References

1. A.R. Khataee, V. Vatanpour, A.R. Amani Ghadim, Decolorization of C.I. acid blue 9 solution by UV/Nano-TiO2, Fenton, Fentonlike, electro-Fenton and electrocoagulation processes: a comparative study, J. Hazard. Mater., 161 (2009) 1225–1233.
2. M.S. Mahmoud, J.Y. Farah, T.E. Farrag, Enhanced removal of Methylene Blue by electrocoagulation using iron electrodes, Egypt. J. Pet., 22 (2013) 211–216.
3. A. Anouzla, Y. Abrouki, S. Souabi, M. Safi, H. Loukili, H. Rhbal, R. Slimani, Optimization of coagulation process with SIWW is coagulant for colour and COD removal of acid dye effluent using central composite design experiment, Int. J. Environ. Monit. Anal., 2 (2014) 1–5.
4. R.V. Kandisa, K.V.N. Saibaba, S.K. Beebi, R. Gopinath, Dye Removal by Adsorption: A Review, J. Bioremediat. Biodegrad., 7 (2016) 1–16.
5. H.N.J. Hoong, N. Ismail, Removal of dye in wastewater by adsorption- coagulation combined system with Hibiscus Sabdariffa as the coagulant, MATEC Web Conf., 152 (2018) 1–7.
6. F. Zidane, P. Drogui, B. Lekhlif, J. Bensaid, J.F. Blais, S. Belcadi, K. El Kacemi, Decolourization of dye- containing effluent using mineral coagulants produced by electrocoagulation, J. Hazard. Mater., 155 (2008) 153–163.
7. V. Kuokkanen, T. Kuokkanen, J. Rämö, U. Lassi, Recent applications of electrocoagulation in treatment of water and wastewater—a review, GSC, 3 (2013) 89–12.
8. A.S. Naje, S. Chelliapan, Z. Zakaria, M.A. Ajeel, P.A. Alaba, A review of electrocoagulation technology for the treatment of textile wastewater, Rev. Chem. Eng., (2016) 1–30.
9. D. Rabiatuladawiyah, C.A. Luqman, S. Shafreeza, Potential of copper electrodes in electrocoagulation process for glyphosate herbicide removal, MATEC Web Conf., 103 (2017) 1–12.
10. R. Katal, H. Pahlavanzadeh, Influence of different combinations of aluminum and iron electrode on electrocoagulation efficiency: application to the treatment of paper mill wastewater, Desalination, 265 (2011) 199–205.
11. C. Guohua, Electrochemical technologies in wastewater treatment, Sep. Purif. Technol., 38 (2004) 11–41.
12. R.G.B. Akanksha, K.S. Lokesh, Comparative study of electrode material (iron, aluminum and stainless steel) for treatment of textile industry wastewater, Int. J. Environ. Sci., 4 (2014) 519–531.
13. N.M. Abu Ghalwa, A.M. Saqer, N.B. Farhat, Removal of reactive red 24 dye by clean electrocoagulation process using iron and aluminum electrodes, J. Chem. Eng. Process Technol., 7 (2016) 1–7.
14. E. Butler, Y.T. Hung, R.Y.L. Yah, M.S. Al Ahmad, Electrocoagulation in wastewater treatment, Water, 3 (2011) 495–525.
15. A.I. Adeogun, R.B. Balakrishnan, Electrocoagulation removal of anthraquinone dye Alizarin Red S from aqueous solution using aluminum electrodes: kinetics, isothermal and thermodynamics studies, Int. J. Electrochem. Sci. Eng., 6 (2016) 199–213.
16. C.E. Barrera Diaz, N. González-Rivas, The use of Al, Cu, and Fe in an integrated electrocoagulation-ozonation process, J. Chem., 2015 (2015) 1–6.
17. J.A. Impa, D.P. Nagarajappa, K. Gouda, N.T. Manjunath, Domestic wastewater treatment by electrocoagulation using copper and aluminum electrodes, Int. J. Innov. Res. Sci. Eng. Technol., 4 (2015) 3844–3850.
18. E. Bazrafshan, K.A. Ownagh, A.H. Mahvi, Application of electrocoagulation process using iron and aluminum electrodes for fluoride removal from aqueous environment, Electron. J. Chem., 9 (2012) 2297–2308.
19. Z. Atashzaban, A. Seidmohammadi, D. Nematollahi, G. Azarian, S.O. Heidary, A.R. Rahmani, The efficiency of electrocoagulation and electroflotation processes for removal of polyvinyl acetate from synthetic effluent, Avicenna. J. Environ. Health Eng., 3 (2016) 1–7.
20. M.A. Ahangarnokolaei, H. Ganjidoust, B. Ayati, Optimization of parameters of electrocoagulation/flotation process for removal of Acid Red 14 with mesh stainless steel electrodes, J. Water Reuse Desalin., 8 (2018) 278–292.
21. B.M.B. Ensano, L. Boreal, V. Naddeo, V. Belgiorno, M.D.G. De Luna, F.C. Ballesteros Jr, Removal of pharmaceuticals from wastewater by intermittent electrocoagulation, Water, 9 (2017) 1–15.
22. D.C. Johnson, D.S. Dandy, V.A. Shamamian, Development of a tubula high-density plasma reactor for water treatment, Water Res., 40 (2006) 311–322.
23. K. Shimizu, S. Muramatsu, T. Sonoda, M. Blajan, Water treatment by low voltage discharge in Water, Int. J. Plasma Environ. Sci. Technol., 4 (2010) 58–64.
24. A. Hazmi, R. Desmiarti, E.P. Waldo, A. Darwison, Removal of microorganisms in drinking water using a pulsed high voltage, J. Eng. Technol. Sci., 45 (2013) 1–8.
25. J. Wang, H. Tan, Y.L. Zhang, Y.Z. Pan, The treatment of high concentration dyeing wastewater with pulsed current electrocoagulation, Mod. Appl. Sci., 10 (2016) 87–97.
26. High-Voltage Water Purification for Water Recycling or Pointof- Use Applications, NASA, 2015 NP-2015–04–1498-HQ.
27. M. Jourshabani, A. Badiei, N. Lashgari, G.M. Ziarani, Application of response surface methodology as an efficient approach for optimization of operational variables in Benzene hydroxylation to Phenol by V/SBA-16 nanoporous catalyst, J. Nanostruct., 6 (2016) 105–113.
28. K.A.M. Said, M.A.M. Amin, Overview on the response surface methodology (RSM) in extraction processes, J. Appl. Sci. Proc. Eng., 2 (2015) 8–17.
29. S.A. Younis, W.I. El-Azab, N.S. El-Gendy, S.Q. Aziz, Y.M. Moustafa, H.A. Aziz, S.S. Abu Amr, Application of response surface methodology to enhance Phenol removal from refinery wastewater by microwave process, Int. J. Microwave Sci. Technol., (2014) 1–12.
30. Z. Derakhshan, M.A. Baghapour, M. Ranjbar, M. Faramarzian, Adsorption of methylene blue dye from aqueous solutions by modified pumice stone: kinetics and equilibrium studies, Health Scope, 2 (2013) 136–144.
31. D.B. Jirekar, A.A. Pathan, M. Farooqui, Adsorption studies of methylene blue dye from aqueous solution onto Phaseolus aureus biomaterials, Orient. J. Chem., 30 (2014) 1263–1269.
32. J.M. Salman, M.A. Baiee, A.R. Omran, Experimental study to removal of methylene blue dye from aqueous solution by adsorption on eco-friendly materials, Int. J. Chem. Technol. Res., 9 (2016) 560–566.
33. X. Duan, P. Wu, K. Pi, H. Zhang, D. Liu, A.R. Gerson, Application of modified electrocoagulation for efficient color removal from synthetic methylene blue wastewater, Int. J. Electrochem. Sci., 13 (2018) 5575–5588.
34. DR5000 Spectrophotometer Procedures Manual, Hach Company, 2005, November 05 Edition 2, Catalog Number DOC082.98.00670.
35. Y. Rohmah, A. Rinanti, D.I. Hendrawan, The determination of ground water quality based on the presence of Escherichia coli on populated area (a case study: Pasar Minggu, South Jakarta), IOP Conf. Series: Earth Environ. Sci., 106 (2018) 1–6.
36. A. Rompre´, P. Servais, J. Baudart, M.R. Roubin, P. Laurent, Detection and enumeration of coliforms in drinking water: current methods and emerging approaches, J. Microbiol. Methods, 49 (2002) 31–54.
37. K.N. Nicholson, K. Neumann, C. Dowling, S. Sharma, E.coli and Coliform Bacteria as indicators for Drinking Water Quality and handling of Drinking Water in the Sagarmatha National Park, Nepal, Environ. Manage. Sustain. Dev., 6 (2017) 411–418.
38. A.H. Divya, P.A. Solomon, Effects of some water quality parameters especially total coliform and fecal coliform in surface water of Chalakudy River, Procedia Technol., 24 (2016) 631–638.
39. N.D. Pant, N. Poudyal, S.K. Bhattacharya, Bacteriological quality of bottled drinking water versus municipal tap water in Dharan municipality, Nepal, J. Health, Popul. Nut., 35 (2016) 1–6.
40. S. Shafi, A.N. Kamili, M.A. Shah, S.A. Bandh, Coliform bacterial estimation: a tool for assessing water quality of Manasbal Lake of Kashmir, Himalaya, Afr. J. Microbiol. Res., 7 (2013) 3996–4000.
41. Standard Method for the Examination of Water and Wastewater, 20th ed,, 2018, pp. 47–58.
42. Microbiology- Cosmetics-General Instructions for Microbiological Examination [in Persian], Institute of Standards and Industrial Research of Iran, (2007) 48–50, ISIRI: 11068.
43. E.G. Gonzalez, J.C. Mirza-Rosca, Study of the corrosion of titanium and some of its alloys for biomedical and dental implant applications, J. Electroanal. Chem., 471 (1999) 109–124.
44. A.J. Varkey, Antibacterial properties of some metals and alloys in combating coliforms in contaminated water, Sci. Res. Essay, 5 (2010) 3834–3839.
45. A. Godymchuk, G. Frolov, A. Gusev, O. Zakharova, E. Yunda, D. Kuznetsov, E. Kolesnikov, Antibacterial properties of copper nanoparticle dispersions: influence of synthesis conditions and physicochemical characteristics, Mater. Sci. Eng., 98 (2015) 1–10.
46. R. McWeeny, More physics: electric charges and fields – electromagnetism, Universita di Pisa, (2011) 1–142.
47. H.G. Kwatny, K. Miu-Miller, Power System Dynamics and Control, Springer Science and Business Media, 2016, pp. 32–56.
48. C. Barrera-Díaz, P. Cañizares, F.J. Fernández, R. Natividad, M.A. Rodrigo, Electrochemical advanced oxidation processes: an overview of the current applications to actual industrial effluents, J. Mex. Chem. Soc., 58 (2014) 256–275.