Studies to determine the optimal coagulant dosage for the precipitation of landfill leachate pollutant
DOI:
https://doi.org/10.3846/enviro.2026.1709Abstract
The treatment of landfill leachate is a critical environmental, social and economic issue. This type of wastewater poses a threat to the environment and human health, so European standards (Council Directive 1999/31/EC on landfill, Water Framework Directive) require its mandatory treatment. Landfill leachate is composed of different toxins and complex chemicals due to the presence of different kinds of pollutants and trash. These toxins and pollutants include heavy metals, organic pollutants, ammonium nitrogen, and xenobiotic compounds. Due to this complexity and variation in the chemical composition, conventional treatment methods such as bio-logical treatment and membrane separation often face various challenges. To address these challenges, the combination of treatment methods such as coagulation/flocculation as pretreatment followed by adsorption techniques has shown promising results in removing all the toxins at a much lower price using natural materials. This combination ensures the removal of suspended solids and colloidal matter trapped in the leachate using coagulation; the remaining dissolved organic and inorganic matter are removed by the adsorption stage. The uncertainties lie in the fact that it is not known exactly which coagulants, and at what doses, would optimally reduce the amount of organic matter in the landfill filtrate. Experimental studies are being conducted to select suitable coagulants. In this study, Al2(SO4)3 and Fe2(SO4)3 metal salt coagulants were selected for the coagulation stage. At the optimal dosages of Al2(SO4)3, a maximum TC removal of 60% was achieved, whereas Fe2(SO4)3 achieved a slightly higher value of about 62%. On the other hand, low TN removal efficiencies were achieved for both coagulants after the coagulation process alone, not exceeding 11%, confirming that coagulation process alone is insufficient for effective nitrogen removal. Subsequent adsorption stage significantly improved the treatment performance using ZMT, as overall TN removal exceeded 90% for both coagulants at the optimal doses, while the overall TC removal remains slightly effected.
Keywords:
landfill leachate, treatment, coagulants, organic matter, adsorptionHow to Cite
Abdel-Shafy, H. I., Ibrahim, A. M., Al-Sulaiman, A. M., & Okasha, R. A. (2024). Landfill leachate: Sources, nature, organic composition, and treatment: An environmental overview. Ain Shams Engineering Journal, 15(1), Article 102293. https://doi.org/10.1016/J.ASEJ.2023.102293
Abdel-Shafy, H. I., & Mansour, M. S. M. (2018). Solid waste issue: Sources, composition, disposal, recycling, and valorization. Egyptian Journal of Petroleum, 27, 1275–1290. https://doi.org/10.1016/j.ejpe.2018.07.003
Ahmed, Z., Yusoff, M. S., & Mokhtar, K. N. H. (2020). Application of natural coagulants for sustainable treatment of semi-aerobic landfill leachate. AIP Conference Proceedings, 2267(1), Article 020024. https://doi.org/10.1063/5.0017406
Al-Yaqout, A., & Hamoda, M. F. (2020). Long-term temporal variations in characteristics of leachates from a closed landfill in an arid region. Water, Air, & Soil Pollution, 231(6), Article 319. https://doi.org/10.1007/S11270-020-04688-7
Bai, F., Tian, H., Wang, C., & Ma, J. (2023). Treatment of nanofiltration concentrate of landfill leachate using advanced oxidation processes incorporated with bioaugmentation. Environmental Pollution, 318, Article 120827. https://doi.org/10.1016/j.envpol.2022.120827
Bayat, M. E., Bilgin, O. N., Varank, G., Yazici Guvenc, S., & Can-Güven, E. (2023). Efficient treatment of landfill leachate membrane bioreactor effluent through sequential coagulation–flocculation and electrooxidation. Environmental Science: Water Research & Technology, 9(9), 2253–2262. https://doi.org/10.1039/D3EW00290J
Chen, W., Gu, Z., Wen, P., & Li, Q. (2019). Degradation of refractory organic contaminants in membrane concentrates from landfill leachate by a combined coagulation-ozonation process. Chemosphere, 217, 411–422. https://doi.org/10.1016/j.chemosphere.2018.11.002
Daud, N. M., Abdullah, S. R. S., Hasan, H. A., Othman, A. R., & Ismail, N. ‘I. (2023). Coagulation-flocculation treatment for batik effluent as a baseline study for the upcoming application of green coagulants/flocculants towards sustainable batik industry. Heliyon, 9(6), Article e17284. https://doi.org/10.1016/j.heliyon.2023.e17284
de Carvalho Izidoro, J., Botelho Junior, A. B., Muracami, H. T. Rodrigues Bertolini, T. C., Chaparro Rodrigues, R. P., Silva, K., Ortega, M. G. C., Fungaro, D. A., Espinosa, D. C. R., & Tenório, J. A. S. (2024). Green nanomaterial-based adsorbent for Cs and Pb removal: Synthesis from industrial waste producing high-value products. Separation Science and Technology, 59(6–9), 909–920. https://doi.org/10.1080/01496395.2024.2349188
Genethliou, C., Tatoulis, T., Charalampous, N., Dailianis, S., Tekerlekopoulou, A. G., & Vayenas, D. V. (2023). Treatment of raw sanitary landfill leachate using a hybrid pilot-scale system comprising adsorption, electrocoagulation and biological process. Journal of Environmental Management, 330, Article 117129. https://doi.org/10.1016/j.jenvman.2022.117129
He, H., Zhang, C., Yang, X., Huang, B., Zhe, J., Lai, C., Liao, Z., & Pan, X. (2023). The efficient treatment of mature landfill leachate using tower bipolar electrode flocculation-oxidation combined with electrochemical biofilm reactors. Water Research, 230, Article 119544. https://doi.org/10.1016/j.watres.2022.119544
Hidayu, A. R., & Muda, N. (2016). Preparation and characterization of impregnated activated carbon from palm kernel shell and coconut shell for CO2 capture. Procedia Engineering, 148, 106–113. https://doi.org/10.1016/j.proeng.2016.06.463
Izidoro, J. d. C., Kim, M. C., Bellelli, V. F., Pane, M. C., Botelho Junior, A. B., Espinosa, D. C. R., & Tenório, J. A. S. (2019). Synthesis of zeolite A using the waste of iron mine tailings dam and its application for industrial effluent treatment. Journal of Sustainable Mining, 18(4), 277–286. https://doi.org/10.1016/j.jsm.2019.11.001
Jagadeesh, N., & Sundaram, B. (2023). Adsorption of pollutants from wastewater by biochar: A review. Journal of Hazardous Materials Advances, 9, Article 100226. https://doi.org/10.1016/j.hazadv.2022.100226
Januševičius, T., Mažeikienė, A., Danila, V., & Paliulis, D. (2024). The characteristics of sewage sludge pellet biochar prepared using two different pyrolysis methods. Biomass Conversion and Biorefinery, 14(1), 891–900. https://doi.org/10.1007/s13399-021-02295-y
Kumar, A., Yadav, K. D., & Kumar, S. (2025). Comprehensive review on technological advances in landfill leachate management: Physico-chemical characteristics, treatment methods and cost analysis. Bioresource Technology Reports, 31, Article 102222. https://doi.org/10.1016/j.biteb.2025.102222
Mažeikienė, A., Vaiškūnaitė, R., & Šarko, J. (2021). Sand from groundwater treatment coated with iron and manganese used for phosphorus removal from wastewater. Science of the Total Environment, 764, Article 142915. https://doi.org/10.1016/j.scitotenv.2020.142915
Mor, S., & Ravindra, K. (2023). Municipal solid waste landfills in lower- and middle-income countries: Environmental impacts, challenges and sustainable management practices. Process Safety and Environmental Protection, 174, 510–530. https://doi.org/10.1016/j.psep.2023.04.014
Narendra, K. R., Shetty, S. J., Prashant, S., Gurumurthy, S. C., & Biliangadi, N. B. (2025). Landfill leachate treatment by incorporating MWCNTs assisted adsorption and coagulation process. Emergent Materials, 8, 1659–1669. https://doi.org/10.1007/S42247-024-00858-z
Satyam, S., & Patra, S. (2024). Innovations and challenges in adsorption-based wastewater remediation: A comprehensive review. Heliyon, 10(9), Article e29573. https://doi.org/10.1016/j.heliyon.2024.e29573
SHIMADZU. (n.d.). Total organic carbon / total nitrogen analyzers. Retrieved January 12, 2026, from https://www.shimadzu.com/
Somashekara, D., & Mulky, L. (2023). Sequestration of contaminants from wastewater: A review of adsorption processes. ChemBioEng Reviews, 10(4), 491–509. https://doi.org/10.1002/cben.202200050
Sossou, K., Bala Prasad, S., Agbotsou, K. E., Saidou Souley, H., & Mudigandla, R. (2024). Characteristics of landfill leachate and leachate treatment by biological and advanced coagulation process: Feasibility and effectiveness – An overview. Waste Management Bulletin, 2(2), 181–198. https://doi.org/10.1016/j.wmb.2024.04.009
Tchobanoglous, G., Cotruvo, J., Crook, E., McDonald, A., Olivieri, A., Salveson, R. S., & Trusselll, R. R. (2015). Framework for direct potable reuse. Alexandria, WateReuse Research Foundation, VA.
Wang, J., & Qiao, Z. (2024). A comprehensive review of landfill leachate treatment technologies. Frontiers in Environmental Science, 12, Article 1439128. https://doi.org/10.3389/fenvs.2024.1439128
Yu, D., Pei, Y., Ji, Z., He, X., & Yao, Z. (2022). A review on the landfill leachate treatment technologies and application prospects of three-dimensional electrode technology. Chemosphere, 291, Article 132895. https://doi.org/10.1016/j.chemosphere.2021.132895
Downloads
CrossMark check
Published
Conference Event
Section
Copyright
License
This work is licensed under a Creative Commons Attribution 4.0 International License.
Vilnius Gediminas Technical University
Nordic Geodetic Commission
International Federation of Surveyors
European Sustainable Energy Innovation Alliance
New European Bauhaus Academy
The Lithuanian Roads Association
Lithuanian Water Suppliers Association
Bentley
AB "Kauno tiltai"
UAB "Kerista"
UAB "Danfoss"
UAB "EMP recycling"
UAB "ACO Lietuva"
UAB "Arginta"
UAB "Skadec LT"
UAB "GPS partneris"
UAB "Hnit-Baltic"
AB "Eurovia Lietuva"
VšĮ "RV Agentūra"
UAB "GeoNovus"