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Removal Of Sumifix Yellow EXF Reactive Azo Dye By Electro-Fenton Method

Year 2023, Volume: 10 Issue: 3, 719 - 728, 30.08.2023
https://doi.org/10.18596/jotcsa.1226203

Abstract

Reactive dyes can be found in large quantities in textile industry wastewater due to their widespread use for dyeing cotton fabrics and their durable nature. In the treatment of wastewater containing dyestuffs in this class, advanced treatment methods have become necessary due to the inadequacy of conventional treatment methods and their disadvantages. For this reason, electro-Fenton, an electrochemical advanced oxidation method, is a strong alternative as a treatment technology that provides complete disintegration of dye molecules. In this study, the electro-Fenton method was used to treat model wastewater containing the reactive azo dye Sumifix Yellow EXF. The electro-Fenton process is based on the in situ generation of hydroxyl radicals (⦁OH), a strong oxidant, using Fe2+ and H2O2 released at the electrodes or added from outside. In the electrochemical cell used, carbon fiber was used as the cathode and iron was used as the anode. While Fe2+ ion was produced at the anode, H2O2 was added to the cell externally. In the experiments carried out at room temperature, a 250 mL glass beaker was used as a reactor. In the study, the optimization of the parameters was achieved by using the classical experimental design method. According to this method, one parameter is changed and other parameters are kept constant. In order to achieve the highest dyestuff removal, experiments were conducted by varying the voltage (5–10 V), H2O2 concentration (9–74 mM), Na2SO4 concentration (6–25 mM), and pH (3-5), and the impact of these factors on dye removal and energy consumption was evaluated. It was found that for the best dye removal, voltage is 7.5 V, the H2O2 concentration is 74 mM, the Na2SO4 concentration is 25 mM and the optimum pH value is 4. At these values, 98.14% removal at 30 minutes was achieved with an energy consumption of 7.98 Wh/L. The electro-Fenton method was found to be a highly effective approach for wastewater treatment and environmental remediation, showing remarkable dye removal efficiency with reasonable energy consumption under optimized conditions.

Supporting Institution

Yok.

Project Number

Yok.

Thanks

This study was presented at the 4th International Congress of Environmental Chemistry (EnviroChem-2022). Thank you for giving us this opportunity.

References

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  • 2. Carmen Z, Daniela S. Textile Organic Dyes-Characteristics, Polluting Effects and Separation/Elimination Procedures from Industrial Effluents-A Critical Overview [Internet]. Available from: <URL>
  • 3. Zhang S, Tappe H, Helmling W, Mischke P, Rebsamen K, Reiher U, et al. Reactive Dyes. In: Ullmann’s Encyclopedia of Industrial Chemistry [Internet]. Weinheim, Germany: Wiley-VCH Verlag GmbH & Co. KGaA; p. 1–20. Available from: <URL>
  • 4. Şahinkaya S. COD and color removal from synthetic textile wastewater by ultrasound assisted electro-Fenton oxidation process. Journal of Industrial and Engineering Chemistry. 2013 Mar 25;19(2):601–5. Available from: <URL>
  • 5. Hunger K, Mischke P, Rieper W. Azo Dyes, 1. General. In: Ullmann’s Encyclopedia of Industrial Chemistry. Wiley-VCH Verlag GmbH & Co. KGaA; 2011. Available from: <URL>
  • 6. Jager D, Kupka D, Vaclavikova M, Ivanicova L, Gallios G. Degradation of Reactive Black 5 by electrochemical oxidation. Chemosphere. 2018;190:405–16. Available from: <URL>
  • 7. Liu X, Yin H, Lin A, Guo Z. Effective removal of phenol by using activated carbon supported iron prepared under microwave irradiation as a reusable heterogeneous Fenton-like catalyst. J Environ Chem Eng. 2017 Feb 1;5(1):870–6. Available from: <URL>
  • 8. Wang X, Jiang J, Gao W. Reviewing textile wastewater produced by industries: characteristics, environmental impacts, and treatment strategies. Vol. 85, Water Science and Technology. IWA Publishing; 2022. p. 2076–96. Available from: <URL>
  • 9. Do TM, Byun JY, Kim SH. An electro-Fenton system using magnetite coated metallic foams as cathode for dye degradation. Catal Today. 2017 Oct 15;295:48–55. Available from: <URL>
  • 10. Kremer ML. Mechanism of the Fenton reaction. Evidence for a new intermediate. Physical Chemistry Chemical Physics. 1999 Aug 1;1(15):3595–605. Available from: <URL>
  • 11. Zhou M, Yu Q, Lei L, Barton G. Electro-Fenton method for the removal of methyl red in an efficient electrochemical system. Sep Purif Technol. 2007 Oct 15;57(2):380–7. Available from: <URL>
  • 12. Ganiyu SO, Zhou M, Martínez-Huitle CA. Heterogeneous electro-Fenton and photoelectro-Fenton processes: A critical review of fundamental principles and application for water/wastewater treatment. Vol. 235, Applied Catalysis B: Environmental. Elsevier B.V.; 2018. p. 103–29. Available from: <URL>
  • 13. Zhang H, Fei C, Zhang D, Tang F. Degradation of 4-nitrophenol in aqueous medium by electro-Fenton method Degradation of 4-nitrophenol in aqueous medium by electro-Fenton method. J Hazard Mater. 2007 Jun 25;145(1–2):227–32. Available from: <URL>
  • 14. Moreira FC, Boaventura RAR, Brillas E, Vilar VJP. Electrochemical advanced oxidation processes: A review on their application to synthetic and real wastewaters. Vol. 202, Applied Catalysis B: Environmental. Elsevier B.V.; 2017. p. 217–61. Available from: <URL>
  • 15. Nidheesh P v., Gandhimathi R. Trends in electro-Fenton process for water and wastewater treatment: An overview. Vol. 299, Desalination. 2012. p. 1–15. Available from: <URL>
  • 16. Smith, R. M., Martell, A. E. Critical Stability Constants, 4, Inorganic Complexes; 1976. 270 p. ISBN: 0608093653, 9780608093659. Available from: <URL>
  • 17. Neta P, Huie RE, Ross AB. Rate·Constants for Reactions of Inorganic Radicals in Aqueous Solution [Internet]. Available from: <URL>
  • 18. de Laat J, Truong Le G, Legube B. A comparative study of the effects of chloride, sulfate and nitrate ions on the rates of decomposition of H2O2 and organic compounds by Fe(II)/H2O2 and Fe(III)/H2O 2. Chemosphere. 2004;55(5):715–23. Available from: <URL>
  • 19. Gökkuş Ö, Yıldız YŞ. Application of electro-Fenton process for medical waste sterilization plant wastewater. Desalination Water Treat. 2016 Nov 7;57(52):24934–45. Available from: <URL>
  • 20. Muruganandham M, Swaminathan M. Decolourisation of Reactive Orange 4 by Fenton and photo-Fenton oxidation technology. Dyes and Pigments. 2004 Dec;63(3):315–21. Available from: <URL>
  • 21. Ghoneim MM, El-Desoky HS, Zidan NM. Electro-Fenton oxidation of Sunset Yellow FCF azo-dye in aqueous solutions. Desalination. 2011 Jul 1;274(1–3):22–30. Available from: <URL>
  • 22. Lei H, Li H, Li Z, Li Z, Chen K, Zhang X, et al. Electro-Fenton degradation of cationic red X-GRL using an activated carbon fiber cathode. Process Safety and Environmental Protection. 2010 Nov;88(6):431–8. Available from: <URL>
  • 23. Wang CT, Hu JL, Chou WL, Kuo YM. Removal of color from real dyeing wastewater by Electro-Fenton technology using a three-dimensional graphite cathode. J Hazard Mater. 2008 Apr 1;152(2):601–6. Available from: <URL>
  • 24. Ai Z, Mei T, Liu J, Li J, Jia F, Zhang L, et al. Fe@Fe2O3 core-shell nanowires as an iron reagent. 3. Their combination with CNTs as an effective oxygen-fed gas diffusion electrode in a neutral electro-fenton system. Journal of Physical Chemistry C. 2007 Oct 11;111(40):14799–803. Available from: <URL>
  • 25. Wang CT, Chou WL, Chung MH, Kuo YM. COD removal from real dyeing wastewater by electro-Fenton technology using an activated carbon fiber cathode. Desalination. 2010 Apr;253(1–3):129–34. Available from: <URL>
  • 26. Shemer H, Linden KG. Degradation and by-product formation of diazinon in water during UV and UV/H2O2 treatment. J Hazard Mater. 2006 Aug 25;136(3):553–9. Available from: <URL>
  • 27. Wang Q, Lemley AT. Kinetic model and optimization of 2,4-D degradation by Anodic Fenton treatment. Environ Sci Technol. 2001 Nov 15;35(22):4509–14. Available from: <URL>
  • 28. Ting WP, Lu MC, Huang YH. Kinetics of 2,6-dimethylaniline degradation by electro-Fenton process. J Hazard Mater. 2009 Jan 30;161(2–3):1484–90. Available from: <URL>
  • 29. Akyol A, Can OT, Demirbas E, Kobya M. A comparative study of electrocoagulation and electro-Fenton for treatment of wastewater from liquid organic fertilizer plant. Sep Purif Technol. 2013 July 10;112: 11–9. Available from: <URL>
Year 2023, Volume: 10 Issue: 3, 719 - 728, 30.08.2023
https://doi.org/10.18596/jotcsa.1226203

Abstract

Project Number

Yok.

References

  • 1. Babuponnusami A, Muthukumar K. A review on Fenton and improvements to the Fenton process for wastewater treatment. Vol. 2, Journal of Environmental Chemical Engineering. Elsevier Ltd; 2014. p. 557–72. Available from: <URL>
  • 2. Carmen Z, Daniela S. Textile Organic Dyes-Characteristics, Polluting Effects and Separation/Elimination Procedures from Industrial Effluents-A Critical Overview [Internet]. Available from: <URL>
  • 3. Zhang S, Tappe H, Helmling W, Mischke P, Rebsamen K, Reiher U, et al. Reactive Dyes. In: Ullmann’s Encyclopedia of Industrial Chemistry [Internet]. Weinheim, Germany: Wiley-VCH Verlag GmbH & Co. KGaA; p. 1–20. Available from: <URL>
  • 4. Şahinkaya S. COD and color removal from synthetic textile wastewater by ultrasound assisted electro-Fenton oxidation process. Journal of Industrial and Engineering Chemistry. 2013 Mar 25;19(2):601–5. Available from: <URL>
  • 5. Hunger K, Mischke P, Rieper W. Azo Dyes, 1. General. In: Ullmann’s Encyclopedia of Industrial Chemistry. Wiley-VCH Verlag GmbH & Co. KGaA; 2011. Available from: <URL>
  • 6. Jager D, Kupka D, Vaclavikova M, Ivanicova L, Gallios G. Degradation of Reactive Black 5 by electrochemical oxidation. Chemosphere. 2018;190:405–16. Available from: <URL>
  • 7. Liu X, Yin H, Lin A, Guo Z. Effective removal of phenol by using activated carbon supported iron prepared under microwave irradiation as a reusable heterogeneous Fenton-like catalyst. J Environ Chem Eng. 2017 Feb 1;5(1):870–6. Available from: <URL>
  • 8. Wang X, Jiang J, Gao W. Reviewing textile wastewater produced by industries: characteristics, environmental impacts, and treatment strategies. Vol. 85, Water Science and Technology. IWA Publishing; 2022. p. 2076–96. Available from: <URL>
  • 9. Do TM, Byun JY, Kim SH. An electro-Fenton system using magnetite coated metallic foams as cathode for dye degradation. Catal Today. 2017 Oct 15;295:48–55. Available from: <URL>
  • 10. Kremer ML. Mechanism of the Fenton reaction. Evidence for a new intermediate. Physical Chemistry Chemical Physics. 1999 Aug 1;1(15):3595–605. Available from: <URL>
  • 11. Zhou M, Yu Q, Lei L, Barton G. Electro-Fenton method for the removal of methyl red in an efficient electrochemical system. Sep Purif Technol. 2007 Oct 15;57(2):380–7. Available from: <URL>
  • 12. Ganiyu SO, Zhou M, Martínez-Huitle CA. Heterogeneous electro-Fenton and photoelectro-Fenton processes: A critical review of fundamental principles and application for water/wastewater treatment. Vol. 235, Applied Catalysis B: Environmental. Elsevier B.V.; 2018. p. 103–29. Available from: <URL>
  • 13. Zhang H, Fei C, Zhang D, Tang F. Degradation of 4-nitrophenol in aqueous medium by electro-Fenton method Degradation of 4-nitrophenol in aqueous medium by electro-Fenton method. J Hazard Mater. 2007 Jun 25;145(1–2):227–32. Available from: <URL>
  • 14. Moreira FC, Boaventura RAR, Brillas E, Vilar VJP. Electrochemical advanced oxidation processes: A review on their application to synthetic and real wastewaters. Vol. 202, Applied Catalysis B: Environmental. Elsevier B.V.; 2017. p. 217–61. Available from: <URL>
  • 15. Nidheesh P v., Gandhimathi R. Trends in electro-Fenton process for water and wastewater treatment: An overview. Vol. 299, Desalination. 2012. p. 1–15. Available from: <URL>
  • 16. Smith, R. M., Martell, A. E. Critical Stability Constants, 4, Inorganic Complexes; 1976. 270 p. ISBN: 0608093653, 9780608093659. Available from: <URL>
  • 17. Neta P, Huie RE, Ross AB. Rate·Constants for Reactions of Inorganic Radicals in Aqueous Solution [Internet]. Available from: <URL>
  • 18. de Laat J, Truong Le G, Legube B. A comparative study of the effects of chloride, sulfate and nitrate ions on the rates of decomposition of H2O2 and organic compounds by Fe(II)/H2O2 and Fe(III)/H2O 2. Chemosphere. 2004;55(5):715–23. Available from: <URL>
  • 19. Gökkuş Ö, Yıldız YŞ. Application of electro-Fenton process for medical waste sterilization plant wastewater. Desalination Water Treat. 2016 Nov 7;57(52):24934–45. Available from: <URL>
  • 20. Muruganandham M, Swaminathan M. Decolourisation of Reactive Orange 4 by Fenton and photo-Fenton oxidation technology. Dyes and Pigments. 2004 Dec;63(3):315–21. Available from: <URL>
  • 21. Ghoneim MM, El-Desoky HS, Zidan NM. Electro-Fenton oxidation of Sunset Yellow FCF azo-dye in aqueous solutions. Desalination. 2011 Jul 1;274(1–3):22–30. Available from: <URL>
  • 22. Lei H, Li H, Li Z, Li Z, Chen K, Zhang X, et al. Electro-Fenton degradation of cationic red X-GRL using an activated carbon fiber cathode. Process Safety and Environmental Protection. 2010 Nov;88(6):431–8. Available from: <URL>
  • 23. Wang CT, Hu JL, Chou WL, Kuo YM. Removal of color from real dyeing wastewater by Electro-Fenton technology using a three-dimensional graphite cathode. J Hazard Mater. 2008 Apr 1;152(2):601–6. Available from: <URL>
  • 24. Ai Z, Mei T, Liu J, Li J, Jia F, Zhang L, et al. Fe@Fe2O3 core-shell nanowires as an iron reagent. 3. Their combination with CNTs as an effective oxygen-fed gas diffusion electrode in a neutral electro-fenton system. Journal of Physical Chemistry C. 2007 Oct 11;111(40):14799–803. Available from: <URL>
  • 25. Wang CT, Chou WL, Chung MH, Kuo YM. COD removal from real dyeing wastewater by electro-Fenton technology using an activated carbon fiber cathode. Desalination. 2010 Apr;253(1–3):129–34. Available from: <URL>
  • 26. Shemer H, Linden KG. Degradation and by-product formation of diazinon in water during UV and UV/H2O2 treatment. J Hazard Mater. 2006 Aug 25;136(3):553–9. Available from: <URL>
  • 27. Wang Q, Lemley AT. Kinetic model and optimization of 2,4-D degradation by Anodic Fenton treatment. Environ Sci Technol. 2001 Nov 15;35(22):4509–14. Available from: <URL>
  • 28. Ting WP, Lu MC, Huang YH. Kinetics of 2,6-dimethylaniline degradation by electro-Fenton process. J Hazard Mater. 2009 Jan 30;161(2–3):1484–90. Available from: <URL>
  • 29. Akyol A, Can OT, Demirbas E, Kobya M. A comparative study of electrocoagulation and electro-Fenton for treatment of wastewater from liquid organic fertilizer plant. Sep Purif Technol. 2013 July 10;112: 11–9. Available from: <URL>
There are 29 citations in total.

Details

Primary Language English
Subjects Electrochemistry
Journal Section RESEARCH ARTICLES
Authors

Elif Özkul 0000-0001-8173-6690

Belgin Karabacakoğlu 0000-0002-3157-7609

Project Number Yok.
Publication Date August 30, 2023
Submission Date December 29, 2022
Acceptance Date June 22, 2023
Published in Issue Year 2023 Volume: 10 Issue: 3

Cite

Vancouver Özkul E, Karabacakoğlu B. Removal Of Sumifix Yellow EXF Reactive Azo Dye By Electro-Fenton Method. JOTCSA. 2023;10(3):719-28.