References

1. J. Alcamo, T. Henrichs, T. Rösch, World Water in 2025: Global Modeling and Scenario Analysis for the World Commission on Water for the 21st Century, Center for Environmental Systems Research, University of Kassel, Germany, 7411 (7440), pp. 1–49.
2. M. Sarmadi, K. Yaghmaeian, R. Nabizadeh, K. Naddafi, R. Saeedi, S. Yousefzadeh, Investigation of natural ventilation potential in different hospital wards affiliated to Tehran university of medical sciences in 2014, Iran Occup. Health, 14 (2017) 150–158.
3. R.P. Schwarzenbach, T. Egli, T.B. Hofstetter, U. Von Gunten, B. Wehrli, Global water pollution and human health, Annu. Rev. Environ. Resour., 35 (2010) 109–136.
4. W.H. Corson, The Global Ecology Handbook: What You Can Do about the Environmental Crisis, ERIC, 1990.
5. R.G. Evans, E.J. Sadler, Methods and technologies to improve efficiency of water use, Water Resour. Res., 44 (2008) 1–15.
6. M. Sarmadi, M. Foroughi, H. Najafi Saleh, D. Sanaei, A.A. Zarei, M. Ghahrchi, E. Bazrafshan, Efficient technologies for carwash wastewater treatment: a systematic review, Environ. Sci. Pollut. Res., 27 (2020) 34823–34839.
7. M. Sarmadi, S. Mortezaeifar, M. Kermani, M. Gholami, Performance evaluation of Semnan Industry Park’s Advanced Wastewater Treatment Plant system (MBR) in industrial effluent recovery, Iran Occup. Health J., 14 (2017) 165–175.
8. U.J. Blumenthal, D.D. Mara, A. Peasey, G. Ruiz-Palacios, R. Stott, Guidelines for the microbiological quality of treated wastewater used in agriculture: recommendations for revising WHO guidelines, Bull. W.H.O., 78 (2000) 1104–1116.
9. B. Metcalf and G. Eddy, Tchobanoglous, Wastewater Engineering: Treatment Disposal Reuse, Central Book Company, McGraw Hill Companies, Inc., England, 1980.
10. W. Lau, A. Ismail, S. Firdaus, Carwash industry in Malaysia: Treatment of carwash effluent using ultrafiltration and nanofiltration membranes, Sep. Purif. Technol., 104 (2013) 26–31.
11. K. Boussu, C. Kindts, C. Vandecasteele, B. Van der Bruggen, Applicability of nanofiltration in the carwash industry, Sep. Purif. Technol., 54 (2007) 139–146.
12. E. Bazrafshan, F. KordMostafapoor, M.M. Soori, A.H. Mahvi, Application of combined chemical coagulation and electrocoagulation process to carwash wastewater treatment, Fresenius Environ. Bull., 21 (2012) 2694–2701.
13. I.A.R. Boluarte, M. Andersen, B.K. Pramanik, C.-Y. Chang, S. Bagshaw, L. Farago, V. Jegatheesan, L. Shu, Reuse of carwash wastewater by chemical coagulation and membrane bioreactor treatment processes, Int. Biodeterior. Biodegrad., 113 (2016) 44–48.
14. Z.A. Bhatti, Q. Mahmood, I.A. Raja, A.H. Malik, M.S. Khan, D. Wu, Chemical oxidation of carwash industry wastewater as an effort to decrease water pollution, Phys. Chem. Earth, 36 (2011) 465–469.
15. T. Li, T. Xue-Jun, C. Fu-Yi, Z. Qi, Y. Jun, Reuse of carwash wastewater with hollow fiber membrane aided by enhanced coagulation and activated carbon treatments, Water Sci. Technol., 56 (2007) 111–118.
16. T. Sibanda, R. Selvarajan, M. Tekere, H. Nyoni, S. Meddows‐ Taylor, Potential biotechnological capabilities of cultivable mycobiota from carwash effluents, MicrobiologyOpen, 6 (2017) 498.
17. D. Mazumder, S. Mukherjee, Treatment of automobile service station wastewater by coagulation and activated sludge process, Int. J. Environ. Sci. Dev., 2 (2011) 64.
18. A. Al-Gheethi, R. Mohamed, M.A.A. Rahman, M. Johari, A. Kassim, Treatment of Wastewater from Car Washes using Natural Coagulation and Filtration System, IOP Publishing, 136 (2016) 12046.
19. A. Breton, C. Vialle, M. Montrejaud-Vignoles, C. Cecutti, C. Vignoles, C. Sablayrolles, Contribution of car, truck, bus and subway wash station discharges to stormwater pollution (Toulouse, France), Fresenius Environ. Bull., 19 (2010) 1954–1962.
20. Z. Nadzirah, H. Nor Haslina, H. Rafidah, In Tilte, Trans Tech Publications, (2015).
21. A.C.S. Pinto, L. de Barros Grossi, R.A.C. de Melo, T.M. de Assis, V.M. Ribeiro; M.C.S. Amaral, K.C. de Souza Figueiredo, Carwash wastewater treatment by micro and ultrafiltration membranes: effects of geometry, pore size, pressure difference and feed flow rate in transport properties, J. Water Process. Eng., 17 (2017) 143–148.
22. A.J. Balkema, H.A. Preisig, R. Otterpohl, F.J. D. Lambert, Indicators for the sustainability assessment of wastewater treatment systems, Urban Water J., 4 (2002) 153–161.
23. D. Moher, A. Liberati, J. Tetzlaff, D.G. Altman, Preferred reporting items for systematic reviews and meta-analyses: the PRISMA statement, BMJ, 7 (2009) 339.
24. W. Abdelmoez, N.A. Barakat, A. Moaz, Treatment of wastewater contaminated with detergents and mineral oils using effective and scalable technology, Water Sci. Technol., 68 (2013) 974–981.
25. G.O. Adams, P.E. Ogedegbe, P. Tawari‐Fufeyin, Assessment of presence of heavy metals and other pollution burden parameters and their effect on water quality in Benin City, Edo State, Environ. Qual. Manage., 26 (2016) 65–87.
26. J. Alam, I.H. Farooqi, H. Haleem, In Management of Grey Water of an automobile workshop–A Case Study, Proceeding of International Workshop on Civil Engineering and Architecture held at Istanbul Turkey, 2014, pp. 133–138.
27. J. Alcocer, A. Lugo, L.E. Marín, E. Escobar, Hydrochemistry of waters from five cenotes and evaluation of their suitability for drinking-water supplies, northeastern Yucatan, Mexico, Hydrogeol. J., 6 (1998) 293–301.
28. A. Al-Odwani, M. Ahmed, S. Bou-Hamad, Carwash water reclamation in Kuwait, Desalination, 206 (2007) 17–28.
29. M. Asha, K. Chandan, H. Harish, S. NikhileswarReddy, K. Sharath, G.M. Liza, Recycling of wastewater collected from automobile service station, Procedia Environ. Sci., 35 (2016) 289–297.
30. I.M. Baddor, N. Farhoud, I. Mohammed, D. Abdel-Magid, S. Alshami, F. hassan Ahmad, E. Asaad, Study of carwash wastewater treatment by adsorption, (2014) 2–22.
31. M.E. Bakacs, S.E. Yergeau, C.C. Obropta, Assessment of carwash runoff treatment using bioretention mesocosms, J. Environ. Eng., 139 (2013) 1132–1136.
32. S. Bhattia, M.A. Memona, I. Kandhira, Z. Siddiquib, S. Memona, G.D. Valasaic, Analysis and Treatment of Wash off Water from Vehicular Service Centres in Hyderabad, Structure, 1 (2016) 2.
33. K. Boussu, G. Van Baelen, W. Colen, D. Eelen, S. Vanassche, C. Vandecasteele, B. Van der Bruggen, Technical and economical evaluation of water recycling in the carwash industry with membrane processes, Water Sci. Technol., 57 (2008) 1131–1135.
34. E.Z. El-Ashtoukhy, N. Amin, Y. Fouad, Treatment of real wastewater produced from Mobil carwash station using electrocoagulation technique, Environ. Monit. Assess., 187 (2015) 628.
35. R. Etchepare, R. Zaneti, A. Azevedo, J. Rubio, Application of flocculation–flotation followed by ozonation in vehicle wash wastewater treatment/disinfection and water reclamation, Desal. Water Treat., 56 (2015) 1728–1736.
36. A.J. Gomes, K.K. Das, S.A. Jame, D.L. Cocke, Treatment of truck wash water using electrocoagulation, Desal. Water Treat., 57 (2016) 25991–26002.
37. Z.B. Gönder, G. Balcıoğlu, I. Vergili, Y. Kaya, Electrochemical treatment of carwash wastewater using Fe and Al electrode: Techno-economic analysis and sludge characterization, J. Environ. Manage., 200 (2017) 380–390.
38. H.L. Guan, Comparative research on treating vehicle-washing wastewater with two and three-dimensional electrode method, Trans Tech Publ., 777 (2013) 370–374.
39. H.L. Guan, Treatment of Vehicle-Washing Wastewater with Three-dimensional Fluidized Bed Electrode Method of Activated Carbon, In Proceedings of the 2015 International Conference on Water Resources and Environment (Beijing), 2015, pp. 25–28.
40. A. Haddis, T. Getahun, E. Mengistie, A. Jemal, I. Smets, B. Bruggen, Challenges to surface water quality in mid‐sized African cities: conclusions from Awetu‐Kito Rivers in Jimma, south‐west Ethiopia, Water Environ. J., 28 (2014) 173–182.
41. T. Hamada, Y. Miyazaki, Reuse of carwash water with a cellulose acetate ultrafiltration membrane aided by flocculation and activated carbon treatments, Desalination, 169 (2004) 257–267.
42. N.H. Hashim, N. Zayadi, Pollutants Characterization of Car Wash Wastewater, EDP Sciences, 47 (216) 5008.
43. S.-K. Hsu, C.-H. Chen, W.-K. Chang, Reclamation of carwashing wastewater by a hybrid system combining bio-carriers and non-woven membranes filtration, Desal. Water Treat., 34 (2011) 349–353.
44. T. Istirokhatun, P. Destianti, A. Hargianintya, W. Oktiawan, H. Susanto, Treatment of car wash wastewater by UF membranes, AIP Publishing, 1699 (2015) 60025.
45. N. Khondee, S. Tathong, O. Pinyakong, S. Powtongsook, T. Chatchupong, C. Ruangchainikom, E. Luepromchai, Airlift bioreactor containing chitosan-immobilized Sphingobium sp. P2 for treatment of lubricants in wastewater, J. Hazard. Mater., 213 (2012) 466–473.
46. S.A. Kiran, G. Arthanareeswaran, Y.L. Thuyavan, A. Ismail, Influence of bentonite in polymer membranes for effective treatment of carwash effluent to protect the ecosystem, Ecotoxicol. Environ. Saf., 121 (2015) 186–192.
47. H. Messrouk, M. hadj Mahammed, Y. Touil, A. Amrane, Physico-chemical characterization of industrial effluents from the town of Ouargla (South East Algeria), Energy Procedia, 50 (2014) 255–262.
48. S. Mirshahghassemi, B. Aminzadeh, A. Torabian, K. Afshinnia, Optimizing electrocoagulation and electro-Fenton process for treating carwash wastewater, Environ. Eng. Manage. J., 4 (2017) 37–43.
49. R. Mohamed, R.M. Saphira, M. Kassim, A. Hashim, Moringa oleifera and Strychnos potatorum seeds as natural coagulant compared with synthetic common coagulants in treating carwash wastewater: case study, Asian J. Appl. Sci., 2 (2014) 693–700.
50. R. Mohamed, R.M. Saphira, A.I. Kutty, N. Mariam, M. Kassim, A. Hashim, Efficiency of using commercial and natural coagulants in treating carwash wastewater treatment, Aust. J. Basic Appl. Sci., 8 (2014) 227–234.
51. M.J. Mohammadi, J. Salari, A. Takdastan, M. Farhadi, P. Javanmardi, A.R. Yari, S. Dobaradaran, H. Almasi, S. Rahimi, Removal of turbidity and organic matter from carwash wastewater by electrocoagulation process, Desal. Water Treat., 68 (2017) 122–128.
52. A. O’Sullivan, D. Smalley, J. Good, Quantifying the impact of carwashing on water quality and assessing simple treatment strategies, Christchurch, New Zealand, 2011.
53. S. Panpanit, Oily Wastewater Treatment by Coupling Membrane Filtration and Ozonation, Dissertation No. EV-01–2, Asian Institute of Technology, Thailand, 2001.
54. N. Paxéus, Vehicle washing as a source of organic pollutants in municipal wastewater, Water Sci. Technol., 33 (1996) 1–8.
55. A. Pervov, A. Andrianov, T. Gorbunova, A. Bagdasaryan, Membrane technologies in the solution of environmental problems, Pet. Chem., 55 (2015) 879–886.
56. A. Pervov, D. Spitsov, Application of membrane techniques for municipal wastewater treatment and reuse, Inżynieria Ekologiczna, 24 (2011) 107–119.
57. Z. Qamar, S. Khan, A. Khan, M. Aamir, J. Nawab, M. Waqas, Appraisement, source apportionment and health risk of polycyclic aromatic hydrocarbons (PAHs) in vehicle-wash wastewater, Pak. Sci. Total Environ., 605 (2017) 106–113.
58. H. Rubí-Juárez, C. Barrera-Díaz, I. Linares-Hernández, C. Fall, B. Bilyeu, A combined electrocoagulation-electrooxidation process for carwash wastewater reclamation, Int. J. Electrochem. Sci., 10 (2015) 6754–6767.
59. C. Sablayrolles, C. Vialle, C. Vignoles, M. Montréjaud-Vignoles, Impact of carwash discharge on stormwater quality (Toulouse, France), Water Sci. Technol., 62 (2010) 2737–2746.
60. F. Sadat Kamelian, S.M. Mousavi, A. Ahmadpour, V. Ghaffarian, Preparation of acrylonitrile-butadiene-styrene membrane: Investigation of solvent/nonsolvent type and additive concentration, Korean J. Chem. Eng., 31 (2014) 1399–1404.
61. S. Shahidan, M.S. Senin, A.B.A. Kadir, L.H. Yee, N. Ali, In Tilte 2017, EDP Sciences.
62. X. Tan, L. Tang, Application of enhanced coagulation aided by UF membrane for car wash wastewater treatment, IEEE, 16 (2016) 3653–3656.
63. M. Tekere, T. Sibanda, K.W. Maphangwa, An assessment of the physicochemical properties and toxicity potential of carwash effluents from professional carwash outlets in Gauteng Province, South Africa, Environ. Sci. Pollut. Res., 23 (2016) 11876–11884.
64. M.A. Tony, Z. Bedri, Experimental design of photo-Fenton reactions for the treatment of carwash wastewater effluents by response surface methodological analysis, Adv. Environ. Chem., 2 (2014) 1–8.
65. M.A. Tony, P.J. Purcell, Y. Zhao, Oil refinery wastewater treatment using physicochemical, Fenton and photo-Fenton oxidation processes, J. Environ. Sci. Health A, 47 (2012) 435–440.
66. M.A. Tony, P.J. Purcell, Y. Zhao, A.M. Tayeb, M. El-Sherbiny, Photo-catalytic degradation of an oil-water emulsion using the photo-fenton treatment process: effects and statistical optimization, J. Environ. Sci. Health A, 44 (2009) 179–187.
67. W.-K. Tu, C.-C. Chang, C.-Y. Chang, D.-R. Ji, J.-Y. Tseng, C.-Y. Chiu, Y.-H. Chen, C.-F. Chang, Y.H. Yu, Treatment of carwash wastewater via novel technologies for recycling and reutilization, Environ. Eng. Manage. J., 19 (2009) 49–57.
68. B. Van der Bruggen, K. Boussu, I. De Vreese, G. Van Baelen, F. Willemse, D. Goedeme, W. Colen, Industrial process water recycling: principles and examples, Environ. Progr. Sustainable Energy, 24 (2005) 417–425.
69. K.J. Xiang, B.F. Xu, In the analysis about pollutant index of the wastewater originating from small vehicles washing, Appl. Mech. Mater., 556 (2014) 833–836.
70. S. Yasin, T. Iqbal, Z. Arshad, M. Rustam, M. Zafar, Environmental pollution from automobile vehicle service stations, J. Qual. Technol., 8 (2012) 61–70.
71. R. Zaneti, R. Etchepare, J. Rubio, Carwash wastewater reclamation. Full-scale application and upcoming features, Resour. Conserv. Recycl., 55 (2011) 953–959.
72. R. Zaneti, R. Etchepare, J. Rubio, Carwash wastewater treatment and water reuse–a case study, Water Sci. Technol., 67 (2012) 82–88.
73. WHO, Water for Health: Taking Charge, World Health Organization, 2001.
74. Drinking-Water, Fact Sheet. Available at: http://www.who.int/ mediacentre/factsheets/fs391/en/ 2018).
75. M.A. Hanjra, P. Drechsel, J. Mateo-Sagasta, M. Otoo, F. Hernández-Sancho, Assessing the finance and economics of resource recovery and reuse solutions across scales, Wastewater, (2015) 113–136.
76. F. Hernández-Sancho, B. Lamizana-Diallo, J. Mateo-Sagasta, M. Qadir, Economic Valuation of Wastewater: The Cost of Action and the Cost of No Action, Kenya, 2015.
77. R. Zaneti, R. Etchepare, J. Rubio, More environmentally friendly vehicle washes: water reclamation, J. Cleaner Prod., 37 (2012) 115–124.
78. A. Romanova, M. Mahmoodian, M.A. Alani, Influence and interaction of temperature, H2S and pH on concrete sewer pipe corrosion, Int. J. Civil Archit. Struct. Urban Sci. Eng., 8 (2014) 592–595.
79. P.N. Patil, D.V. Sawant, R. Deshmukh, Physico-chemical parameters for testing of water-a review, Int. J. Environ. Sci., 3 (2012) 1194.
80. F. Deluise, L.K. Wang, S.-Y. Chang, Y.-T. Hung, Screening and comminution, Physicochem. Treat. Processes, 3 (2005) 1–19.
81. H. Stonerook, S.A. Hubbs, R. Bruce, I. Somerset, C. Spangler, Understanding Sewage Treatment and Disposal, Volunteers in Technical Assistance, 1984.
82. P. Wongburi, Sustainable Wastewater Treatment Technologies, University of Wisconsin–Madison, Madison, 2017, pp. 100–110.
83. C.H. Koo, A.W. Mohammad, Recycling of oleochemical wastewater for boiler feed water using reverse osmosis membranes—a case study, Desalination, 271 (2011) 178–186.
84. WHO, Guidelines for Drinking-Water Quality, WHO Chronicle, Vol. 38, 2011, pp. 104–108.
85. C.N. Sawyer, Chemistry for Environmental Engineering and Science, McGraw-Hill, 5 (2003) 587590.
86. A. Reyes, M. Letelier, R. De la Iglesia, B. Gonzalez, G. Lagos, Microbiologically induced corrosion of copper pipes in low-pH water, Int. Biodeterior. Biodegrad., 61 (2008) 135–141.
87. D.A. Lytle, M.N. Nadagouda, A comprehensive investigation of copper pitting corrosion in a drinking water distribution system, Corros. Sci., 52 (2010) 1927–1938.
88. N.P. Cheremisinoff, Handbook of Water and Wastewater Treatment Technologies, Butterworth-Heinemann, United Kingdom, 2001.
89. M. Henze, M.C. van Loosdrecht, G.A. Ekama, D. Brdjanovic, Biological Wastewater Treatment, IWA Publishing, United Kingdom, 2008.
90. E.P. Act, Standards for Effluent Discharge Regulations, General notice No. 44 of 2003. 2002.
91. S. Sani, Environmental Quality Act 1974: Then and Now, Institute for Environment and Development, Universiti Kebangsaan Malaysia, Bangi Selangor, 1997.
92. D.L. Corwin, S.M. Lesch, Apparent soil electrical conductivity measurements in agriculture, Comput. Electron. Agric., 46 (2005) 11–43.
93. American Public Health Association, American Water Works Association, W.P.C. Federation, W.E. Federation, Standard Methods for the Examination of Water and Wastewater, American Public Health Association, Vol. 2, United States, 1915. Available at: https://www.google.com/url?sa=t&rct=j&q=&esrc= s&source=web&cd=&cad=rja&uact=8&ved=2ahUKEwiHoq Lx0ZjwAhXTgP0HHRRbDTMQFjAAegQIAxAD&url=https %3A%2F%2Fen.wikipedia.org%2Fwiki%2FUnited_States &usg=AOvVaw0tTp1Zndz6lnSnC8nPG6X_
94. Degremont: Degremont Company, Water Treatment Handbook, Lavoisier Publishing, Paris, 1991, pp. 1–1459.
95. S.P. Phungula, An Evaluation of the Water Quality and Toxicity of Wastewater at Selected Carwash Facilities in Tshwane, Gauteng, (Doctoral Dissertation, University of South Africa), 2016.
96. S. Panpanit, C. Visvanathan, S. Muttamara, Separation of oil– water emulsion from carwashes, Water Sci. Technol., 41 (2000) 109–116.
97. D.M. Anderson, P.M. Glibert, J.M. Burkholder, Harmful algal blooms and eutrophication: nutrient sources, composition, and consequences, Estuaries, 25 (2002) 704–726.
98. J. Abowei, Salinity, dissolved oxygen, pH and surface water temperature conditions in Nkoro River, Niger Delta, Nigeria, Adv. J. Food Sci. Technol., 2 (2010) 36–40.
99. C.E. Mortimer, Chemistry, Wadsworth Publishing Company, 1998, 902 p.
100. V.K. Gupta, I. Ali, T.A. Saleh, A. Nayak, S. Agarwal, Chemical treatment technologies for wastewater recycling—an overview, RSC Adv., 2 (2012) 6380–6388.
101. P. Tri, Oily Wastewater Treatment by Membrane Bioreactor Process Coupled with Biological Activated Carbon Process, AIT, Bangkok, Thailand, 2002.
102. S. Facchin, P.D.D. Alves, F. de Faria Siqueira, T.M. Barroca, J.M.N. Victória, E. Kalapothakis, Biodiversity and secretion of enzymes with potential utility in wastewater treatment, Open J. Ecol., 3 (2013) 34.
103. P.S. Chauhan, A. Choubey, Z. Zhong, M.G. Pecht, Copper Wire Bonding, In Copper Wire Bonding, Springer, 2014, pp. 1–9.
104. A. International, AIH Committee, AIAPD Committee, Metals Handbook: Properties and Selection, ASM International, 2, United States, 1990, pp. 94–140.
105. F. Abad, R. Pinto, J. Diez, A. Bosch, Disinfection of human enteric viruses in water by copper and silver in combination with low levels of chlorine, Appl. Environ. Microbiol., 60 (1994) 2377–2383.
106. B. Pyle, S. Broadaway, G. McFeters, Efficacy of copper and silver ions with iodine in the inactivation of Pseudomonas cepacia, J. Appl. Microbiol., 72 (1992) 71–79.
107. J. Ma, W. Liu, Effectiveness and mechanism of potassium ferrate (VI) preoxidation for algae removal by coagulation, Water Res., 36 (2002) 871–878.
108. I.H. Scheinberg, D. Gitlin, Deficiency of ceruloplasmin in patients with hepatolenticular degeneration (Wilson’s disease), Science, 116 (1952) 484–485.
109. R.B. Parker, The New Cold-Molded Boatbuilding: from Lofting to Launching, WoodenBoat Books, 2005.
110. V. Rich, The International Lead Trade, Woodhead Publishing, 2014.
111. I. Thornton, R. Rautiu, S. Brush, Lead-the Facts, IC Consultants Ltd., London, UK, 2001.
112. E.P. Becker, Trends in tribological materials and engine technology, Tribol. Int., 37 (2004) 569–575.
113. G. Guinther, Airborne Engine Additive Delivery System, Google Patents, 2018.
114. O. Yamauchi, A. Sigel, H. Sigel, R. KO Sigel, Lead: its effects on environment and health. Volume 17 of Metal Ions in Life Sciences, Transition Metal Chem., 42 (2017) 575–577.
115. A.L. Wani, A. Ara, J.A. Usmani, Lead toxicity: a review, Interdiscip. Toxicol., 8 (2015) 55–64.
116. E.E. Beier, J.A. Inzana, T.J. Sheu, L. Shu, J.E. Puzas, R.A. Mooney, Effects of combined exposure to lead and high-fat diet on bone quality in juvenile male mice, Environ. Health Perspect., 123 (2015) 935.
117. L. Niu, Z. Jiang, G. Li, C. Gu, J. Lian, A study and application of zinc phosphate coating on AZ91D magnesium alloy, Surf. Coat. Technol., 200 (2006) 3021–3026.
118. M. Fourez, F. Gheno, P.E. White, The application of zincaluminium flake non-electroytic surface coatings, Trans. IMF, 71 (1993) 21–25.
119. A. Kołodziejczak-Radzimska, T. Jesionowski, Zinc oxide— from synthesis to application: a review, Materials, 7 (2014) 2833–2881.
120. J. Foster, F.D. JUN, Role of zinc in metabolism, Nature, 166 (1950) 833.
121. M.E. Wastney, W.A. House, R.M. Barnes, K.N.S. Subramanian, Kinetics of zinc metabolism: variation with diet, genetics and disease, J. Nutr., 130 (2000) 1355S–1359S.
122. L.M. Plum, L. Rink, H. Haase, The essential toxin: impact of zinc on human health, Int. J. Environ. Res. Public Health, 7 (2010) 1342–1365.
123. C.F. Mills, Zinc in Human Biology, Springer Science & Business Media, German, 2013.
124. M. Al-Yousuf, M. El-Shahawi, S. Al-Ghais, Trace metals in liver, skin and muscle of Lethrinus lentjan fish species in relation to body length and sex, Sci. Total Environ., 256 (2000) 87–94.
125. J. Bowness, R. Morton, Distribution of copper and zinc in the eyes of fresh-water fishes and frogs. Occurrence of metals in melanin fractions from eye tissues, Biochem. J., 51 (1952) 530.
126. E.J. Lavernia, J. Ayers, T.S. Srivatsan, Rapid solidification processing with specific application to aluminium alloys, Int. Mater. Rev., 37 (1992) 1–44.
127. A. Heinz, A. Haszler, C. Keidel, S. Moldenhauer, R. Benedictus, W.S. Miller, Recent development in aluminium alloys for aerospace applications, Mater. Sci. Eng. A, 280 (2000) 102–107.
128. C.T. Driscoll Jr, J.P. Baker, J.J. Bisogni Jr, C.L. Schofield, Effect of aluminium speciation on fish in dilute acidified waters, Nature, 284 (1980) 161.
129. G.D. Howells, D.J. Brown, Sadler, K. Effects of acidity, calcium, and aluminium on fish survival and productivity—a review, J. Sci. Food Agric., 34 (1983) 559–570.
130. H. Sigel, R.K. Sigel, A. gibt es Überschneidungen, Nickel and its surprising impact in nature, Angew. Chem., 120 (2008) 836–837.
131. A. Sigel, H. Sigel, R.K. Sigel, Nickel and Its Surprising Impact in Nature, John Wiley & Sons, West Sussex, England PO19 8SQ England, Vol. 5, 2007.
132. J. Godt, F. Scheidig, C. Grosse-Siestrup, V. Esche, P. Brandenburg, A. Reich, D.A. Groneberg, The toxicity of cadmium and resulting hazards for human health, J. Occup. Med. Toxicol., 1 (2006) 22.
133. A. Bernard, Cadmium and its adverse effects on human health, Indian J. Med. Res., 128 (2008) 557.
134. A.E. Sahmoun, L.D. Case, S.A. Jackson, G.G. Schwartz, Cadmium and prostate cancer: a critical epidemiologic analysis, Cancer Invest., 23 (2005) 256–263.
135. T. Bahadir, G. Bakan, L. Altas, H. Buyukgungor, The investigation of lead removal by biosorption: an application at storage battery industry wastewaters, Enzyme Microb. Technol., 41 (2007) 98–102.
136. V.K. Gupta, C.K. Jain, I. Ali, M. Sharma, V.K. Saini, Removal of cadmium and nickel from wastewater using bagasse fly ash—a sugar industry waste, Water Res., 37 (2003) 4038–4044.
137. A. Patwardhan, Industrial Wastewater Treatment, PHI Learning Pvt. Ltd., 2017.
138. A.S. Prasad, Essential and Toxic Element: Trace Elements in Human Health and Disease, Elsevier, Netherlands, 2013.
139. S. Gettier, D. Martens, T. Brumback, Timing of foliar manganese application for correction of manganese deficiency in soybean, Agron. J., 77 (1985) 627–630.
140. M. Saber, M.a. Yousry, M. Kabesh, Effect of manganese application on the activity of phosphate-dissolving bacteria in a calcareous soil cultivated with pea plants, Plant Soil, 47 (1977) 335–339.
141. S.D. Haigh, A review of the interaction of surfactants with organic contaminants in soil, Sci. Total Environ., 185 (1996) 161–170.
142. S.S. Talmage, Environmental and Human Safety of Major Surfactants: Alcohol Ethoxylates and Alkylphenol Ethoxylates, CRC Press, United States, 1994.
143. A. Sivak, M. Goyer, J. Perwak, P. Thayer, Environmental and Human Health Aspects of Commercially Important Surfactants, In Solution Behavior of Surfactants, Springer, 1982, pp. 161–188.
144. A. Wilkinson, A. McNaught, IUPAC Compendium of Chemical Terminology, (the” Gold Book”), International Union of Pure and Applied Chemistry, 1997.
145. U. Peters, F. Nierlich, E. Schulte‐Körne, M. Sakuth, R. Deeb, M. Laugier, M. Suominen, M. Kavanaugh, Methyl Tert‐ Butyl Ether, Ullmann’s Encyclopedia of Industrial Chemistry, 2003.
146. C.S. Chen, Y.C. Hseu, S.H. Liang, J.-Y. Kuo, S.C. Chen, Assessment of genotoxicity of methyl-tert-butyl ether, benzene, toluene, ethylbenzene, and xylene to human lymphocytes using comet assay, J. Hazard. Mater., 153 (2008) 351–356.
147. F. Colombo, L. Cori, L. Dalloro, P. Delogu, Equilibrium constant for the methyl tert-butyl ether liquid-phase synthesis using UNIFAC, Ind. Eng. Chem. Fundam., 22 (1983) 219–223.
148. C. Culberson, A. Johnson, Substitution of methyl tert.- butyl ether for diethyl ether in the standardized thin-layer chromatographic method for lichen products, J. Chromatogr., 238 (1982) 483–487.
149. M. Rossberg, W. Lendle, G. Pfleiderer, A. Tögel, E.-L. Dreher, E. Langer, H. Rassaerts, P. Kleinschmidt, H. Strack, R. Cook, U. Beck, K.-A. Lipper, T.R. Torkelson, E. Löser, K.K. Beutel, T. Mann, Chlorinated Hydrocarbons, In Ullmann’s Encyclopedia of Industrial Chemistry, Wiley-VCH Verlag GmbH & Co. KGaA, 2000.
150. UNEP Chemicals, Guidelines for the Identification of PCBs and Materials Containing PCBs, First Issue, August 1999, United Nationas Environmental Program(UNEP) Chemicals web page. Available at: http://www. chem. unep. ch/pops.
151. T. Godish, Indoor Environmental Quality, CRC Press, United States, 2016.
152. K. Pivnenko, M.E. Olsson, R. Götze, E. Eriksson, T.F. Astrup, Quantification of chemical contaminants in the paper and board fractions of municipal solid waste, Waste Manage., 51 (2016) 43–54.
153. K. Gehle, Agency for Toxic Substances and Disease Registry (ATSDR) Case Studies in Environmental Medicine Toxicity of Polycyclic Aromatic Hydrocarbons (PAHs), USA Department of Health and Human Services Agency for Toxic Substances and Disease Registry Division of Toxicology and Environmental Medicine, United States, 2009.
154. C.E. Cerniglia, Biodegradation of Polycyclic Aromatic Hydrocarbons, In Microorganisms to Combat Pollution, Springer, 1992, pp. 227–244.
155. K. Lah, H. Yagi, Polycyclic Aromatic Hydrocarbons, Department of Biochemistry and Drug Huffmann-La Roch Inc., Nutley, New Jersey, 2011.
156. H. Soclo, P. Garrigues, M. Ewald, Origin of polycyclic aromatic hydrocarbons (PAHs) in coastal marine sediments: case studies in Cotonou (Benin) and Aquitaine (France) areas, Mar. Pollut. Bull., 40 (2000) 387–396.
157. J. Zhang, G. Liu, R. Wang, H. Huang, Polycyclic aromatic hydrocarbons in the water-SPM-sediment system from the middle reaches of Huai River, China: distribution, partitioning, origin tracing and ecological risk assessment, Environ. Pollut., 230 (2017) 61–71.
158. É. Euvrard, C. Druart, N. Morin-Crini, G. Crini, Monitoring and origin of polycyclic aromatic hydrocarbons (PAHs) in effluents from a surface treatment industry, Polycyclic Aromat. Compd., 5 (2017) 1–10.
159. H.I. Abdel-Shafy, M.S.M. Mansour, A review on polycyclic aromatic hydrocarbons: source, environmental impact, effect on human health and remediation, Egypt. J. Petrol., 25 (2016) 107–123.
160. J.N. Hao, B. Yan, Determination of urinary 1‐hydroxypyrene for biomonitoring of human exposure to polycyclic aromatic hydrocarbons carcinogens by a lanthanide‐functionalized metal‐organic framework sensor, Adv. Funct. Mater., 27 (2017) 1603856.
161. D.K. Singh, K. Kawamura, A. Yanase, L.A. Barrie, Distributions of polycyclic aromatic hydrocarbons, aromatic ketones, carboxylic acids, and trace metals in Arctic aerosols: longrange atmospheric transport, photochemical degradation/ production at Polar sunrise, Environ. Sci. Technol., 51 (2017) 8992–9004.
162. S. Marzooghi, D.M. Di Toro, A critical review of polycyclic aromatic hydrocarbon phototoxicity models, Environ. Toxicol. Chem., 36 (2017) 1138–1148.