Abstract
Olive industries include processes of production produce liquid wastes and solid contaminates. The solid part produced is manned olive stone waste, while the major product liquid part is olive mill wastewater (OMW), which has many contaminants in the water and solid parts. More than 95% of the olive production and its processes are in the Mediterranean countries. As a result, OMW is considered a toxic source that is harming the environment and water bodies. There are many methods for disposing of OMW in the environment to avoid toxicity. Different basic methods of discharging OMW include evaporation, landfilling, circulating pond, and crop irrigation. This research introduces a treatment process by adding low-cost chemical coagulants, filtration processes, and finally, treatment by adding hydrogen peroxide (H2O2). The samples were analyzed in two places: Al-Hussein Bin Talal University (AHU) laboratories and Royal Scientific Society (RSS) laboratories. Results show the effectiveness of ferric chloride (FeCl3) and ferric oxide (Fe2O3; inorganic chemical coagulants) with lime (Ca (OH)2) plus filtration process followed by adding the H2O2. The overall removals in percentage reached 99.5%. This approved those inorganic chemical coagulants used helped through suspended, colloidal, and dissolved matter removal, destabilized by adding the chemical coagulants FeCl3 and Fe2O3.
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21 November 2022
A Correction to this paper has been published: https://doi.org/10.1007/s13762-022-04672-0
References
Alburquerque J et al (2004) Agrochemical characterisation of “alperujo”, a solid by-product of the two-phase centrifugation method for olive oil extraction. Biores Technol 91(2):195–200
Al-Eitan LN et al (2021) The Effects of Olive Mill Wastewater on Soil Microbial Populations. Jordan J Biol Sci 14(3):546
Al-Essa K, Al-Essa EM (2021) Effective approach of activated Jordanian bentonite by sodium ions for total phenolic compounds removal from olive mill wastewater. J Chem
Al-Hmoud L, Al-Saida B, Sandouqa A (2020) Olive mill wastewater treatment: a recent review. Jordanian J Eng Chem Ind 3(3):91–106
Ayoub S (2017) Management of olive by-products in Jordan. In: Ensuring sustainability of Jordanian olive sector conference. Amman, Jordan
Azzam MOJ et al (2010) Dynamic treatment response of olive mills wastewater using series of adsorption steps. Clean-Soil, Air, Water 38(9):822–830
Bhatnagar A et al (2013) An overview of the modification methods of activated carbon for its water treatment applications. Chem Eng J 219:499–511
Coskun T, Debik E, Demir NM (2010) Treatment of olive mill wastewaters by nanofiltration and reverse osmosis membranes. Desalination 259(1–3):65–70
Dermeche S et al (2013) Olive mill wastes: biochemical characterizations and valorization strategies. Process Biochem 48(10):1532–1552
Ena A, Pintucci C, Carlozzi P (2012) The recovery of polyphenols from olive mill waste using two adsorbing vegetable matrices. J Biotechnol 157(4):573–577
Galiatsatou P et al (2002) Treatment of olive mill waste water with activated carbons from agricultural by-products. Waste Manage 22(7):803–812
Halalsheh M, Kassab G, Shatanawi K (2021) Impact of legislation on olive mill wastewater management: Jordan as a case study. Water Policy 23(2):343–357
Jeguirim M et al (2017) Olive mill wastewater: from a pollutant to green fuels, agricultural water source and bio-fertilizer—Part 1 the drying kinetics. Energies 10(9):1423
Kang H, Kim E, Jung SP (2017) Influence of flowrates to a reverse electro-dialysis (RED) stack on performance and electrochemistry of a microbial reverse electrodialysis cell (MRC). Int J Hydrog Energy 42(45):27685–27692
Kaur A, Gupta U (2009) A review on applications of nanoparticles for the preconcentration of environmental pollutants. J Mater Chem 19(44):8279–8289
Khdair A, Abu-Rumman G (2020) Sustainable environmental management and valorization options for olive mill byproducts in the middle East and North Africa (MENA) region. Processes 8(6):671
Khdair AI, Abu-Rumman G, Khdair SI (2019) Pollution estimation from olive mills wastewater in Jordan. Heliyon 5(8):e02386
Klisovicc D et al (2021) The utilisation solutions of olive mill by-products in the terms of sustainable olive oil production: a review. Int J Food Sci Technol 56(10):4851–4860
Koo B, Jung SP (2021) Improvement of air cathode performance in microbial fuel cells by using catalysts made by binding metal-organic framework and activated carbon through ultrasonication and solution precipitation. Chem Eng J 424:130388
Manisalidis I, et al. (2020) Environmental and health impacts of air pollution: a review. Front public health. p. 14
Mohammadi S et al (2015) Phenol removal from industrial wastewaters: a short review. Desalin Water Treat 53(8):2215–2234
Odeh F et al (2022) Coupling magnetite and goethite nanoparticles with sorbent materials for olive mill wastewater remediation. Emergent Mater 5(1):77–88
Ouazzane H et al (2017) Olive mill solid waste characterization and recycling opportunities: a review. J Mater Environ Sci 8(8):2632–2650
Park J-H et al (2020) Enhancing anaerobic digestion for rural wastewater treatment with granular activated carbon (GAC) supplementation. Biores Technol 315:123890
Pawar AA, et al. (2022) Microbial electrolysis cells for electromethanogenesis: Materials, configurations and operations. Environ Eng Res 27(1)
Rocha C, Soria MA, Madeira LM (2022) Olive mill wastewater valorization through steam reforming using multifunctional reactors: challenges of the process intensification. Energies 15(3):920
Roig A, Cayuela ML, Sánchez-Monedero M (2006) An overview on olive mill wastes and their valorisation methods. Waste Manage 26(9):960–969
Son S et al (2021) Comparison of hydrogen production and system performance in a microbial electrolysis cell containing cathodes made of non-platinum catalysts and binders. J Water Process Eng 40:101844
Tran HV, Kim E, Jung SP (2022) Anode biofilm maturation time, stable cell performance time, and time-course electrochemistry in a single-chamber microbial fuel cell with a brush-anode. J Ind Eng Chem 106:269–278
Vlyssides AG, Loizides M, Karlis PK (2004) Integrated strategic approach for reusing olive oil extraction by-products. J Clean Prod 12(6):603–611
Wang H, Ren ZJ (2013) A comprehensive review of microbial electrochemical systems as a platform technology. Biotechnol Adv 31(8):1796–1807
Zagklis DP et al (2015) Purification of olive mill wastewater phenols through membrane filtration and resin adsorption/desorption. J Hazard Mater 285:69–76
Zahid M et al (2022) Microbial desalination cell: desalination through conserving energy. Desalination 521:115381
Zorpas AA, Inglezakis VJ (2011) Intergraded applied methodology for the treatment of heavy polluted waste waters from olive oil industries. Appl Environ Soil Sci. 2011
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The authors are thankful to King Hussein Bin Talal University and Middle East University, Amman—Jordan, for all types of support.
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MAA-S, AA, DA-K, and MSA-H was involved in conceptualization; MSA-H and OAA-K helped in methodology; MAA-S and FA contributed to formal analysis; AFK and MEAE-H were involved in investigation; AFK and MEAE-H helped in writing—original draft preparation; FA helped in writing—review and editing; visualization. All authors have approved the submitted version.
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Al-Shaweesh, M.A., Awad, A., Al-Kabariti, D. et al. Dephenolization and discoloration of olive mill wastewater using coagulation, filtration, and hydrogen peroxide oxidation. Int. J. Environ. Sci. Technol. 20, 8763–8770 (2023). https://doi.org/10.1007/s13762-022-04578-x
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DOI: https://doi.org/10.1007/s13762-022-04578-x