ZnO-Loaded SA-g-Poly (AC-co-EBS) Hydrogel Nanocomposite as an Efficient Adsorption of Tetracycline and Phenol: Kinetics and Thermodynamic Models
Aseel Mushtak Aljeboree(1), Mohammed Kassim Al-Hussainawy(2*), Usama Salim Altimari(3), Shaymaa Abed Al-Hussein(4), Maha Daham Azeez(5), Ayad Fadhil Alkaim(6)
(1) Department of Chemistry, College of Sciences for Girls, University of Babylon, Hilla 51001, Iraq
(2) Ministry of Education, Directorate of Education Al-Muthanna, Al-Samawah, AL-Muthanna 66001, Iraq
(3) Department of Medical Laboratories Technology, AL-Nisour University College, Baghdad 10017, Iraq
(4) Department of Medical Laboratories Technology, Al-Manara College for Medical Sciences, Maysan 62001, Iraq
(5) National University of Science and Technology, Dhi Qar 64001, Iraq
(6) Department of Chemistry, College of Sciences for Girls, University of Babylon, Hilla 51001, Iraq
(*) Corresponding Author
Abstract
A synthetic superabsorbent polymer hydrogel nanocomposite was prepared by the free radical graft co-polymerization method. This study included the preparation of two surfaces: first sodium alginate-g-(acrylic acid-co-sodium; 4-ethenylbenzenesulfonate), SA-g-poly (Ac-co-EBS) hydrogel, and second surface hydrogel after zinc oxide loading SA-g-poly (Ac-co-EBS). Hydrogel nanocomposite was prepared from different monomers for the removal of pollutants. The physical characterizations of nanocomposite have been studied using several techniques like UV-vis, FTIR, FE-SEM, TEM, EDX, and XRD. The data from the adsorption study show that E% increases with increasing contact time, with the best agitation time of 1 h, after which the adsorption becomes constant. The increase in adsorbent amount 0.01–0.1 g, the percentage removal of tetracycline (TC) and phenol (PH) increased from 60.639–97.085 and 487.71–94.05%, respectively, and Qe decreased 606.39–97.08 to 487.1831–94.456 mg/g on hydrogel. The ∆H value is endothermic. All processes of adsorption are considered spontaneous, from a negative value of ∆G to a positive value of ∆S. The release of the TC drug was studied in conditions similar to those in the human body in terms of acidity and temperature. The cumulative release of TC drug in 3 h was 50.65%, 42.33%, pH = 7.5 and pH 1.2, respectively.
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[1] Abid Alradaa, Z.A., and Kadam, Z.M., 2021, Preparation, characterization and prevention biological pollution of 4 (4-benzophenylazo) pyrogallol and their metal complexes, IOP Conf. Ser.: Earth Environ. Sci., 790, 12038.
[2] Omran, A.R., Baiee, M.A., Juda, S.A., Salman, J.M., and AlKaim, A.F., 2016, Removal of Congo red dye from aqueous solution using a new adsorbent surface developed from aquatic plant (Phragmites australis), Int. J. ChemTech Res., 9 (4), 334–342.
[3] Mahmoud, M.E., El-Ghanam, A.M., Saad, S.R., and Mohamed, R.H.A., 2020, Promoted removal of metformin hydrochloride anti-diabetic drug from water by fabricated and modified nanobiochar from artichoke leaves, Sustainable Chem. Pharm., 18, 100336.
[4] Aljeboree, A.M., Alrazzak, N.A., Alqaraguly, M.B., Mahdi, M.A., Jasim, L.S., and Alkaim, A.F., 2020, Adsorption of pollutants by using low-cost (environment-friendly): Equilibrium, kinetics and thermodynamic studies: A review, Sys. Rev. Pharm., 11 (12), 1988–1997.
[5] Yazidi, A., Atrous, M., Edi Soetaredjo, F., Sellaoui, L., Ismadji, S., Erto, A., Bonilla-Petriciolet, A., Luiz Dotto, G., and Ben Lamine, A., 2020, Adsorption of amoxicillin and tetracycline on activated carbon prepared from durian shell in single and binary systems: Experimental study and modeling analysis, Chem. Eng. J., 379, 122320.
[6] Liu, H., Yang, Y., Sun, H., Zhao, L., and Liu, Y., 2018, Fate of tetracycline in enhanced biological nutrient removal process, Chemosphere, 193, 998–1003.
[7] Hamadneh, I., Abu-Zurayk, R.A., and Al-Dujaili, A.H., 2020, Removal of phenolic compounds from aqueous solution using MgCl2-impregnated activated carbons derived from olive husk: The effect of chemical structures, Water Sci. Technol., 81 (11), 2351–2367.
[8] Khalid Mahmoud, D., Mohd Salleh, M.A., and Wan Abdul Karim, W.A., 2012, Langmuir model application on solid–liquid adsorption using agricultural wastes: Environmental application review, J. Purity, Util. React. Environ., 1 (4), 170–199.
[9] Xie, J., Li, H., Zhang, T., Song, B., Wang, X., and Gu, Z., 2023, Recent advances in ZnO nanomaterial-mediated biological applications and action mechanisms, Nanomaterials, 13 (9), 1500.
[10] Xin, Z., He, Q., Wang, S., Han, X., Fu, Z., Xu, X., and Zhao, X., 2022, Recent progress in ZnO-based nanostructures for photocatalytic antimicrobial in water treatment: A review, Appl. Sci., 12 (15), 7910.
[11] Chavhan, J., Rathod, R., Tandon, V., Gupta, S., and Malav, J.K., 2022, Development of EPA/ZnO nanocomposites: Structural, physical, and electrochemical studies, Surf. Coat. Technol., 448, 128846.
[12] Al-Hussainawy, M.K., Sahb Mehdi, Z., Jasim, K.K., Alshamsi, H.A.H., Saud, H.R., and Kyhoiesh, H.A.K., 2022, A single rapid route synthesis of magnetite/chitosan nanocomposite: Competitive study, Results Chem., 4, 100567.
[13] Kyhoiesh, H.A.K., Al-Hussainawy, M.K., and Saud, H.R., 2022, Synthesis and characterization of polyacrylamide/crotonic acid and its composites with carbon nanotube and Rhodamine B, AIP Conf. Proc., 2398 (1), 030018.
[14] Waheeb, A.S., Alshamsi, H.A.H., Al-Hussainawy, M.K., and Saud, H.R., 2020, Myristica fragrans shells as potential low cost bio-adsorbent for the efficient removal of rose Bengal from aqueous solution: Characteristic and kinetic study, Indones. J. Chem., 20 (5), 1152–1162.
[15] Jebur, M.H., Albdere, E.A., Al-Hussainawy, M.K., Alwan, S.H., 2022, Synthesis and characterization of new 1,3-Oxazepine-4,7-dione compounds from 1,2-diaminobenzene, Int. J. Health Sci., 6, 4578–4589.
[16] Oladipo, A.A., and Gazi, M., 2014, Enhanced removal of crystal violet by low cost alginate/acid activated bentonite composite beads: Optimization and modelling using non-linear regression technique, J. Water Process Eng., 2, 43–52.
[17] Kyhoiesh, H.A.K., Al-Hussainawy, M.K., Waheeb, A.S., and Al-Adilee, K.J., 2021, Synthesis, spectral characterization, lethal dose (LD50) and acute toxicity studies of 1,4-Bis(imidazolylazo)benzene (BIAB), Heliyon, 7 (9), e07969.
[18] Karim, A.R., and Radia, N.D., 2022, Hydrogel/clay nanocomposites for removal of cationic organic dye from their aqueous solutions, HIV Nurs., 22 (2), 1936–1940.
[19] Al-Taweel, S.S., Saud, H.R., Kadhum, A.A.H., and Takriff, M.S., 2019, The influence of titanium dioxide nanofiller ratio on morphology and surface properties of TiO2/chitosan nanocomposite, Results Phys., 13, 102296.
[20] Mittal, H., Al Alili, A., Morajkar, P.P., and Alhassan, S.M., 2021, Graphene oxide crosslinked hydrogel nanocomposites of xanthan gum for the adsorption of crystal violet dye, J. Mol. Liq., 323, 115034.
[21] El Shafey, A.M., Abdel-Latif, M.K., and Abd El-Salam, H.M., 2021, The facile synthesis of poly (acrylate/acrylamide) titanium dioxide nanocomposite for groundwater ammonia removal, Desalin. Water Treat., 212, 61–70.
[22] Xiong, H.M., Xu, Y., Ren, Q.G., and Xia, Y.Y., 2008, Stable aqueous ZnO@polymer core−shell nanoparticles with tunable photoluminescence and their application in cell imaging, J. Am. Chem. Soc., 130 (24), 7522–7523.
[23] Badri, N., Chhiti, Y., Bentiss, F., and Bensitel, M., 2020, Synthesis and characterization of vanadium pentoxide on different metal oxides by the sol-gel process for application in the conversion of the SO2 to SO3, Moroccan J. Chem., 8 (3), 560–572.
[24] Aljeboree, A.M., and Alkaim, A.F., 2019, Comparative removal of three textile dyes from aqueous solutions by adsorption: As a model (corn-cob source waste) of plants role in environmental enhancement, Plant Arch., 19 (1), 1613–1620.
[25] Wang, F., Zeng, Q., Su, W., Zhang, M., Hou, L., and Wang, Z.L., 2019, Adsorption of bisphenol A on peanut shell biochars: The effects of surfactants, J. Chem., 2019, 2428505.
[26] Kim, D.G., Boldbaatar, S., and Ko, S.O., 2022, Enhanced adsorption of tetracycline by thermal modification of coconut shell-based activated carbon, Int. J. Environ. Res. Public Health, 19 (21), 13741.
[27] Zhang, X., Lin, X., He, Y., and Luo, X., 2019, Phenolic hydroxyl derived copper alginate microspheres as superior adsorbent for effective adsorption of tetracycline, Int. J. Biol. Macromol., 136, 445–459.
[28] Dehmani, Y., Dridi, D., Lamhasni, T., Abouarnadasse, S., Chtourou, R., and Lima, E.C., 2022, Review of phenol adsorption on transition metal oxides and other adsorbents, J. Water Process Eng., 49, 102965.
[29] Dehmani, Y., Lainé, J., Daouli, A., Sellaoui, L., Bonilla-Petriciolet, A., Lamhasni, T., Abouarnadasse, S., and Badawi, M., 2023, Unravelling the adsorption mechanism of phenol on zinc oxide at various coverages via statistical physics, artificial neural network modeling and ab initio molecular dynamics, Chem. Eng. J., 452, 139171.
[30] Koesnarpadi, S., Santosa, S.J., Siswanta, D., and Rusdiarso, B., 2017, Humic acid coated Fe3O4 nanoparticle for phenol sorption, Indones. J. Chem., 17 (2), 274–283.
[31] Alkaim, A.F., and Aljobree, A.M., 2020, White marble as an alternative surface for removal of toxic dyes (methylene blue) from aqueous solutions, Int. J. Adv. Sci. Technol., 29 (5), 5470–5479.
[32] Temel, F., Turkyilmaz, M., and Kucukcongar, S., 2020, Removal of methylene blue from aqueous solutions by silica gel supported calix[4]arene cage: Investigation of adsorption properties, Eur. Polym. J., 125, 109540.
[33] Tanhaei, B., Ayati, A., Iakovleva, E., and Sillanpää, M., 2020, Efficient carbon interlayed magnetic chitosan adsorbent for anionic dye removal: Synthesis, characterization and adsorption study, Int. J. Biol. Macromol., 164, 3621–3631.
[34] Liu, X., Wang, L., Zhou, X., He, X., Zhou, M., Jia, K., and Liu, X., 2021, Design of polymer composite-based porous membrane for in-situ photocatalytic degradation of adsorbed organic dyes, J. Phys. Chem. Solids, 154, 110094.
[35] Aljeboree, A.M., Alshirifi, A.N., and Alkaim, A.F., 2019, Activated carbon (as a waste plant sources)-clay micro/nanocomposite as effective adsorbent: Process optimization for ultrasound-assisted adsorption removal of amoxicillin drug, Plant Arch., 19 (Suppl. 2), 915–919.
[36] Chen, L., Ren, X., Alharbi, N.S., and Chen, C., 2021, Fabrication of a novel Co/Ni-MOFs@BiOI composite with boosting photocatalytic degradation of methylene blue under visible light, J. Environ. Chem. Eng., 9 (5), 106194.
[37] Xu, D., Zhang, Y., Zhang, S., Yang, W., Wang, Z., and Li, J., 2022, Copper nanoleaves SERS substrates with high surface roughness for sensitive detection crystal violet and rhodamine 6G, Opt. Laser Technol., 145, 107502.
[38] Al-Niaeem, H.S., Abdulwahid, A., and Hanoosh, W., 2022, Preparation of semi IPNs-hydrogel composite for removing Congo red and Bismarck Brown Y from wastewater: Kinetic and thermodynamic study, Egypt. J. Chem., 65 (1), 19–34.
[39] Osman, A.M., Hendi, A.H., and Saleh, T.A., 2020, Simultaneous adsorption of dye and toxic metal ions using an interfacially polymerized silica/polyamide nanocomposite: Kinetic and thermodynamic studies, J. Mol. Liq., 314, 113640.
[40] Omer, O.S., Hussein, M.A., Hussein, B.H.M., and Mgaidi, A., 2018, Adsorption thermodynamics of cationic dyes (methylene blue and crystal violet) to a natural clay mineral from aqueous solution between 293.15 and 323.15 K, Arabian J. Chem., 11 (5), 615–623.
[41] Chowdhury, S., Mishra, R., Saha, P., and Kushwaha, P., 2011, Adsorption thermodynamics, kinetics and isosteric heat of adsorption of malachite green onto chemically modified rice husk, Desalination, 265 (1-3), 159–168.
[42] Jan, S.U., Ahmad, A., Khan, A.A., Melhi, S., Ahmad, I., Sun, G., Chen, C.M., and Ahmad, R., 2021, Removal of azo dye from aqueous solution by a low-cost activated carbon prepared from coal: Adsorption kinetics, isotherms study, and DFT simulation, Environ. Sci. Pollut. Res., 28 (8), 10234–10247.
[43] del Mar Orta, M., Martín, J., Medina-Carrasco, S., Santos, J.L., Aparicio, I., and Alonso, E., 2019, Adsorption of propranolol onto montmorillonite: Kinetic, isotherm and pH studies, Appl. Clay Sci., 173, 107–114.
[44] Chowdhury, A., Kumari, S., Khan, A.A., Chandra, M.R., and Hussain, S., 2021, Activated carbon loaded with Ni-Co-S nanoparticle for superior adsorption capacity of antibiotics and dye from wastewater: Kinetics and isotherms, Colloids Surf., A, 611, 125868.
[45] Kevadiya, B.D., Joshi, G.V, Mody, H.M., and Bajaj, H.C., 2011, Biopolymer–clay hydrogel composites as drug carrier: Host–guest intercalation and in vitro release study of lidocaine hydrochloride, Appl. Clay Sci., 52 (4), 364–367.
[46] Aguzzi, C., Capra, P., Bonferoni, C., Cerezo, P., Salcedo, I., Sánchez, R., Caramella, C., and Viseras, C., 2010, Chitosan–silicate biocomposites to be used in modified drug release of 5-aminosalicylic acid (5-ASA), Appl. Clay Sci., 50 (1), 106–111.
DOI: https://doi.org/10.22146/ijc.86711
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