EXPLORING THE PHENOL REMOVAL STRATEGIES; BY THE MEANS OF ADSORPTION

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Yazarlar

  • Ülküye Dudu GÜL Bilecik Şeyh Edebali Üniversitesi

Anahtar Kelimeler:

adsorpsiyon- fenol- atıksu arıtımı

Özet

Endüstriyel faaliyetler sonucunda oluşan fenol ve fenolik bileşikler atık sular aracılığla su kaynaklarına karışmaktadır. Su kaynaklarına karışan fenol ve türevleri son dönemlerde dikkat çeken çevre kirliliği etmenleri olmalarının yanı sıra içme sularına ulaştığında insan sağlığını tehdit etmektedir. Bu nedenlerle atık sularda yüksek oranlarda bulunan fenollerin gidermi önem kazanmıştır. Sucul ortamlardan fenol giderimi için önerilen yöntemlerden biri de adsorpsiyondur. Bu çalışmanın amacı sulu çözeltilerden fenol giderim stratejisi olarak kullanılan adsorpsiyon prosesi ile ilgili güncel literatürü derlemektir. Bu amaç doğrultusunda adsorpsiyon prosesinde kullanılan farklı adsorbanlara ait sonuçlar incelenmiş ve fenol adsorpsiyonunu etkileyen faktörler ifade edilmiştir. Ayrıca fenol için adsorpsiyon mekanizmasının açıklanmasında kullanılan izoterm ve kinetik çalışmalara ait sonuçlar derlenmiştir. Bu çalışmada sunulan verilerin gelecekte fenol arıtımına yönelik sistemlerin tasarlanabilmesi için önemli kaynak oluşturacağı öngörülmektedir.

Referanslar

Sobiesiak, M. (2017): Chemical Structure of Phenols and Its Consequence for Sorption Processes. InTech. doi: 10.5772/66537

William W. Anku, Messai A. Mamo and Penny P. Govender (March 15th 2017). Phenolic Compounds in Water: Sources, Reactivity, Toxicity and Treatment Methods, Phenolic Compounds - Natural Sources, Importance and Applications, Marcos Soto-Hernandez, Mariana Palma-Tenango and Maria del Rosario Garcia-Mateos, IntechOpen, doi: 10.5772/66927.

Villegas, L.G.C., Mashhadi, N., Chen, M. et al. (2016): A Short Review of Techniques for Phenol Removal from Wastewater. Current Pollution Reports 2: 157–167.

Hussain, A., Dubey, S.K., Kumar, V. (2015): Kinetic study for aerobic treatment of phenolic wastewater, Water Resources and Industry 11: 81-90.

Kulkarni, S.J., Kaware, J.P. (2013): Review on research for removal of phenol from wastewater. International Journal of Scientific and Research Publications 3:1–4.

Todorović, V. (2003): Akutna trovanja fenolom [Acute phenol poisoning]. Medicinski Pregled (56) 1: 37-41.

EPA Toxic Release Inventory National Analysis, accessed 2021: Available from: https://www.epa.gov/sites/default/files/2016-09/documents/phenol.pdf.

Kulkarni, S., Jayant, K. (2013): Adsorption For Phenol Removal-A Review. International Journal Of Scientific Engineering And Research (Ijser), 1(2): 90-96.

Erattemparambil, K., Mohan, L., Gnanasundaram, N., Krishnamoorthy, R. (2023): Insights into adsorption theory of phenol removal using a circulating fluidized bed system. Arabian Journal of Chemistry 16(6): 104750.

Culp, G.L., and R.L. Culp. (1974): New Concepts in Water Purification. Van Nostrand Reinhold Co., New York.

Afsharnia, M., Saeidi, M., Zarei, A., Narooie, M.R., Biglari, H. (2016). Phenol Removal from Aqueous Environment by Adsorption onto Pomegranate Peel Carbon. Electron Physician 8(11):3248-3256.

Ingole, R.S., Lataye, D.H., Dhorabe, P.T. (2017): Adsorption of phenol onto Banana Peels Activated Carbon. KSCE Journal of Civil Engineering 21: 100–110.

Mojoudi, N., Mirghaffari, N., Soleimani, M. et al. (2019): Phenol adsorption on high microporous activated carbons prepared from oily sludge: equilibrium, kinetic and thermodynamic studies. Scientific Reports 9:19352.

Xie, B., Qin, J., Wang, S., Li, X., Sun, H., Chen, W. (2020). Adsorption of Phenol on Commercial Activated Carbons: Modelling and Interpretation. International Journal of Environmental Research and Public Health 17(3):789.

Ho, Z. H., Adnan, L. A. (2021): Phenol Removal from Aqueous Solution by Adsorption Technique Using Coconut Shell Activated Carbon. Tropical Aquatic and Soil Pollution 1(2): 98–107.

Darla, U.R., Lataye, D.H., Kumar, A. et al. (2023): Adsorption of phenol using adsorbent derived from Saccharum officinarum biomass: optimization, isotherms, kinetics, and thermodynamic study. Scientific Reports 13: 18356.

Dehmani, Y., Lamhasni, T., Mohsine, A., Tahri, Y., Lee, H., Lgaz, H., Alrashd, A. A., Abouarnadasse, S. (2024): Adsorption removal of phenol by oak wood charcoal activated carbon. Biomass Conversion and Biorefinery 14 (6): 8015-8027.

Senturk, H. B., Ozdes, D., Gundogdu, A., Duran, C., Soylak, M. (2009): Removal of phenol from aqueous solutions by adsorption onto organomodified Tirebolu bentonite: Equilibrium, kinetic and thermodynamic study, Journal of Hazardous Materials, 172(1): 53-362.

Asnaoui, H., Dehmani, Y., Khalis, M., Hachem, E. K. (2020): Adsorption of phenol from aqueous solutions by Na–bentonite: kinetic, equilibrium and thermodynamic studies. International Journal of Environmental Analytical Chemistry, 102(13): 3043–3057.

He, H., Xu E., Qiu Z., Wu T., Wang S., Lu Y., Chen G. 2022: Phenol Adsorption Mechanism of Organically Modified Bentonite and Its Microstructural Changes. Sustainability 14(3):1318.

Alidra, H., Djazi, F., Keskin, B. (2024): Enhanced phenol removal from aqueous media by adsorption onto organo-modified bentonite. Research on Chemical Intermediates 50: 989–1011.

Congur, G., Gül, Ü. D. (2022): Electrochemical Detection of Phenol Removal by Using a Biosorbent Originated Factory Solid Waste. Electroanalysis 34: 455.

Sasi, R., Zachariah, S., Suchithra, T.V. (2022): The Untapped Potential of Fungi in Phenol Biodegradation. In: Shukla, A.C. (eds) Applied Mycology. Fungal Biology. Springer, Cham. https://doi.org/10.1007/978-3-030-90649-8_19.

Ertuğrul Karatay, S., Gül, Ü.D., Dönmez, G. (2014): Stimulation of Phenol Removal Efficiency of Aspergillus versicolor by Surfactants, a Promising Way to Treat Phenol-Containing Waste Waters. Journal of Surfactants and Detergents 17: 1223–1228.

Abujayyab, M., Al-Zuhair, S. (2017): Microalgae cultivation for phenol removal from wastewater. MOJ Toxicology 3(6):140–141.

Campaniello, D., Speranza, B., Altieri, C., Sinigaglia, M., Bevilacqua, A., Corbo, M.R. (2021): Removal of Phenols in Table Olive Processing Wastewater by Using a Mixed Inoculum of Candida boidinii and Bacillus pumilus: Effects of Inoculation Dynamics, Temperature, pH, and Effluent Age on the Abatement Efficiency. Microorganisms 9(8):1783.

Benit, N., Amala Lourthuraj, A., Barathikannan, K., Mostafa, A.A-F., Alodaini, H. A., Yassin, M.T., Hatamleh, A. A. (2022): Immobilization of Halomonas halodurans and Bacillus halodurans in packed bed bioreactor for continuous removal of phenolic impurities in waste water, Environmental Research, 209: 112822.

Khan, M.J., Wibowo, A., Karim, Z., Posoknistakul, P., Matsagar, B.M., Wu, K.C. (2024): Sakdaronnarong C. Wastewater Treatment Using Membrane Bioreactor Technologies: Removal of Phenolic Contaminants from Oil and Coal Refineries and Pharmaceutical Industries. Polymers (Basel) 16(3):443.

Beker, U., Ganbold, B., Dertli, H., Duranoğlu Gülbayir, D. (2010): Adsorption of phenol by activated carbon: Influence of activation methods and solution pH, Energy Conversion and Management, 51 (2): 235-240.

Galdino, A. L., Oliveira, J. C. A., Magalhaes, M. L., Lucena, S. M. P. (2021): Prediction of the phenol removal capacity from water by adsorption on activated carbon. Water Science & Technology 84 (1): 135- 143.

Garba, Z.N., Ekwumemgbo, P.A., Stephen, G. (2022): Optimization of phenol adsorption from synthetic wastewater by synthesized BiFeO3 perovskite material, using split-plot central composite design. Bulletin of the National Research Centre 46: 186.

Elayadi, F., Boumya, W., Achak, M., Chhiti, Y., Alaoui, F. E. M., Barka, N., El Adlouni, C. (2021): Experimental and modeling studies of the removal of phenolic compounds from olive mill wastewater by adsorption on sugarcane bagasse, Environmental Challenges 4: 100184.

Machrouhi, A., Boumya, W., Khnifira, M., Sadiq, M., Abdennouri, M., Elhalil, A., Tounsadi, H., Qourzal, S., Barka, N. (2020): Synthetic dyes adsorption and discoloration of a textile wastewater effluent by H3PO4 and H3BO3 activated Thapsia transtagana biomass. Desalination and Water Treatment 202: 435-449.

Ververi, M., Goula, A.M. (2019): Pomegranate peel and orange juice by-product as new biosorbents of phenolic compounds from olive mill wastewaters, Chemical Engineering and Processing - Process Intensification 138: 86-96.

Freundlich, H. (1907): Über die Adsorption in Lösungen.Zeitschrift für Physikalische Chemie – Stöchiometrie und Verwandschaftslehre 57 (4): 385–470.

Langmuir, I. (1917): The Constitution and Fundamental Properties of Solids and Liquids: II. Liquids. Journal of the American Chemical Society 39 (9): 1848–1906.

Corbett J. F. (1972): Pseudo first-order kinetics. Journal of Chemical Education 49 (10): 663.

Ho, Y.S., McKay, G. (1999): Pseudo-second order model for sorption processes. Process Biochemistry 34 (5): 451-465.

Mishra, P., Singh, K., Dixit, U. (2021): Adsorption, kinetics and thermodynamics of phenol removal by ultrasound-assisted sulfuric acid-treated pea (Pisum sativum) shells. Sustainable Chemistry and Pharmacy 22: 100491.

Ouallal, H., Dehmani, Y., Moussout, H., Messaoudi, L., Azrour, M. (2019): Kinetic, isotherm and mechanism investigations of the removal of phenols from water by raw and calcined clays. Heliyon 5(5):e01616.

Wei, X., Huang, S., Yang, J., Liu, P., Li, X., Wu, Y., Wu, S. (2023). Adsorption of phenol from aqueous solution on activated carbons prepared from antibiotic mycelial residues and traditional biomass. Fuel Processing Technology 242: 107663.

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Yayınlanmış

2024-12-12

Nasıl Atıf Yapılır

GÜL, Ülküye D. (2024). EXPLORING THE PHENOL REMOVAL STRATEGIES; BY THE MEANS OF ADSORPTION. Türk Bilimsel Derleme Dergisi, 17(2), 53–63. Geliş tarihi gönderen https://derleme.gen.tr/index.php/derleme/article/view/483

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