References

1. S.W. Hughes, J.M. Slater, Produced water treatment technologies: a case study, Soc. Pet. Eng., SPE, 27131 (1994) 345–352.
2. G. Pieruz, P. Grassia, R.A.W. Dryfe, Boron removal from produced water by facilitated ion transfer, Desalination, 167 (2004) 417.
3. G.F. Doran, K.L. Williams, J.A. Drago, S.S. Huang, L.Y.C. Leong, Pilot study results to convert oil field produced water to drinking water or reuse quality, Soc. Pet. Eng., SPE, 54110 (1999) 1–12.
4. P. Baldoni-Andrey, N. Lesage, B. Segues, P. Pedenaud, P.-L. Dehaene, Impact of high salinity of produced water on the technical feasibility of biotreatment for E&P on shore applications, Soc. Pet. Eng., SPE, 98751 (2006) 1–5.
5. T.O. Ukpohor, Produced water: Environmental issues/technological solution of the Nigeria depletion era, Soc. Pet. Eng., SPE, 71437 (2001) 1–12.
6. Brazil, CONAMA Resolution N° 357 - Establishes provisions for the classification of water bodies as well as environmental directives for their framework, establishes conditions and standards for effluent releases and makes other provisions. The National Environment Council (CONAMA). Ministry of Environment, (2005) 1–27.
7. Brazil, CONAMA Resolution Nº 393 - Establishes provisions for the continuous release of processed water or water produced on oil and natural gas sea platforms and makes other provisions. The National Environment Council (CONAMA). Ministry of Environment, (2007) 1–3.
8. Brazil, CONAMA Resolution Nº 430 - Provisions the conditions and standards of effluents and complements and changes Resolution 357. The National Environment Council (CONAMA). Ministry of Environment, (2011) 1–9.
9. K. Dahm, M. Chapman, Produced water treatment primer: Case studies of treatment applications. Reclamation - Managing water in the West, U.S. Department of the Interior, Bureau of Reclamation, (2014) 1–58.
10. E.T. Igunnu, G.Z. Chen, Produced water treatment technologies, Int. J. Low-Carbon. Tech., 9 (2014) 157–177.
11. H. Duhon, Produced water treatment: Yesterday, today, and tomorrow, Oil and Gas Facilities, 1 (2012) 29–30.
12. F.-R. Ahmadun, A. Pendashteh, L.C. Abdullah, D.R.A. Biak, S.S. Madaeni, Z.Z. Abidin, Review of technologies for oil and gas produced water treatment, J. Hazard. Mater., 170 (2009) 530–551.
13. V.K. Gupta, I. Ali, T.A. Saleh, A. Nayak, S. Agarwal, Chemical treatment tecnologies for wastewater recycling - an overview, RSC Adv., 2 (2012) 6380–6388.
14. E.V. Santos, J.H.B. Rocha, D.M. Araújo, D.C, Moura, C.A. Martinez-Huide, Decontamination of produced water containing petroleum hydrocarbons by electrochemical methods: A minireview, Envirol. Sci. Pollut. Res., 21 (2014) 8432–8441.
15. J.G. Ottaviano, J. Cai, R.S. Murphy, Assessing the decontamination efficiency of a three-component flocculation system in the treatment of oilfield-produced water, Water Res., 52 (2014) 122–130.
16. M. Padaki, R.S. Murali, M.S. Abdullah, N. Misdan, A. Moslehyani, M.A. Kassin, N. Hilal, A.F. Ismail, Membrane technology enhanced oil-water separation. A review, Desalination, 357 (2015) 197–207.
17. B.D. Coday, C. Hoppe-Jones, D. Wandera, J. Shethji, J. Herron, K. Lampi, S.A. Snyder, T.Y. Cath, Evaluation of the transport parameters and physiochemical properties of forward osmosis membranes after treatment of produced water, J. Membr. Sci., 499 (2016) 491–502.
18. S. Munirasu, M.A. Haija, F. Banat, Use of membrane technology for oil field and refinery produced water treatment - A review, Process Saf. Environ. Prot., 100 (2016) 183–202.
19. H.S. Almarouf, M.S. Nasser, M.J. Al-Marri, M. Khraisheh, S.A. Onaizi, Demulsification of stable emulsions from produced water using a phase separator with inclined parallel arc coalescing plates, J. Pet. Sci. Eng., 135 (2015) 16–21.
20. Z.G. Naraghi, S. Yaghmaei, M.M. Mardanpour, M. Hasany, Produced water treatment with simultaneous bioenergy production using novel bioeletrochemical systems, Electrochim. Acta., 180 (2015) 535–544.
21. J.M. Younker, M.E. Walsh, Bench-scale investigation of an integrated adsorption-coagulation-dissolved air flotation process for produced water treatment, J. Environ. Chem. Eng., 2 (2014) 692–697.
22. A. Motta, C. Borges, K. Esquerre, A. Kiperstok, Oil produced water treatment for oil removal by an integration of coalescer bed and microfiltration membrane processes, J. Membr. Sci., 469 (2014) 371–378.
23. R.T. Duraisamy, A.H. Beni, A. Henni, State of the art treatment of produced water, In: W. Elshorbagy, R.K. Chowdhury, Water treatment, InTech, UK, 2013, pp. 199–222.
24. L.L. Schramm, D.G. Marangoni, Surfactants and their solutions: Basic principles, In: Surfactants: fundamentals and applications in the petroleum industry, Cambridge University Press, UK, 2000, pp. 3–50.
25. T.P. Hoar, J.H. Schulman, Transparent water-in-oil dispersions: The oleopathic hydro-micelle, Nature, 152 (1943) 102–103.
26. C. Solans, R. Ponds, Overview of basic aspects of microemulsions. In: C Solans, H. Kunieda, Industrial applications of microemulsions, Marcel Dekker Inc., Surfact Sci. Series 66, New York 1997, pp. 1–18.
27. A.A. Dantas Neto, T.N.C. Dantas, M.C.P.A. Moura, E.L. Barros Neto, A. Gurgel, Microemulsions as potential interfacial chemical systems applied in the petroleum industry. In: M. Fanun, Microemulsions: Properties and Applications, CRC Press, Surfact Sci. Series 144, Boca Raton 2009, pp. 411–449.
28. T.N. Castro Dantas, A.A. Dantas Neto, M.C.P.A. Moura, Removal of chromium from aqueous solutions by diatomite treated with microemulsion ,Water Res., 35 (2001) 2219–2224.
29. T.N. Castro Dantas, A.A. Dantas Neto, M.C.P.A, Moura, E.L. Barros Neto, K.R. Forte, R.H. Leite, Heavy metals extraction by microemulsions, Water Res., 37 (2003) 2709–2717.
30. T.N. Castro Dantas, K.R. Oliveira, A.A. Dantas Neto, M.C.P.A. Moura, The use of microemulsions to remove chromium from industrial sludge, Water Res., 43 (2009) 1464–1470.
31. Y. Yan-Zhao, Z. Tao, X. Chuan-Bo, X. Xue-Mei, L. Ling, L. Zhan-Yu, Study on the extraction of cobalt and nickel from NH₄SCN solution by Winsor II microemulsion system, Sep. Purif. Technol., 60 (2008) 174–179.
32. W. Lu, Y. Lu, F. Liu, K. Shang, W. Wang, Y. Yang, Extraction of gold (III) from hydrochloric acid solutions by CTAB/nheptane/iso-amyl alcohol/Na2SO3 microemulsion, J. Hazard. Mater., 186 (2011) 2166–2170.
33. R. Leung, D.O. Shah, Solubilization and phase equilibria of water-in-oil microemulsions: II. Effects of alcohols, oils, and salinity on single-chain surfactant systems, J. Colloid Interface. Sci., 120 (1987) 330–344.
34. P.A. Winsor, Hydrotopy, solubilization, and related emulsification processes - Part I, Trans. Faraday Soc., 44 (1948) 376–382.
35. S.P. Moulik, B.K. Paul, Uses and applications of microemulsionsulsions, Curr. Sci., 80 (2001) 990–1001.
36. A.C.S. Ramos, A.A. Dantas Neto, T.N.C. Dantas, Application of an experimental methodology in the optimization of a tungsten concentration process by microemulsions, Braz. J. Chem. Eng., 14 (1997) 159–165.
37. G.A.V. Aken, J.T.G. Overbeek, P.L.D. Bruijn, H.N.W. Lekkerkerker, Partitioning of salt in Winsor II microemulsion systems with an anionic surfactant and the consequences for the phase behavior, J. Colloid Interface Sci., 157 (1993) 235–243.
38. S.A. Arain, T.G. Kazi, H.I. Afridi, M.S. Arain, A.H. Panhwar, N. Khan, J.A. Baig, F. Shah, A new dispersive liquid–liquid microextraction using ionic liquid based microemulsion coupled with cloud point extraction for determination of copper in serum and water samples, Ecotoxicol. Environ. Saf., 126 (2016) 186–192.
39. H. Watarai, Microemulsions in separation sciences, J. Chromatogr. A, 780 (1997) 93–102.
40. P. Plucinski, W. Nitsch, Kinetics of the interfacial ion exchange in Winsor II microemulsion systems, J. Colloid Interface Sci., 154 (1992) 104–112.
41. H.S. Ferreira, A.C.N. Santos, L.A. Portugal, C.S. Costa, M. Miró, S.L.C. Ferreira, Pre-concentration procedure for determination of copper and zinc in food samples by sequential multi-element flame atomic absorption spectrometry, Talanta, 77 (2008) 73–76.