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Issue
Korean Journal of Chemical Engineering,
Vol.34, No.11, 2999-3008, 2017
Electrodegradation of tetracycline using stainless steel net electrodes: Screening of main effective parameters and interactions by means of a two-level factorial design
Foroughi M, Arezoomand HRS, Rahmani AR, Asgari G, Nematollahi D, Yetilmezsoy K, Samarghandi MR
Performance of electrodegradation process using stainless steel net electrodes was explored for removal of tetracycline (TC) from synthetic wastewater in a laboratory batch study. Main effects of various operating parameters, such as initial TC concentration (20 and 100mg/L), reaction pH (3.0 and 9.0), current density (4.1 and 17.1mA/cm2), agitation speed (250 and 750 rpm), and electrolysis time (20, 50, and 80 min), and their interactions on the TC removal efficiency, were optimized by means of a five-factor and two-level factorial experimental design methodology. The significance of responses obtained from the proposed design (sixteen experimental runs under batch mode conditions) was statistically evaluated by preparing a Pareto chart, half-normal probability plot, and plots of main effects and their interactions (herein referred to as Factions) within the framework of the analysis of variance (ANOVA). The statistical results corroborated with 95% certainty that TC concentration, pH, and current density showed the largest effects (absolute values) on the TC removal efficiency. Besides the most effective Factions, a sodium sulfate (used as supporting electrolyte) dose of 1 g/200 cc was determined as the optimum value for the studied process. Under the conditions of an initial TC concentration=20 mg/L, a reaction pH=3.0, current density=17.1mA/cm2, an agitation speed=250 rpm, and an electrolysis time=20min, about 70% of TC could be successfully removed from the simulated wastewater. Findings of this experimental study clearly confirmed the applicability of the electrodegradation process for the removal of a broad spectrum antibacterial agent like TC, and also demonstrated the effectiveness of the factorial design methodology before transferring the obtained experimental knowledge for a full-scale facility.
Keywords: Electrodegradation; Screening; Factorial Experimental Design; Stainless Steel Nets; Supporting Electrolyte, Tetracycline
[References]
  1. Zhang H, Liu P, Feng Y, Yang F, Marine Pollution Bulletin, 73, 282, 2013
  2. Hou GY, Hao XY, Zhang R, Wang J, Liu RT, Liu CG, Bioresour. Technol., 212, 20, 2016
  3. Rodriguez-Mozaz S, Chamorro S, Marti E, Huerta B, Gros M, Sanchez-Melsio A, Borrego CM, Barcelo D, Balcazar JL, Water Res., 69, 234, 2015
  4. Garcia-Rodriguez A, Matamoros V, Fontas C, Salvado V, Chemosphere, 90, 2297, 2013
  5. Hou LW, Zhang H, Xue XF, Sep. Purif. Technol., 84, 147, 2012
  6. Brinzila CI, Pacheco MJ, Ciriaco L, Ciobanu RC, Lopes A, Chem. Eng. J., 209, 54, 2012
  7. Yi QZ, Gao YX, Zhang H, Zhang HF, Zhang Y, Yang M, Chem. Eng. J., 300, 139, 2016
  8. Ou J, Mei M, Xu X, J. Solid State Chem., 238, 182, 2016
  9. Li JH, Han MS, Guo Y, Wang F, Meng LJ, Mao DJ, Ding SS, Sun C, Appl. Catal. A: Gen., 524, 105, 2016
  10. Liu Q, Zheng Y, Zhong L, Cheng X, J. Environ. Sci., 28, 29, 2015
  11. Norvill ZN, Toledo-Cervantes A, Blanco S, Shilton A, Guieysse B, Munoz R, Bioresour. Technol., 232, 35, 2017
  12. Zhu XD, Liu YC, Qian F, Zhou C, Zhang SC, Chen JM, Bioresour. Technol., 154, 209, 2014
  13. Teh CY, Budiman PM, Shak KPY, Wu TY, Ind. Eng. Chem. Res., 55(16), 4363, 2016
  14. Yan L, Wang YF, Li J, Ma HZ, Liu HJ, Li T, Zhang YJ, Desalination, 341, 87, 2014
  15. Ferrag-Siagh F, Fourcade F, Soutrel I, Ait-Amar H, Djelal H, Amrane A, J. Chem. Technol. Biotechnol., 88(7), 1380, 2013
  16. Oturan N, Wu J, Zhang H, Sharma VK, Oturan MA, Appl. Catal. B: Environ., 140, 92, 2013
  17. Duan F, Li Y, Cao H, Wang Y, Crittenden JC, Zhang Y, Chemosphere, 125, 205, 2015
  18. Daghrir R, Drogui P, Tshibangu J, Sep. Purif. Technol., 131, 79, 2014
  19. Zheng SQ, Yang FF, Chen SL, Liu L, Xiong Q, Yu T, Zhao F, Schroder U, Hou HQ, J. Power Sources, 284, 252, 2015
  20. Yuksel E, Eyvaz M, Gurbulak E, Environ. Prog., 32, 60, 2013
  21. Pulkka S, Martikainen M, Bhatnagar A, Sillanpaa M, Sep. Purif. Technol., 132, 252, 2014
  22. Brillas E, Sires I, TrAC Trends in Analytical Chemistry, 70, 112, 2015
  23. Gerayeli F, Ghojavand F, Mousavi SM, Yaghmaei S, Amiri F, Sep. Purif. Technol., 118, 151, 2013
  24. Sharif KM, Rahman MM, Azmir J, Mohamed A, Jahurul MHA, Sahena F, Zaidul ISM, J. Food Eng., 124, 105, 2014
  25. Wong WH, Lee WX, Ramanan RN, Tee LH, Kong KW, Galanakis CM, Sun J, Prasad KN, Ind. Crop. Prod., 63, 238, 2015
  26. Huyskens C, Helsen J, de Haan AB, Desalination, 328, 8, 2013
  27. Wu TY, Mohammad AW, Jahim JM, Anuar N, J. Chem. Technol. Biotechnol., 84(9), 1390, 2009
  28. Shak KPY, Wu TY, Ind. Crop. Prod., 76, 1169, 2015
  29. Samarghandi MR, Khiadani M, Foroughi M, Nasab HZ, Environ. Sci. Pollut. Res., 23, 887, 2016
  30. Sepehr MN, Yetilmezsoy K, Marofi S, Zarrabi M, Ghaffari HR, Fingas M, Foroughi M, J. Taiwan Inst. Chem. Eng., 45, 2786, 2014
  31. Shokoohi R, Asgari G, Leili M, Khiadani M, Foroughi M, Hemmat MS, Int. J. Environ. Sci. Technol., 14, 841, 2017
  32. Zhang L, Song XY, Liu XY, Yang LJ, Pan F, Lv JN, Chem. Eng. J., 178, 26, 2011
  33. Yehya T, Chafi M, Balla W, Vial C, Essadki A, Gourich B, Sep. Purif. Technol., 132, 644, 2014
  34. Khiadani M, Foroughi M, Amin MM, Desalin. Water Treat., 52, 678, 2014
  35. Nidheesh PV, Gandhimathi R, Desalination, 299, 1, 2012
  36. Zheng T, Wang Q, Shi Z, Fang Y, Shi S, Wang J, Wu C, J. Environ. Sci., 50, 21, 2016
  37. Benredouane S, Berrama T, Doufene N, Chemometrics Intell. Lab. Syst., 155, 128, 2016
  38. David C, Arivazhagan M, Tuvakara F, Ecotox. Environ. Safe., 121, 142, 2015
  39. Govindan K, Noel M, Mohan R, J. Water Process Eng., 6, 58, 2015
  40. Ezechi EH, Isa MH, bin Mohamed Kutty SR, Ahmed Z, J. Environ. Chem. Eng., 3, 1962, 2015
  41. Jeon YS, Yang JS, Park ER, Yang JW, Baek K, J. Taiwan Inst. Chem. Eng., 64, 142, 2016
  42. Gerek EE, Yılmaz S, Koparal AS, Gerek ON, J. Water Process Eng., (2017) (In Press, Corrected Proof).
  43. Liakos TI, Sotiropoulos S, Lazaridis NK, J. Environ. Chem. Eng., 5, 699, 2017
  44. Long YJ, Li HN, Xing X, Ni JR, Chem. Eng. J., 325, 360, 2017
  45. Zhang C, Jiang YH, Li YL, Hu ZX, Zhou L, Zhou MH, Chem. Eng. J., 228, 455, 2013
  46. Kakavandi B, Takdastan A, Jaafarzadeh N, Azizi M, Mirzaei A, Azari A, J. Photochem. Photobiol. A-Chem., 314, 178, 2016
  47. Design Expert Software, In: Trial Version 8.0.7.1 User’s Guide (2011).
  48. Okogbenin EA, Okogbenin OB, Obibuzor JU, Emoghene AO, Int. J. Stat. Appl., 4, 117, 2014
  49. Eigenvector Documentation Wiki (2014), Half-normal probability plot, http://wiki.eigenvector.com/index.php?title=Half-Normal_Probability_Plot. Accessed in July 2017.
  50. Dholariya YN, Bansod YB, Vora RM, Mittal SS, Shirsat AE, Bhingare CL, Int. J. Pharm., 4, 93, 2014
  51. Gonzalez T, Dominguez JR, Palo P, Sanchez-Martin J, Cuerda-Correa EM, Desalination, 280(1-3), 197, 2011
  52. Banala VT, Srinivasan B, Rajamanickam D, Veerbadraiah BB, Varadarajan M, ISRN Pharmaceutics, 1 (2013).
  53. Yetilmezsoy K, Demirel S, Vanderbei RJ, J. Hazard. Mater., 171(1-3), 551, 2009
  54. Zhang H, Li Y, Wu X, Zhang Y, Zhang D, Waste Manage., 30, 2096, 2010
  55. Minitab I. MINITAB Release 17: Statistical Software for Windows. Minitab Inc., U.S.A. (2014).
  56. -Ruiz BG, Gomez-Lavin S, Diban N, Boiteux V, Colin A, Dauchy X, Urtiaga A, Chem. Eng. J., 322, 196, 2017
  57. Comninellis C, Doyle M, Winnick J(Eds.), Proceedings of the International Symposium held during the 2001 Joint International Meeting of the ECS and ISE in San Francisco, California, U.S.A. (2001).
  58. Wilson S, Farone W, Leonard G, Birnstingl J, Leombruni A, Regenesis Bioremediation Products Inc., San Clemente, CA, U.S.A. (2013).
  59. Diallo MS, Fromer NA, Jhon MS(Eds.), Springer Science & Business, New York, U.S.A. (2014).
  60. Yehya T, Chafi M, Balla W, Vial C, Essadki A, Gourich B, Sep. Purif. Technol., 132, 644, 2014
  61. Wisniak J, Stefanovic S, Rubin E, Hoffman Z, Talmon Y, J. Am. Oil Chem. Soc., 48, 379, 1971
  62. Asaithambi P, Susree M, Saravanathamizhan R, Matheswaran M, Desalination, 297, 1, 2012
  63. Khandegar V, Saroha AK, Chin. J. Chem. Eng., 20(3), 439, 2012
  64. Wang C, Huang YK, Zhao Q, Ji M, Chem. Eng. J., 243, 1, 2014
  65. Yahiaoui I, Aissani-Benissad F, Fourcade F, Amrane A, Chem. Eng. J., 221, 418, 2013
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