Pyro-processed Coconut Fibre for Removal of Lead Ions from Aqueous Solution
DOI:
https://doi.org/10.54536/ajcp.v5i1.7007Keywords:
Activated Coconut Fibre Charcoal, Adsorbent, Coconut Fibre Charcoal And LeadAbstract
Approximately 80% of the population in developing countries lacks access to clean, safe water. A major source of water contamination is heavy metal ions, which pose great risks to human health. This is expected to increase with the projected population and industrial growth if immediate remediation is not taken. Current operational methods for removing the heavy metal ions in wastewater include: chemical coagulation, ion exchange, electrochemical methods, adsorption using activated carbon, natural zeolite, membrane process, ultra-filtration, among others, which are uneconomical due to high costs and unaffordable to low-income earners. Coconut fibres are locally available agricultural waste that can be converted by activation into adsorbents for water remediation due to their fineness and large surface area. This study reports the synthesis and characterization of coconut fibre charcoal (CFC) and activated coconut fibre charcoal (ACFC) to remediate water contaminated with Pb2+ ions. This involved burning dry coconut fibre in a limited amount of air to obtain coconut fibre charcoal followed by dissolving fine powder of charcoal in 2 M phosphoric acid for 24 hours at a temperature of 25 ºC to obtain activated coconut fibre charcoal. The adsorbents were characterized using FT-IR and SEM. Batch sorption studies were carried out while varying parameters of contact time, shaking speed, temperature, adsorbent dose, pH, and initial concentration of metal ions in solution. Residue Pb2+ ion concentrations were determined using atomic absorption spectroscopy (AAS). The FT-IR results showed absorption peaks at 1423 cm-1 and 840 cm-1 attributed to symmetric –COO- stretch and -OH deformation in ACFC adsorbent, these peaks shifted to 1384 cm-1 and 813 cm-1 while PO4- aromatic strain vibration in ACFC disappeared upon saturation of ACFC with Pb2+ ions respectively. SEM analysis showed pores of different sizes and shapes in ACFC compared to a rigid, concrete, and smooth surface upon saturation with Pb2+ ions. Adsorption data for Pb2+ ions best fitted into the Freundlich model with maximum adsorption capacities of 32.09 mg lead/g activated coconut fibre charcoal. The results from this study suggest that coconut fibre charcoal and activated coconut fibre charcoal are potential adsorbents of Pb2+ions.
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Ahmed, H.M., Sobhy, N.A., and Hefny, M.M. (2023). Evaluation of agrowaste species for removal of heavy metals from synthetic wastewater. Journal of Environmental and Public Health, 1-20.
Argun, M. E., Dursun, S., Ozdemir, C., and Karatas, M. (2007). Heavy metal adsorption by modified oak sawdust: Thermodynamics and kinetics. Journal of Hazardous Materials, 141: 77–85.
Banerjee, S., Chattopadhyaya, M., Srivastava, V., Sharma, M. (2014). Adsorption studies of methylene blue onto activated saw dust: kinetics, equilibrium, and thermodynamic studies. Environmental Progress & Sustainable Energy, 33: 790-799
Bashir, A., Malik, L., Ahad, S., Manzoor, T., Bhat, M., Dar, G. (2019). Removal of heavy metal ions from aqueous system by ion-exchange and biosorption methods journal of Environmental chemistry 17: 729–754.
Edris, G., Alhamed, Y., and Alzahrani, A. (2012). Cadmium and Lead Biosorption by Chlorella Vulgaris. In Sixteenth International Water Technology Conference (IWTC 16); Istanbul, Turkey.
Feng, R., Zhao, P., Zhu, Y., Yang, J., Wei, X., Yang, L. (2021). Application of inorganic selenium to reduce accumulation and toxicity of heavy metals (metalloids) in plants: the main mechanisms, concerns, and risks. Journal of Environmental Science. 771: 144 - 776.
Habib K (2017). Effect of pH and initial pb (II) concentration on the lead removal efficiency from industrial wastewater using Ca(OH)2. International Journal of Wastewater Treat, 3:1–4.
Hammond, P., Ali, D. and Cumming, R. (2005). A system on chip digital pH meter for use in a wireless diagnostic capsule. Biomedical Engineering, 4: 687-694.
Jeyakumar, S., and Chandrasekaran, V. (2014). Adsorption of Lead (II) Ions By Activated Carbons Prepared from Marine Green Algae: Equilibrium and Kinetics Studies. International Journal of Industrial Chemistry, 5: 10.
Khanna, E., Shahjahana, and T. A., (2018). Adsorption of methyl red on activated carbon derived from custard apple (Annona squamosa) fruit shell: equilibrium isotherm and kinetic studies. Journal of molecular liquid, 249:1195-1211.
Krauklis, A., Gagani, A., and Echtermeyer, A. (2018). Near infrared spectroscopic method for monitoring water content in epoxy resins and fiber reinforced composite. Journal of Environmental Chemical Engineering, 11: 586–599.
Kumar, A., Kumar, A., Cabral-Pinto, M. (2020). Lead toxicity health hazards, influence on food chain, and sustainable remediation approaches. International Journal of Environmental Research and Public Health, 17:2179
Long, Z., Huang, Y., Zhang, W (2021) Effect of different indus-trial activities on soil heavy metal pollution, ecological risk, and health risk. Environmental Monitoring and Assessment 193:1–12
Luo, X., Li, C., Müller., K., Yu, H., Huang, P., Li, T., sang, T., Bolan, N., Rinklebe J., Wang H. (2018). Sorption of norfloxacin, sulfamerazine and oxytetracycline by KOH-modified biochar under single and ternary systems. Bioresource Technology, 263: 385-392.
Meez, E., Rahdar, A., and Kyzas, G. (2021). Sawdust for the Removal of Heavy Metals from Water, journal of Review. Molecules, 26(14): 4318.
Mureithi, G., Onindo, O. and Muthakia, G. (2012). Kinetic and equilibrium study for the sorption of Pb (II) ions from aqueous phase by water hyacinth (Eichhorniacrassipes). Bulletin of the Chemical Society of Ethiopia, 2: 181-193.
Nleonu, E.C., Onyemenonu, C.C., Okeke, P.I. and Opara, J.N. (2023). Adsorption characteristics of Chrysophyllumalbidum (African Star Apple) peels towards heavy metal ions. Journal of Chemical Review and Letters, 6: 44-54.
Pap, S., Kirk, C., Bremner, B., Maja, M., and Taggart, M (2020). Low-cost chitosan-calcite adsorbent development for potential phosphate removal and recovery from wastewater effluent. Journal of water research, 173: 115573-115586.
Peng, L., and Bartzas, G. (2021). Editorial overview: heavy metals and metalloids: a serious threat to environment and human health. Environmental Health Science, 23: 100287. 2468-5844.
Petrella, A., Spasiano, D., Acquafredda, P., De Vietro, N., Ranieri, E., Cosma, P., Rizzi, V., Petruzzelli, V. and Petruzzelli, D., (2018). Heavy metals Retention Pb(II), Cd(II) from single and multi-metal solution by natural biosorbents from the Olive oil milling operations. Process Safety and Environment Protection, 114: 79-90.
Qasem, N., Mohammed, R., and Lawal, D. (2021). Removal of heavy metal ions from wastewater: a comprehensive and critical review. Journal of Clean. Water, 4: 36.
Renu, Agarwal, M., and Singh, K. (2017). Heavy metal removal from waste-water using various adsorbents, journal of water reuse and desalination, 7(4): 387–419.
Senthil, K. P., Ramakrishnan, K., Kirupha, S. D., and Sivanesan, S. (2010). Thermodynamic and Kinetic Studies of Cadmium Adsorption from Aqueous Solution onto Rice Husk. Brazilian Journal of Chemical Engineering, 27: 347–355.
Singh, J., and Kaur, G. (2013). Freundlich , Langmuir adsorption isotherms and kinetics for the removal of malachite green from aqueous solutions using agricultural waste rice straw. International Journal of Environmental Sciences, 4: 250–258.
Titus, M., Harun, M. and Maingi, F.M. (2022). Evaluation of Activated Charcoal Based Hydrogels Functionalized with Maleic Acid on Growth Performance of Zea Mays in Semi-arid Regions of Kenya. International Journal of Agriculture & Environmental Science, 9(3), 69-76.
Wang, X., Ren, H., Sun, L., Ma, H., Zhu, J. (2016). Sorption of polychlorinated biphenyls onto bio chars derived from corn straw and the effect of propranolol. Bio resource Technology, 219: 458-465.
Xiao, X., Liu, X., Zhang, S., and Zheng, S. (2017). Phosphorus removal and recovery from secondary effluent in sewage treatment plant by magnetite mineral micro particles, Powder technology, 306: 68-73.
Zahid, ZM., Athar, A., Uzma, U. (2017). Sorption studies of cadmium ions on alginate-calcium carbonate composite beads. Journal of Applied Water Science, 7:915–922.
Zhu, S., Wang, J., Yan, H., Wang, Y., Zhao, Y., Feng, B., Duan, K. and Weng, J. (2017). An injectable supramolecular self-healing bio-hydrogel with high stretch ability, extensibility and ductility, and a high swelling ratio. Journal of Material Chemistry, 5: 7021.
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Copyright (c) 2026 Titus M. Kasimu, Francis M. Maingi, Harun M. Mbuvi, Margaret M. Ng’ang’a, Adamu Abdulhameed
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