Identyfikatory
Warianty tytułu
Języki publikacji
Abstrakty
As a result of rapid industrialization and population development, toxic chemicals have been introduced into water systems in recent decades. Because of its excellent efficiency and simple design, the three-dimensional (3D) electro-Fenton method has been used for the treatment of wastewater. The goal of the current study is to explore the efficiency of phenol removal by the 3D electro-Fenton process, which is one of the advanced oxidation processes (AOPs). In the present work, the effect of the addition of granular activated carbon (GAC) particles to the electro-Fenton system as the third electrode would be investigated in the presence of graphite as the anode and nickel foam as the cathode, which is the source of electro-generated hydrogen peroxide (H2O2). The influence of operation parameters (current density, electrolysis time, and GAC) on catalytic performance will be studied, which will be adjusted by the response surface methodology (RSM). The pH was adjusted to 3, and the airflow was set to 10 L/h. According to the results the nickel foam was an excellent cathode material choice. The best conditions for phenol elimination were at current density of 3.56 mA/cm2, FeSO4.7H2O dosage of 0.1 mM, GAC of 30 g, and a time of 3 h to attain the removal rates of phenol and chemical oxygen demand (COD) of 98.79% and 93.01%, respectively. The results showed that time had a higher effect on the phenol and COD removal efficiency, while the impact of current density was lower. The model equation’s high R2 value (97.90%) demonstrates its suitability.
Czasopismo
Rocznik
Tom
Strony
92--104
Opis fizyczny
Bibliogr. 40 poz., rys., tab.
Twórcy
autor
- Department of Chemical Engineering, College of Engineering, University of Baghdad, Baghdad, Iraq
autor
- Department of Chemical Engineering, College of Engineering, University of Baghdad, Baghdad, Iraq
Bibliografia
- 1. Abbas, A.S., Hafiz, M.H., Salman, R.H. 2016. Indirect Electrochemical Oxidation of Phenol Using Rotating Cylinder Reactor. Iraqi Journal of Chemical and Petroleum Engineering. 17(4), 43–55.
- 2. Abbas, R.N., Abbas, A.S. 2022. Kinetics and Energetic Parameters Study of Phenol Removal from Aqueous Solution by Electro-Fenton Advanced Oxidation Using Modified Electrodes with PbO2 and Graphene. Iraqi Journal of Chemical and Petroleum Engineering, 23(2), 1–8.
- 3. Abbas, Z.I., Abbas, A.S. 2019. Oxidative degradation of phenolic wastewater by electro-fenton process using MnO2-graphite electrode. Journal of Environmental Chemical Engineering, 7(3).
- 4. Abd Gami, A., Yunus Shukor, M., Abdul Khalil, K., Aini Dahalan, F., Khalid, A., Aqlima Ahmad, S. 2014. Phenol and Phenolic Compounds Toxicity, 2(1), 11-23.
- 5. Adil Sabbar, H. 2019. Adsorption of Phenol from Aqueous Solution using Paper Waste. Iraqi Journal of Chemical and Petroleum Engineering, 20(1), 23–29.
- 6. Al-Rubaiey, N. 2022. A trends in Ozone Treatment of Wastewater: a Review. Iraqi Journal of Oil and Gas Research (IJOGR), 2(1), 55–64.
- 7. Atsdr. 2008.Toxicological profile for phenol. Division of toxicology and environmental medicine/applied toxicology branch US Department of health and human services. Georgia, United States, 1–20.
- 8. Bocos, E., Iglesias, O., Pazos, M., Ángeles Sanromán, M. 2016. Nickel foam a suitable alternative to increase the generation of Fenton’s reagents. Process Safety and Environmental Protection, 101, 34–44.
- 9. Bury, N.A., Mumford, K.A., Stevens, G.W. 2021. The electro-Fenton regeneration of Granular Activated Carbons: Degradation of organic contaminants and the relationship to the carbon surface. Journal of Hazardous Materials, 416.
- 10. Dao, K.C., Yang, C.C., Chen, K.F., Tsai, Y.P. 2020. Recent trends in removal pharmaceuticals and personal care products by electrochemical oxidation and combined systems. Water (Switzerland), 12(4).
- 11. Davarnejad, R., Sahraei, A. 2016. Industrial wastewater treatment using an electrochemical technique: an optimized process. Desalination and Water Treatment, 57(21), 9622–9634.
- 12. Fahem, A.S., Abbar, A.H. 2020. Treatment of petroleum refinery wastewater by electro-Fenton process using porous graphite electrodes. Egyptian Journal of Chemistry, 63(12), 4805–4819.
- 13. Fockedey, E., Lierde, A. Van 2002. Coupling of anodic and cathodic reactions for phenol electro-oxidation using three-dimensional electrodes, 36, 4169–4175.
- 14. Ghjair, A., Abbar, A. 2022. Removal of chemical oxygen demand (COD) from hospital wastewater by electro fenton process using graphite–graphite electrochemical system. Al-Qadisiyah Journal for Engineering Sciences, 15(1), 23–31.
- 15. Gümüş, D., Akbal, F. 2016. Comparison of Fenton and electro-Fenton processes for oxidation of phenol. Process Safety and Environmental Protection, 103, 252–258.
- 16. Haji Ali, B., Baghdadi, M., Torabian, A. 2021. Application of nickel foam as an effective electrode for the electrochemical treatment of liquid hazardous wastes of COD analysis containing mercury, silver, and chromium (VI). Environmental Technology and Innovation, 23.
- 17. He, H., Zhou, Z. 2017. Electro-fenton process for water and wastewater treatment. Critical Reviews in Environmental Science and Technology, 47(21), 2100–2131.
- 18. Ho, S. 2022. Low-Cost Adsorbents for the Removal of Phenol/Phenolics, Pesticides, and Dyes from Wastewater Systems: A Review. Water (Switzerland), 14(20).
- 19. Hu, X., Tian, X., Lin, Y.W., Wang, Z. 2019. Nickel foam and stainless steel mesh as electrocatalysts for hydrogen evolution reaction, oxygen evolution reaction and overall water splitting in alkaline media. RSC Advances, 9(54), 31563–31571.
- 20. Ibrahim, M.H., Salman, R.H. 2022. Study the Optimization of Petroleum Refinery Wastewater Treatment by Successive Electrocoagulation and Electrooxidation Systems. Iraqi Journal of Chemical and Petroleum Engineering, 23(1), 31–41.
- 21. Issa, Z.M., Salman, R.H. 2023. Chromium Ions Removal by Capacitive Deionization Process: Optimization of the Operating Parameters with Response Surface Methodology. Journal of Ecological Engineering, 24(1), 51–65.
- 22. Khalid, M.W., Salman, S.D. Adsorption of Heavy Metals from Aqueous Solution onto Sawdust Activated Carbon. Journal Al-Khwarizmi Engineering Journal, 15(3), 60–69.
- 23. Li, Q., Gao, X., Liu, Y., Wang, G., Li, Y.Y., Sano, D., Wang, X., Chen, R. 2021. Biochar and GAC intensify anaerobic phenol degradation via distinctive adsorption and conductive properties. Journal of Hazardous Materials, 405(August), 124183.
- 24. Lütke, S.F., Igansi, A.V., Pegoraro, L., Dotto, G.L., Pinto, L.A.A., Cadaval, T.R.S. 2019. Preparation of activated carbon from black wattle bark waste and its application for phenol adsorption. Journal of Environmental Chemical Engineering, 7(5).
- 25. Mohd, A. 2022. Presence of phenol in wastewater effluent and its removal: an overview. International Journal of Environmental Analytical Chemistry, 102(6), 1362–1384.
- 26. Nidheesh, P.V., Ganiyu, S.O., Martínez-Huitle, C.A., Mousset, E., Olvera-Vargas, H., Trellu, C., Zhou, M., Oturan, M.A. 2023. Recent advances in electro-Fenton process and its emerging applications. Critical Reviews in Environmental Science and Technology, 53(8), 887–913.
- 27. Norra, G.F., Radjenovic, J. 2021. Removal of persistent organic contaminants from wastewater using a hybrid electrochemical-granular activated carbon (GAC) system. Journal of Hazardous Materials, 415(February), 125557.
- 28. Oturan, N., Bo, J., Trellu, C., Oturan, M.A. 2021. Comparative Performance of Ten Electrodes in Electro-Fenton Process for Removal of Organic Pollutants from Water. ChemElectroChem, 8(17), 3294–3303.
- 29. Roddaeng, S., Promvonge, P., Anuwattana, R. 2018. Behaviors of hydrogen sulfide removal using granular activated carbon and modified granular activated carbon. In MATEC Web of Conferences. EDP Sciences, 192.
- 30. Siburian, R., Sihotang, H., Lumban Raja, S., Supeno, M., Simanjuntak, C. 2018. New route to synthesize of graphene nano sheets. Oriental Journal of Chemistry, 34(1), 182–187.
- 31. Singh, S., Mahesh, S., Sahana, M. 2019. Three-dimensional batch electrochemical coagulation (ECC) of health care facility wastewater—clean water reclamation. Environmental Science and Pollution Research, 26(13), 12813–12827.
- 32. Sun, Y., Li, P., Zheng, H., Zhao, C., Xiao, X., Xu, Y., Sun, W., Wu, H., Ren, M. 2017. Electrochemical treatment of chloramphenicol using Ti-Sn/γ-Al2O3 particle electrodes with a three-dimensional reactor. Chemical Engineering Journal, 308, 1233–1242.
- 33. Umar, S., Bakhary, N., Abidin, A.R.Z. 2018. Response surface methodology for damage detection using frequency and mode shape. Measurement: Journal of the International Measurement Confederation, 115, 258–268.
- 34. Wan, W., Zhang, Y., Ji, R., Wang, B., He, F. 2017. Metal Foam-Based Fenton-Like Process by Aeration. ACS Omega, 2(9), 6104–6111.
- 35. Yan, L., Ma, H., Wang, B., Wang, Y., Chen, Y. 2011. Electrochemical treatment of petroleum refinery wastewater with three-dimensional multi-phase electrode. Desalination, 276(1–3), 397–402.
- 36. Yang, B., Tang, J. 2018. Electrochemical oxidation treatment of wastewater using activated carbon electrode. International Journal of Electrochemical Science, 13(1), 1096–1104.
- 37. Yang, C., Liu, H., Luo, S., Chen, X., He, H. 2012. Performance of Modified Electro-Fenton Process for Phenol Degradation Using Bipolar Graphite Electrodes and Activated Carbon. Journal of Environmental Engineering, 138(6), 613–619.
- 38. Zhang, C., Jiang, Y., Li, Y., Hu, Z., Zhou, L., Zhou, M. 2013. Three-dimensional electrochemical process for wastewater treatment: A general review. Chemical Engineering Journal, 228, 455–467.
- 39. Zhang, Y., Chen, Z., Wu, P., Duan, Y., Zhou, L., Lai, Y., Wang, F., Li, S. 2020. Three-dimensional heterogeneous Electro-Fenton system with a novel catalytic particle electrode for Bisphenol A removal. Journal of Hazardous Materials, 393.
- 40. Zheng, Y., Qiu, S., Deng, F., Zhu, Y., Li, G., Ma, F. 2019. Three-dimensional electro-Fenton system with iron foam as particle electrode for folic acid wastewater pretreatment. Separation and Purification Technology, 224, 463–474.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-e64653c9-ddff-4d05-b5f9-8a87aafb0e1c