulation/flocculation processes, an eco-friendly approach, Eur. Polym. J., 45 (2009) 1332–1348.
24. M.H. Sellami, K. Loudiyi, MC. Boubaker, H. Habbaz, Treatment and reuse of wastewaters discharged by petroleum industries (HMD/Algeria), Int. J. Waste Resour., 6 (2015)1–6.
25. F.M. Mohamed, K.A. Alfalous, The effectiveness of activated silica derived from rice husk in coagulation process compared with inorganic coagulants for wastewater treatment, Egypt. J. Aquat. Res., 46 (2020) 1–6.
26. B. Cerff, D. Key, B. Bladergroen, A review of the processes associated with the removal of oil in water pollution, Sustainability, 13 (2021) 1–20.
27. S. Jamaly, A. Giwa, S.W. Hasan, Recent improvements in oily wastewater treatment: progress, challenges, and future opportunities, J. Environ. Sci., 37 (2015) 15–30.
28. C. Zhao, J. Zhou, Y. Yan, L. Yang, G. Xing, H. Li, P. Wu, M. Wang, H. Zheng, Application of coagulation/flocculation in oily wastewater treatment: a review, Sci. Total Environ., 765 (2021) 142795, doi:10.1016/j.scitotenv.2020.142795.
29. Z. You, L. Zhang, S. Zhang, Y. Sun, K.J. Shah, Treatment of oilcontaminated water by modified polysilicate aluminum ferric sulfate, Processes, 6 (2018) 2–14.
30. K.M. Mousa, H.J. Hadi, Coagulation/flocculation process for produced water treatment, Int. J. Curr. Eng. Technol., 6 (2016) 551–555.
31. H. Farajnezhad, P. Gharbani, Coagulation treatment of wastewater in petroleum industry using poly aluminium chloride and ferric chloride, IJRRAS, 13 (2012) 306–310.