References

  1. G. Tai, Y. Qu, Y. Wang, M. Wu, Research and application of on-line detection and control technology for fracturing fluid, Miner. Metall., 28 (2019) 89–93.
  2. A.C. Ground Water Protection Council, Modern Shale Gas Development in the United States: A Primer, United States Department of Energy, Office of Fossil Energy, Washington, D.C., 2009.
  3. K. Wang, T. Li, G. Lv, Research progresses on treatment technologies of oilfield fracturing flow-back fluid, Chem. Eng. Equip., 2 (2019) 246–247.
  4. Y. Liu, W. Chen, S. Zhang, D.P. Shi, M.J. Zhu, Assessment of gas production and electrochemical factors for fracturing flowback fluid treatment in Guangyuan oilfield, Environ. Eng. Res., 24 (2018) 521–528.
  5. J. Wang, J. Li, K. Lei, X. Zhang, P. Lu, L. Qiang, S. Wei, Research progress in fracturing flow-back fluid treatment technology, Appl. Chem. Ind., 46 (2017) 1414–1416+1423.
  6. Y. Gao, J. Zhao, D. Ji, Two-stage oxidation-coagulation treatment on the recycling of fracturing flow-back fluid, Technol. Water Treat., 41 (2015) 115–118.
  7. J. Du, C. Qu, T. Yu, Adsorption of boron in fracturing flow-back fluid by XSC-700 resin, Chem. Eng. (China), 47 (2019) 29–34.
  8. J. Wu, C. Li, M. Wang, Z. Xiao, Experimental research on the treatment of fracturing flowback fluid by the distillation method, Ind. Water Treat., 37 (2017) 37–41.
  9. H. Niu, B. Jiang, Y. Du, Study on micro-electrolytic treatment of fracturing flow-back fluid in west sichuan oilfield,
    J. Chongqing Univ. Sci. Technol., Nat. Sci. Ed., 13 (2011) 100–102.
  10. C. Geng, R. Qiao, G. Chen, B. Yu, H. Li, Y. Wang, D. Xu, S. Yang, Y. Tian, The treatment technologies of hydraulic fracturing fluid flowback of shale gas, Energy Environ. Prot., 30 (2016) 12–16+56.
  11. J. Song, Experiment on oxidation treatment of fracturing flowback fluid from a gas field, Environ. Prot. Oil Gas Fields, 29 (2019) 12–15+18+60.
  12. A. Chen, B. Wang, H. Ren, Composite experimental research on fracturing liquid of
    preoxidation-coagu-flocculation-ozone deeply oxidation process, Sci. Technol. Chem. Ind., 19 (2011) 26–30.
  13. Z. Hu, T. Zhang, Z. Zhu, P. Luo, T. Huang, Research on the treatment of fracturing flow-back fluid by the coagulationadvanced oxidation combined technology, Ind. Water Treat., 38 (2018) 81–84+94.
  14. H. Ren, J. Wang, W. Zhu, T. Yu, Study on scale prevention of shale gas fracturing backflow fluid treated by ceramic membrane, Ind. Water Treat., 40 (2020) 19–22.
  15. S. Wang, X. Zhao, Z. Li, Q. Yu, Research progresses on treatment technologies of oilfield fracturing flow-back fluid, Environ. Prot. Chem. Ind., 36 (2016) 493–499.
  16. M. Dolatabadi, M. Mehrabpour, M. Esfandyari, S. Ahmadzadeh, Adsorption of tetracycline antibiotic onto modified zeolite: experimental investigation and modeling, MethodsX, 7 (2020) 100885, doi: 10.1016/j.mex.2020.100885.
  17. J. Wu, W. Wu, Y. Yan, M. Wang, Z. Xiao, Research on the treatment status and difficulties of fracturing flowback, Technol. Water Treat., 44 (2018) 12–16.
  18. W. Chen, J. Zhang, J. Zhu, G. Tan, F. Meng, B. Jing, R. Li, Research progress in the composite process of advanced treatment of oil field fracturing flow back liquid, Ind. Water Treat., 36 (2016) 10–14.
  19. D. Zhou, X. Shi, B. Li, F. Wang, Oil and gas field acidification and fracturing flow back treatment technology, Petrochem. Ind. Appl., 37 (2018) 97–99.
  20. M. Mousazadeh, Z. Naghdali, Z. Al-Qodah, S.M. Alizadeh, E.K. Niaragh, S. Malekmohammadi, P.V. Nidheesh,
    E.P. Roberts, M. Sillanpää, M.M. Emamjomeh, A systematic diagnosis of state of the art in the use of electrocoagulation as a sustainable technology for pollutant treatment: an updated review, Sustainable Energy Technol. Assess., 47 (2021) 101353, doi: 10.1016/j.seta.2021.101353.
  21. W. Chen, P. Mei, Electrochemical Technology for Environmental Pollution Control, Petroleum Industry Press, Beijing, 2013.
  22. S. Ahmadzadeh, A. Kassim, M. Rezayi, Y. Abdollahi, G.H. Rounaghi, A conductometric study of complexation reaction between Meso-octamethylcalix[4]pyrrole with titanium cation in acetonitrile–ethanol binary mixtures, Int. J. Electrochem. Sci., 6 (2011) 4749–4759.
  23. S. Ahmadzadeh, M. Rezayi, H. Karimi-Maleh, Y. Alias, Conductometric measurements of complexation study between 4-isopropylcalix[4]arene and Cr3+ cation in THF–DMSO binary solvents, Measurement, 70 (2015) 214–224.
  24. J.N. Hakizimana, B. Gourich, M. Chafi, Y. Stiriba, C. Vial, P. Drogui, J. Naja, Electrocoagulation process in water treatment: a review of electrocoagulation modeling approaches, Desalination, 404 (2017) 1–21.
  25. M. Dolatabadi, T. Świergosz,S. Ahmadzadeh, Electro-Fenton approach in oxidative degradation of dimethyl phthalate – the treatment of aqueous leachate from landfills, Sci. Total Environ., 772 (2021) 145323, doi:10.1016/j.scitotenv.2021.145323.
  26. T. Karchiyappan, A review on hydrogen energy production from electrochemical system: benefits and challenges, Energy Sources, Part A, 41 (2019) 902–909.
  27. O. Sahu, B. Mazumdar, P.K. Chaudhari, Treatment of wastewater by electrocoagulation: a review, Environ. Sci. Pollut. Res., 21 (2014) 2397–2413.
  28. S. Ahmadzadeh, F. Karimi, N. Atar, E.R. Sartori, E. Faghih- Mirzaei, E. Afsharmanesh, Synthesis of CdO nanoparticles using direct chemical precipitation method: fabrication of novel voltammetric sensor for square wave voltammetry determination of chlorpromazine in pharmaceutical samples, Inorg. Nano-Metal Chem., 47 (2017) 347–353.
  29. R. Mores, H. Treichel, C.A. Zakrzevski, A. Kunz, J. Steffens, R.M. Dallago, Remove of phosphorous and turbidity of swine wastewater using electrocoagulation under continuous flow, Sep. Purif. Technol., 171 (2016) 112–117.
  30. M. Shen, Y. Zhang, E. Almatrafi, T. Hu, C. Zhou, B. Song, Z. Zeng, G. Zeng, Efficient removal of microplastics from wastewater by an electrocoagulation process, Chem. Eng. J., 428 (2022) 131161, doi: 10.1016/j.cej.2021.131161.
  31. M. Mousazadeh, S.M. Alizadeh, Z. Frontistis, I. Kabdaşlı, E. Karamati Niaragh, Z. Al Qodah, Z. Naghdali, A.E.D. Mahmoud, M.A. Sandoval, E. Butler, M. Mahdi Emamjomeh, Electrocoagulation as a promising defluoridation technology from water: a review of state of the art of removal mechanisms and performance trends, Water, 13 (2021) 656, doi: 10.3390/ w13050656.
  32. J.-W. Feng, Y.-B. Sun, Z. Zheng, J.-B. Zhang, L.I. Shu, Y.-C. Tian, Treatment of tannery wastewater by electrocoagulation, J. Environ. Sci. (China), 19 (2007) 1409–1415.
  33. F.L. Lobo, H. Wang, T. Huggins, J. Rosenblum, K.G. Linden, Z.J. Ren, Low-energy hydraulic fracturing wastewater treatment via AC powered electrocoagulation with biochar, J. Hazard. Mater., 309 (2016) 180–184.
  34. Y. Li, T. Zhang, Y. Li, W. Tang, Treatment of fracturing flow-back fluid by electrochemistry technology and reconfiguration of polymer fracturing fluid, Mod. Chem. Ind., 39 (2019) 186–190.
  35. Y. Wang, Q. Li, S. Huang, Y. Wan, Y. Qu, M. Wu, Development and application of electrochemical treatment device for fracturing flowback fluid, Mod. Chem. Ind., 38 (2018) 171–174.
  36. Y. Zhang, X. Cui, S. Liu, W. Zhu, X. Han, Y. Wang, Treatment of oil field fracturing flowback wastewater based on 3D/O3 process, China Environ. Sci., 40 (2020) 2270–2275.
  37. Y. Xu, Y. Jin, L. Chen, H. Liu, M. Zhang, Pilot test study on treatment of fracturing fluid by three-dimensional electrocatalytic oxidation process, Nat. Gas Oil., 38 (2020) 100–104.
  38. Y. Wang, X. Wu, J. Yi, J. Dai, New three-dimensional electrochemical oxidation system for treatment of fracturing flow-back fluid, Environ. Prot. Chem. Ind., 38 (2018) 251–255.
  39. K.A. Sitterley, J. Rosenblum, B. Ruyle, R. Keliher, K.G. Linden, Factors impacting electrocoagulation treatment of hydraulic fracturing fluids and removal of common fluid additives and scaling ions, J. Environ. Chem. Eng., 8 (2020) 103728, doi: 10.1016/j.jece.2020.103728.
  40. Y. Liu, W. Chen, D. Wu, Advances on the effect and harm of gas generation in electrochemical treatment process of wastewater, Appl. Chem. Ind., 47 (2018) 2235–2241.
  41. GB/T 6920-1986, Water Quality–Determination of pH Value – Glass Electrode Method, Standards Press of China, Beijing, 1987.
  42. Z. Fanliang, L. Xiantao, Determination of the colority of water samples by spectrophotometry, 2006, pp. 69–72+77.
  43. HJ 501-2009, Water Quality–Determination of Total Organic Carbon-Combustion Oxidation Nondispersive Infrared Absorption Method, Standards Press of China, Beijing, 2009.
  44. N. Gros, M.F. Camões, C. Oliveira, M. Silva, Ionic composition of seawaters and derived saline solutions determined by ion chromatography and its relation to other water quality parameters, J. Chromatogr. A, 1210 (2008) 92–98.
  45. HJ 637-2018, Water Quality–Determination of Petroleum, Animal Fats and Vegetable Oils–Infrared Spectrophotometry, Standards Press of China, Beijing, 2018.
  46. HJ 828-2017, Water Quality–Determination of the Chemical Oxygen Demand–Dichromate Method, Standards Press of China, Beijing, 2017.
  47. HJ1075-2019, Water Quality–Determination of Turbidity– Nephelometry, Standards Press of China, Beijing, 2020.
  48. M.M. Emamjomeh, H.A. Jamali, Z. Naghdali, M. Mousazadeh, Carwash wastewater treatment by the application of an environmentally friendly hybrid system: an experimental design approach, Desal. Water Treat., 160 (2019) 171–177.
  49. M. Dolatabadi, M.T. Ghaneian, C. Wang, S. Ahmadzadeh, Electro-Fenton approach for highly efficient degradation of the herbicide 2,4-dichlorophenoxyacetic acid from agricultural wastewater: process optimization, kinetic and mechanism, J. Mol. Liq., 334 (2021) 116116, doi: 10.1016/j.molliq.2021.116116.
  50. T. Ntambwe Kambuyi, F. Eddaqaq, A. Driouich, B. Bejjany, B. Lekhlif, H. Mellouk, K. Digua, A. Dani, Using response surface methodology (RSM) for optimizing turbidity removal by electrocoagulation/electro-flotation in an internal loop airlift reactor, Water Supply, 19 (2019) 2476–2484.
  51. V. Preethi, S.T. Ramesh, R. Gandhimathi, P.V. Nidheesh, Optimization of batch electrocoagulation process using Box– Behnken experimental design for the treatment of crude vegetable oil refinery wastewater, J. Dispersion Sci. Technol., 41 (2019) 592–599.
  52. M. Behbahani, M.M. Alavi, M. Arami, A comparison between aluminum and iron electrodes on removal of phosphate from aqueous solutions by electrocoagulation process, Int. J. Environ. Res., 5 (2011) 403–412.
  53. D. Sharma, P.K. Chaudhari, A.K. Prajapati, Removal of chromium(VI) and lead from electroplating effluent using electrocoagulation, Sep. Sci. Technol., 55 (2020) 321–331.
  54. S. Badakhshan, S. Ahmadzadeh, A. Mohseni-Bandpei, M. Aghasi, A. Basiri, Potentiometric sensor for iron(III) quantitative determination: experimental and computational approaches, BMC Chem., 13 (2019) 1–12.
  55. M. Fouladgar, S. Ahmadzadeh, Application of a nanostructured sensor based on NiO nanoparticles modified carbon paste electrode for determination of methyldopa in the presence of folic acid, Appl. Surf. Sci., 379 (2016) 150–155.
  56. R. Mohtashami, J.Q. Shang, Electroflotation for treatment of industrial wastewaters: a focused review, Environ. Process., 6 (2019) 325–353.
  57. C. Ding, H. Zeng, Y. Huang, F. Peng, Z. Xu, Study on the decolorizaton of simulated azo dye wastewater with electro coagulation method, Text. Aux., 29 (2012) 39–41.
  58. G. Zhang, S. Gong, F. Wu, S. Yang, L. Liu, Study on optimum parameter for turbidity removal in rainwater collection by electro-coagulation in northwest region, J. Water Resour. Water Eng., 23 (2012) 38–41.
  59. I. Zongo, J. Leclerc, H.A. Maiga, J. Wéthé, F. Lapicque, Removal of hexavalent chromium from industrial wastewater by electrocoagulation: a comprehensive comparison of aluminium and iron electrodes, Sep. Purif. Technol., 66 (2009) 159–166.
  60. A. Sarpola, V. Hietapelto, J. Jalonen, J. Jokela, R.S. Laitinen, Identification of the hydrolysis products of AlCl3·6H2O by electrospray ionization mass spectrometry, J. Mass Spectrom., 39 (2004) 423–430.
  61. M. Rezayi, L.Y. Heng, A. Kassim, S. Ahmadzadeh, Y. Abdollahi, H. Jahangirian, Immobilization of tris(2 pyridyl) methylamine in a PVC-membrane sensor and characterization of the membrane properties, Chem. Cent. J., 6 (2012) 1–6.
  62. D. Li, C. Wang, X. He, R. Wang, N. Zhao, L. Huang, Y. Qian, Removal of ammonia from micro-polluted water by electrochemical oxidation process, Chin. J. Environ. Eng., 6 (2012) 1553–1558.
  63. S.D. Ashrafi, G.H. Safari, K. Sharafi, H. Kamani, J. Jaafari, Adsorption of 4-nitrophenol on calcium alginate-multiwall carbon nanotube beads: modeling, kinetics, equilibriums and reusability studies, Int. J. Biol. Macromol., 185 (2021) 66–76.
  64. J. Jaafaria, K. Yaghmaeiana, Response surface methodological approach for optimizing heavy metal biosorption by the bluegreen alga Chroococcus disperses, Desal. Water Treat., 142 (2019) 225–234.