The removal of heavy metals from water is a key environmental challenge. This study focuses on synthesizing and using Schiff base-modified cellulose as adsorbents for cadmium (Cd) and lead (Pb) ions. The materials were developed by modifying cellulose and incorporating Schiff base ligands with Fe(III) and Zn(II) binding sites (Schiffs 1 and 2). Characterization through EDX, SEM, FT-IR, elemental analysis, XRD, and TGA confirmed improved surface properties and active adsorption sites. Adsorption followed pseudo-second-order kinetics, indicating chemisorption. The monolayer adsorption capacities for Schiff 1 were 83 mg/g Cd and 78 mg/g Pb, while for Schiff 2, they were 70 mg/g Cd and 63 mg/g Pb. Optimal conditions included solution pH 4.0–5.0, stirring for 45–60 min, 100 mg/L metal concentration, and room temperature (25 ± 2 °C). EDTA efficiently desorbed Cd and Pb for 4 cycles with over 85% efficiency. This study highlights the material’s potential as a cost-effective and eco-friendly solution for wastewater treatment.

[1] Li, C., Yu, Y., Fang, A., Feng, D., Du, M., Tang, A., Chen, S., and Li, A., 2022, Insight into biosorption of heavy metals by extracellular polymer substances and the improvement of the efficacy: A review, Lett. Appl. Microbiol., 75 (5), 1064–1073.

[2] Rajendran, S., Priya, A.K., Senthil Kumar, P., Hoang, T.K.A., Sekar, K., Chong, K.Y., Khoo, K.S., Ng, H.S., and Show, P.L., 2022, A critical and recent developments on adsorption technique for removal of heavy metals from wastewater-A review, Chemosphere, 303 (Pt. 2), 135146.

[3] Okatch, H., Ghimirey, A., Lam, H., Nkala, J.J., Raseipei, P., and Regis, N., 2023, Identifying contextually relevant lead exposures and risk practices/behaviors in Botswana and assessing caregiver lead knowledge levels, Cogent Public Health, 10 (1), 2211725.

[4] Nam, Y.S., Alex-Oni, K., Fitzstevens, M., Patel, K., and Hore, P., 2025, Advancing public health interventions: A novel surveillance system for hazardous consumer products, J Public Health Manage. Pract., 31 (3), 372–376.

[5] Ibrahim, F.M., Najeeb, D.A., and ThamerSadeq, H., 2023, Green preparation of Cu nanoparticles of the avocado seed extract as an adsorbent surface, Mater. Sci. Energy Technol., 6, 130–136.

[6] Razzak, S.A., Faruque, M.O., Alsheikh, Z., Alsheikhmohamad, L., Alkuroud, D., Alfayez, A., Hossain, S.M.Z., and Hossain, M.M., 2022, A comprehensive review on conventional and biological-driven heavy metals removal from industrial wastewater, Environ. Adv., 7, 100168.‏

[7] Kumar, P., Abbas, Z., Kumar, P., Das, D., and Mobin, S.M., 2024, Highlights in interface of wastewater treatment by utilizing metal organic frameworks: Purification and adsorption kinetics, Langmuir, 40 (10), 5040–5059.‏

[8] Yuan, Y., Li, R., and Peng, S., 2023, Research progress on chemical modification of waste biomass cellulose to prepare heavy metal adsorbents, Polym. Bull., 80 (11), 11671–11700.

[9] Rashid, R., Shafiq, I., Akhter, P., Iqbal, M.J., and Hussain, M., 2021, A state-of-the-art review on wastewater treatment techniques: The effectiveness of adsorption method, Environ. Sci. Pollut. Res., 28 (8), 9050–9066.

[10] Alhaithloul, H.A.S., Alsudays, I.M., Zaki, E.G., Elsaeed, S.M., Mubark, A.E., Salib, L., Safwat, G., Niedbała, G., Diab, A., Abdein, M.A., Alharthi, A., Zakai, S.A., and Elkelish, A., 2024, Retrieval of Cu²⁺ and Cd²⁺ ions from aqueous solutions using sustainable guar gum/PVA/montmorillonite nanocomposite films: Effect of temperature and adsorption isotherms, Front. Chem., 12, 1393791.

[11] Annu, A., Mittal, M., Tripathi, S., and Shin, D.K., 2024, Biopolymeric nanocomposites for wastewater remediation: An overview on recent progress and challenges, Polymers, 16 (2), 294.‏

[12] Ibrahim, F.M., and Abdalhadi, S.M., 2021, Performance of Schiff bases metal complexes and their ligand in biological activity: A review, Al-Nahrain J. Sci., 24 (1), 1–10.

[13] Etale, A., Onyianta, A.J., Turner, S.R., and Eichhorn, S.J., 2023, Cellulose: A review of water interactions, applications in composites, and water treatment, Chem. Rev., 123 (5), 2016–2048.

[14] Ahmad, S.M., Ibrahim, F.M., Adnan Hasan, A., Mawlood Mikhlif, H., Saad Jwad, R., Alhuwaymil, Z., Alshareef, S.A., Alyami, M.S.S., Al-Mashhadani, M.H., and Kommanaboyina, S., 2024, Fluorescent properties of chitosan-stabilized bisdemethoxycurcumin-silver nanoparticles: Synthesis and characterization, Results Chem., 10, 101719.

[15] Kaur, J., Sengupta, P., and Mukhopadhyay, S., 2022, Critical review of bioadsorption on modified cellulose and removal of divalent heavy metals (Cd, Pb, and Cu), Ind. Eng. Chem. Res., 61 (5), 1921–1954.

[16] Olawale, S.A., Bonilla-Petriciolet, A., Mendoza-Castillo, D.I., Okafor, C.C., Sellaoui, L., and Badawi, M., 2022, Thermodynamics and mechanism of the adsorption of heavy metal ions on keratin biomasses for wastewater detoxification, Adsorpt. Sci. Technol., 2022, 7384924.‏

[17] Abd El-Sayed, E.S., Dacrory, S., Essawy, H.A., Ibrahim, H.S., Ammar, N.S., and Kamel, S., 2023, Sustainable grafted chitosan-dialdehyde cellulose with high adsorption capacity of heavy metal, BMC Chem., 17 (1), 117.‏

[18] Yue, X., Huang, J., Jiang, F., Lin, H., and Chen, Y., 2019, Synthesis and characterization of cellulose-based adsorbent for removal of anionic and cationic dyes, J. Eng. Fibers Fabr., 14, 1558925019828194.

[19] Sharma, P., Jain, R., Premi, A., Kumar, N., and Parashar, A., 2022, Linear and non-linear regression analysis for the sorption kinetics of Tropaeoline 000 onto nano talc, Int. J. Environ. Anal. Chem., 102 (9), 2152–2167.

[20] Ben Haj Fraj, S., Ferlazzo, S., El Haskouri, A., Neri, J., and Baouab, M.H.V., 2023, New fluorescent Schiff base modified nanocellulose-based chemosensors for the selective detection of Fe³⁺, Zn²⁺ and Cu²⁺ in semi-aqueous media and application in seawater sample, Int. J. Biol. Macromol., 253, 127762.

[21] Ren, L., Yang, Z., Huang, L., He, Y., Wang, H., and Zhang, L., 2020, Macroscopic poly Schiff base-coated bacteria cellulose with high adsorption performance, Polymers, 12 (3), 714.

[22] Sun, Q., Dong, X., Meng, Q., Xu, J., Wang, T., 2024, Reversible Schiff base chemistry in arginine-grafted regenerated cellulose hydrogel: Integration of chitosan and zinc ions for enhanced hemostasis, antibacterial action, and accelerated wound healing, ACS Appl. Bio Mater., 7 (10), 7030–7039.

[23] Alhalili, Z., and Abdelrahman, E.A., 2024, Efficient removal of Zn(II) ions from aqueous media using a facilely synthesized nanocomposite based on chitosan Schiff base, Sci. Rep., 14 (1), 17598.

[24] Kumar, R., and Sharma, R.K., 2019, Synthesis and characterization of cellulose based adsorbents for removal of Ni(II), Cu(II) and Pb(II) ions from aqueous solutions, React. Funct. Polym., 140, 82–92.

[25] Xu, Y., Shi, Y., Lei, F., and Dai, L., 2020, A novel and green cellulose-based Schiff base-Cu(II) complex and its excellent antibacterial activity, Carbohydr. Polym., 230, 115671.

[26] Meng, P., Zhang, T., Su, Y., Peng, D., Zhou, Q., Zeng, H., Yu, H., Lun, L., Zhang, N., Zhang, L., and Zheng, L., 2024, Cellulose-based materials in the treatment of wastewater containing heavy metal pollution: Recent advances in quantitative adsorption mechanisms, Ind. Crops Prod., 217, 118825.

[27] Elwakeel, K.Z., Elgarahy, A.M., and Mohammad, S.H., 2017, Magnetic Schiff's base sorbent based on shrimp peels wastes for consummate sorption of chromate, Water Sci. Technol., 76 (1), 35–48.

[28] Kaur, M., Kumar, S., Yusuf, M., Lee, J., Malik, A.K., Ahmadi, Y., and Kim, K.H., 2023, Schiff base-functionalized metal-organic frameworks as an efficient adsorbent for the decontamination of heavy metal ions in water, Environ. Res., 236, 116811.

[29] Son, D., Cho, S., Nam, J., Lee, H., and Kim, M., 2020, X-ray-based spectroscopic techniques for characterization of polymer nanocomposite materials at a molecular level, Polymers, 12 (5), 1053.

[30] Saberi-Zare, M., and Bodaghifard, M.A., 2025, A Schiff base-functionalized chitosan magnetic bio-nanocomposite for efficient removal of Pb(II) and Cd(II) ions from aqueous solutions, Int. J. Biol. Macromol., 296, 139794.

[31] Kenawy, E.R., Azaam, M.M., Afzal, M., Khatoon, A., Ansari, M.T., and Hasnain, M.S., 2020, “Pharmaceutical Application of Cellulose Derivatives” in Tailor-Made Polysaccharides in Biomedical Applications, Eds. Nayak, A., Hasnain, M.S., and Aminabhavi, T., Academic Press, Cambridge, MA, US, 305–328.

[32] Poletto, M., Pistor, V., and Zattera, A.J., 2013, “Structural Characteristics and Thermal Properties of Native Cellulose” in Cellulose - Fundamental Aspects, Eds. Van De Ven, T.G.M., and Godbout, L., IntechOpen, Rijeka, Croatia.

[33] Verma, C., Singh, V., and AlFantazi, A., 2024, Cellulose, cellulose derivatives and cellulose composites in sustainable corrosion protection: Challenges and opportunities, Phys. Chem. Chem. Phys., 26 (15), 11217–11242.

[34] Jenisha, J., David, S.T., and Priyadharsini, J.P., 2015, Schiff base ligand its complexes and their FT-IR spectroscopy studies, Int. J. Appl. Bioeng., 9 (1), 1–4.

[35] Fakhre, N.A., and Ibrahim, B.M., 2018, The use of new chemically modified cellulose for heavy metal ion adsorption, J. Hazard. Mater., 343, 324–331.

[36] Saravanan, R., and Ravikumar, L., 2015, The use of new chemically modified cellulose for heavy metal ion adsorption and antimicrobial activities, J. Water Resour. Prot., 7 (6), 530–545.

[37] Coates, J., 2006, “Interpretation of Infrared Spectra, A Practical Approach” in Encyclopedia of Analytical Chemistry, John Wiley & Sons, Hoboken, New Jersey, US.

[38] Patil, M.K., Masand, V.H., and Maldhure, A.K., 2021, Schiff base metal complexes precursor for metal oxide nanomaterials: A review, Curr. Nanosci., 17 (4), 634–645.‏

[39] Oyewo, O.A., Nevondo, N.G., Onwudiwe, D.C., and Onyango, M.S., 2021, Photocatalytic degradation of methyl blue in water using sawdust-derived cellulose nanocrystals-metal oxide nanocomposite, J. Inorg. Organomet. Polym. Mater., 31 (6), 2542–2552.

[40] Di Bernardo, P., Zanonato, P.L., Tamburini, S., Tomasin, P., and Vigato, P.A., 2006, Complexation behaviour and stability of Schiff bases in aqueous solution. The case of an acyclic diimino(amino) diphenol and its reduced triamine derivative, Dalton Trans., (39), 4711–4721.

[41] Gharamaleki, J.A., Akbari, F., Karbalaei, A., Ghiassi, K.B., and Olmstead, M.M., 2016, Synthesis, characterization and crystal structure of a new Schiff base ligand from a bis(thiazoline) template and hydrolytic cleavage of the imine bond induced by a Co(II) cation, Open J. Inorg. Chem., 6 (1), 76–88.

[42] Wang, L.K., Wang, M.H.S., Hung, Y.T., Shammas, N.K., and Chen, J.P., 2017, Handbook of Advanced Industrial and Hazardous Wastes Management, 1^st Ed., CRC Press, Boca Raton, FL, US.

[43] Kyzas, G.Z., and Matis, K.A., 2015, Nanoadsorbents for pollutants removal: A review, J. Mol. Liq., 203, 159–168.

[44] Bhatnagar, A., and Sillanpää, M., 2010, Utilization of agro-industrial and municipal waste materials as potential adsorbents for water treatment—A review, Chem. Eng. J., 157 (2-3), 277–296.

[45] Khalil, M.M.H., Ismail, E.H., Mohamed, G.G., Zayed, E.M., and Badr, A., 2012, Synthesis and characterization of a novel Schiff base metal complexes and their application in determination of iron in different types of natural water, Open J. Inorg. Chem., 2 (2), 13–21.

[46] Barakat, M.A., 2011, New trends in removing heavy metals from industrial wastewater, Arabian J. Chem., 4 (4), 361–377.

[47] Somorjai, G.A., and Li, Y., 2010, Introduction to Surface Chemistry and Catalysis, John Wiley & Sons, Hoboken, NJ, US.

[48] Foo, K.Y., Hameed, B.H., 2010, Insights into the modelling of adsorption isotherm systems, Chem. Eng. J., 156 (1), 2–10.

[49] Mardani, H.R., Ravari, F., Kalaki, A., and Hokmabadi, L., 2020, New Schiff-base’s modified chitosan: Synthesis, characterization, computational, thermal study and comparison on adsorption of copper(II) and nickel(II) metal ions in aqueous, J. Polym. Environ., 28 (9), 2523–2538.

[50] Nyamato, G.S., Kabogo, I.T., Maqinana, S., Bachmann, R., Schmitz, M., Ogunah, J., Kleist, W., and Ojwach, S.O., 2024, Removal, mechanistic and kinetic studies of Cr(VI), Cd(II), and Pb(II) cations using Fe₃O₄ functionalized Schiff base chelating ligands, Environ. Sci. Pollut. Res., 31 (54), 63374–63392.

[51] El Mahdaoui, A., Radi, S., Elidrissi, A., Faustino, M.A.F., Neves, M.G.P.M.S., and Moura, N.M.M., 2024, Progress in the modification of cellulose-based adsorbents for the removal of toxic heavy metal ions, J. Environ. Chem. Eng., 12 (5), 113870.

[52] Ho, Y.S., and McKay, G., 1999, Pseudo-second order model for sorption processes, Process Biochem., 34 (5), 451–465.

[53] Zayed, E.M., Zayed, M.A., and Hindy, A.M.M., 2014, Thermal and spectroscopic investigation of novel Schiff base, its metal complexes, and their biological activities, J. Therm. Anal. Calorim., 116 (1), 391–400.

[54] Naiya, T.K., Bhattacharya, A.K., Mandal, S., and Das, S.K., 2009, The sorption of lead(II) ions on rice husk ash, J. Hazard. Mater., 163 (2-3), 1254–1264.

[55] Chen, D., Wang, X., Wang, X., Feng, K., Su, J., and Dong, J., 2020, The mechanism of cadmium sorption by sulphur-modified wheat straw biochar and its application cadmium-contaminated soil, Sci. Total Environ., 714, 136550.

[56] Kazemian, H., Gedik, K., and İmamoğlu, İ., 2012, “Environmental Applications of Natural Zeolites” in Handbook of Natural Zeolites, Bentham Science Publishers,‏ Sharjah, UAE, 473–508.

[57] Carmalin Sophia, A., Arfin, T., and Lima, E.C., 2019, “Recent Developments in Adsorption of Dyes Using Graphene Based Nanomaterials” in A New Generation Material Graphene: Applications in Water Technology, Eds. Naushad, M., Springer, Cham, Switzerland, 439–471.

[58] Sutherland, C., and Venkobachar, C., 2020, Regeneration of a chemically improved peat moss for the removal and recovery of Cu(II) and Pb(II) from aqueous solution, Desalin. Water Treat., 178, 172–181.

[59] Mubark, A.E., Zaki, E.G., Hakem, H.A., Abdel-Rahman, A.A.H., Elsaeed, S.M., and Elkelish, A., 2025, Guar gum hydrogel as a biosorbent for Cd(II) and Cu(II) ions: Kinetic, equilibrium, and thermodynamic insights, ChemistrySelect, 10 (3), e202404817.

[60] Hasankola, Z.S., Rahimi, R., and Safarifard, V., 2019, Rapid and efficient ultrasonic-assisted removal of lead(II) in water using two copper-and zinc-based metal-organic frameworks, Inorg. Chem. Commun., 107, 107474.

[61] Molaudzi, N.R., and Ambushe, A.A., 2022, Sugarcane bagasse and orange peels as low-cost biosorbents for the removal of lead ions from contaminated water samples, Water, 14 (21), 3395.

[62] Kumar, S., Gunasekar, V., and Ponnusami, V., 2013, Removal of methylene blue from aqueous effluent using fixed bed of groundnut shell powder, J. Chem., 2013 (1), 259819.

[63] Darabdhara, J., and Ahmaruzzaman, M., 2022, Recent developments in MOF and MOF based composite as potential adsorbents for removal of aqueous environmental contaminants, Chemosphere, 304, 135261.