Ionic Surfactant Enhancement of Clay Properties for Heavy Metals Adsorption: Kinetics and Isotherms

https://doi.org/10.22146/ijc.59480

Adekeye Damilola Kayode(1*), Asaolu Samuel Sunday(2), Adefemi Samuel Oluyemi(3), Ibigbami Olayinka Abidemi(4), Akinsola Abiodun Folasade(5), Awoniyi Marcus Gbolahan(6), Popoola Olugbenga Kayode(7)

(1) Department of Chemistry, Ekiti State University, Ado-Ekiti, Nigeria
(2) Department of Chemistry, Ekiti State University, Ado-Ekiti, Nigeria
(3) Department of Chemistry, Ekiti State University, Ado-Ekiti, Nigeria
(4) Department of Chemistry, Ekiti State University, Ado-Ekiti, Nigeria
(5) Department of Industrial Chemistry, Ekiti State University, Ado-Ekiti, Nigeria
(6) Department of Biosciences, University of Nottingham, Nottingham, United Kingdom
(7) Department of Chemistry, Ekiti State University, Ado-Ekiti, Nigeria
(*) Corresponding Author

Abstract


The global health problems arising from ingesting toxic metals necessitate the quest for developing efficient materials for their remediation. Surface properties of raw kaolinite clay collected from Ire-Ekiti, South-western Nigeria, were improved by modification using sodium dodecyl sulphate (SDS) for the adsorptive removal of Pb, Cr, Ni and Cu from their respective aqueous solution. The raw and modified clays were characterized by X-ray fluorescence, Fourier transformed infrared spectrometry, Scanning electron microscope coupled with EDX and Particle induced x-ray emission technique. A batch adsorption study was used to examine the performance efficiency of the modified clay. Optimization of adsorption conditions like temperature, particle size, concentration, agitation time and pH was performed. The clay after modification showed improved surface properties such as increased pore diameter and number. Freundlich, Langmuir and Temkin isotherm models were applied to explicate the adsorption processes, while Pseudo-First order, Pseudo-Second order and the Elovich kinetic models were used to predict possible mechanisms driving the adsorption processes. The adsorption processes driven by chemical mechanisms involved series of complex mechanisms that include ion exchange, direct bonding and surface complexation other than precipitation. The percentage removal of the metals by the modified clay soil reached the values of 98.53, 94.50, 73.82, and 80.40 for Pb, Cu, Ni and Cr.


Keywords


kaolinite clay; heavy metals; clay modification; adsorption kinetics; adsorption isotherms

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References

[1] Awaleh, M.O., and Soubaneh, Y.D., 2014, Waste water treatment in chemical industries: The concept and current technologies, Hydrol.: Curr. Res., 5 (1), 1000164.

[2] Saxena, G., Chandra, R., and Bharagava, R.N., 2016, Environmental pollution, toxicity profile and treatment approaches for tannery wastewater and its chemical pollutants, Rev. Environ. Contam. Toxicol., 240, 31–69.

[3] Wen, J., Fang, Y., and Zeng, G. 2018, Progress and prospect of adsorptive removal of heavy metal ions from aqueous solution using metal-organic frameworks: A review of studies from the last decade, Chemosphere, 201, 627–643.

[4] Chen, C.W., Chen, C.F., and Dong, C.D., 2012, Distribution and accumulation of mercury in sediments of Kaohsiung River mouth, Taiwan, APCBEE Procedia, 1, 153–158.

[5] Ahmaruzzaman, M., 2011, Industrial wastes as low-cost potential adsorbents for the treatment of wastewater laden with heavy metals, Adv. Colloid Interface Sci., 166 (1), 36–59.

[6] Guillaume, P.L.A., Chelaru, A.M., Visa, M., and Lassine, O., 2018, “Titanium oxide-clay” as adsorbent and photocatalysts for wastewater treatment, J. Membrane Sci. Technol., 8 (1), 1000176.

[7] Pinto, A.C.S., Grossi, L., de Melo, R.A.C, de Assis, T.M., Ribeiro, V.M., Amaral, M.S.C., and Figueiredo, K.C.S, 2017, Carwash wastewater treatment by micro and ultrafiltration mem-branes: Effects of geometry, pore size, pressure difference and feed flow rate in transport properties, J. Water Process Eng., 17, 143–148.

[8] Tan, J., Huang, Y., Wu, Z., and Chen, X., 2017, Ion exchange resin on treatment of copper and nickel wastewater, IOP Conf. Ser.: Earth Environ. Sci., 94, 012122.

[9] Akhter, M., Habib, G., and Qama, S.U., 2018, Application of electrodialysis in waste water treatment and impact of fouling on process performance, J. Membr. Sci. Technol., 8 (2), 1000182.

[10] Jaishankar, M., Mathew, B.B., Shah, M.S., Murthy, K.T.P., and Gowda, S.K.R., 2014, Biosorption of few heavy metal ions using agricultural wastes, J. Environ. Pollut. Hum. Health, 2, 1–6.

[11] Adekeye, D.K., Popoola, O.K., Asaolu, S.S., Adebawore, A.A., Aremu, O.I., and Olabode, K.O., 2019, Adsorption and conventional technologies for environmental remediation and decontami-nation of heavy metals: an overview, Int. J. Res. Rev., 6 (8), 505–516.

[12] Uddin, M.K., 2016, A review on the adsorption of heavy metals by clay minerals, with special focus on the past decade, Chem. Eng. J., 308, 438–462.

[13] Mustapha, S., Ndamitso, M.M., Abdulkareem, A.S., Tijani, J.O., Mohammed, A.K., and Shuaib, D.T., 2019, Potential of using kaolin as a natural adsorbent for the removal of pollutants from tannery wastewater, Heliyon, 5 (11), e02923.

[14] Kumrić, K.R., Đukić, A.B., Trtić-Petrović, T.M., Vukelić, N.S., Stojanović, Z., Novaković, J.D.G., Matović, L., 2013, Simultaneous removal of divalent heavy metals from aqueous solutions using raw and mechanochemically treated interstratified montmorillonite/kaolinite clay, Ind. Eng. Chem. Res., 52 (23), 7930–7939.

[15] Iannicelli-Zubiani, E.M., Cristiani, C., Dotelli, G., and Stampino, G.P. 2017, Recovery of valuable metals from electronic scraps by clays and organo-clays: Study on bi-ionic model solutions, Waste Manage., 60, 582.

[16] Fu, F., and Wang, Q., 2011, Removal of heavy metal ions from wastewaters: A review, J. Environ. Manage., 92 (3), 407–418.

[17] Srinivasan, R., 2011, Advances in application of natural clay and its composites in removal of biological, organic, and inorganic contaminants from drinking water, Adv. Mater. Sci. Eng., 2011, 872531.

[18] Adekeye, D.K., Asaolu, S.S., Adefemi, S.O., Ibigbami, O.A., Adebawore, A.A., Osundare, O.S., and Olumide, A.H., 2019, Clay soil modification techniques for the adsorption of heavy metals in aqueous medium: A review, Int. J. Adv. Re. Chem. Sci., 6 (6), 14–31.

[19] Yuan, G.D., Theng, B.K.G., Churchman, G.J., and Gates, W.P., 2013, “Chapter 5.1 – Clays and clay minerals for pollution control” in Development in Clay Science Series: Handbook of Clay Science, 2nd Ed., Eds. Bergaya, F., and Lagaly, G., 2nd Ed., Elsevier, 587–644.

[20] Al-Essa, K., and Khalili, F., 2018, Heavy metals adsorption from aqueous solutions onto unmodified and modified Jordanian kaolinite clay: batch and column techniques, Am. J. Appl. Chem., 6 (1), 25–34.

[21] Akpomie, K.G., Odewole, O.A., Ibeji, C.U., Okagu, O.D., and Agboola., I.I., 2017, Enhanced sorption of trivalent chromium unto novel cassava peel modified kaolinite clay, Der Pharma Chem., 9 (5), 48–55.

[22] Zen, S., El Berrichi, F.Z., Abidi, N., Duplay, J., Jada, A., and Gasmi, B., 2018, Activated kaolin’s potential adsorbents for the removal of Derma Blue R67 acid dye: kinetic and thermodynamic studies, Desalin. Water Treat., 112, 196–206.

[23] Marino, T., Russo, F., Rezzouk, L., Bouzid, A., and Figoli, A., 2017, PES-kaolin mixed matrix membranes for arsenic removal from water, Membranes, 7, 57.

[24] Zhu, J., Cozzolino, V., Pigna, M., Huang, Q., Caporale, A.G., and Violante, A., 2011, Sorption of Cu, Pb and Cr on Na-montmorillonite: Competition and effect of major elements, Chemosphere, 84 (4), 484–489.

[25] Olu-Owolabi, B.I., Alabi, A.H., Unuabonah, E.I., Diagboya, P.N., Böhm, L. and Düring, R., 2016, Calcined biomass-modified bentonite clay for removal of aqueous metal ions, J. Environ. Chem. Eng., 4 (1), 1376–1382.

[26] Adekeye, D.K., Asaolu, S.S., Adefemi, S.O., and Ibigbami, O.A., 2019, Heavy metal adsorption properties of the basement complex of clay deposit in Ire-Ekiti Southwestern Nigeria, IOSR J. Environ. Sci. Toxicol. Food Technol., 13 (2), 1–8.

[27] Mbaye, C.A.K., Diop, J.M., Miehe-Brendle, J., Senocq, F., and Maury, F., 2014, Characterization of natural and chemically modified kaolinite from Mako (Senegal) to remove lead from aqueous solutions, Clay Miner., 49 (4), 527–539.

[28] Olagboye, S.A., Ejelonu, B.C., Oyeneyin, O.E., Adekeye, D.K., and Gbolagade, Y.A., 2018, Synthesis, characterization and antimicrobial activities of metal complexes of Cu(II) and Zn(II) with prednisolone in water-isopropyl alcohol medium, Int. J. Adv. Res. Chem. Sci., 5(12), 16–23.

[29] Akinola, Oluwatoyin, O., Ademilua, and Oladimeji, L., 2014, Compositional features and functional industrial applications of the lateritic clay deposits in Oye-Ekiti and Environs, Southwestern Nigeria, IJST, 2 (9), 6–12.

[30] Awokunmi, E.E., and Asaolu, S.S., 2017, Physicochemical and performance evaluation of natural and modified Ire-Ekiti clay: Emerging substrate in the de-fluoridation of drinking water, J. Phys. Chem. Sci., 5 (4), 1–5.

[31] Cristiani, C., Iannicelli-Zubiani, E.M., Bellotto, M., Dotelli, G., Stampino, P.G., Latorrata, S., Ramis, G., and Finocchio, E, 2021, Capture mechanism of La and Cu ions in mixed solutions by clay and organoclay, Ind. Eng. Chem. Res., 60 (18), 6803–6813.

[32] Erdemoğlu, M., Erdemoğlu, S., Sayilkan, F., Akarsu, M., Şener, S., and Sayilkan, H., 2004, Organo-functional modified pyrophyllite: Preparation, characterization and Pb(II) ion adsorption property, Appl. Clay Sci., 27 (1), 41–52.

[33] Chaari, I., Medhioub, M., and Jamaoussi, F., 2011, Use of clay to remove heavy metals from Jebel Chakir landfill leachate, J. Appl. Sci. Environ. Sanit., 6 (2), 143–148.

[34] Dal Bosco, S.M., Jimenez R.S., Vignado, C., Fontana, J., Geraldo, B. Figueiredo, F.C.A., Mandelli, D., and Carvalho, W.A., 2006. Removal of Mn(II) and Cd(II) from wastewaters by natural and modified clays, Adsorption, 12 (2), 133–146.

[35] Jaiswal, A., Banerjee, S., Mani, R., and Chattopadhyaya, M.C., 2013, Synthesis, characterization and application of goethite mineral as an adsorbent, J. Environ. Chem. Eng., 1 (3), 281–289.

[36] Senthil, K.P., Vincent, C.K., Kirthika, K., and Sathish, K.K., 2010, Kinetics and equilibrium studies of Pb2+ ion removal from aqueous solutions by use of nano-silversol-coated activated carbon, Braz. J. Chem. Eng., 27 (2), 339–346.

[37] Teixeira, S.C.G., Ziolli, R.L., Marques, M.R.C., and Pérez, D.V., 2011, Study of pyrene adsorption on two Brazilian soils, Water Air Soil Pollut., 219 (1), 297–301.

[38] An, C., Huang, G., Yu, H., Wei, J., Chen, W., and Li, G., 2010, Effect of short-chain organic acidsn and pH on the behaviors of pyrene in soil–water system, Chemosphere, 81, 1423–1429.

[39] Olu-Owolabi, B.I., Diagboya, P.N., and Adebowale, K.O., 2014, Evaluation of pyrene sorption–desorption on tropical soils, J. Environ. Manage., 137, 1–9.

[40] Rattanaphani, S., Chairat, M., Bremner, J.B., and Rattanaphani, V., 2007, An adsorption and thermodynamic study of lac dyeing on cotton pretreated with chitosan, Dyes Pigm., 72 (1), 88–96.

[41] Zouraibi, M., Ammuri, A., Khadija, Z., and Saidi, M., 2016, Adsorption of Cu(II) onto natural clay: Equilibrium and thermodynamic studies, J. Mater. Environ. Sci., 7 (2), 566–570.

[42] Kara, S., Aydiner, C., Demirbas, E., Kobya, M., and Dizge, N., 2007, Modeling the effects of adsorbent dose and particle size on the adsorption of reactive textile dyes by fly ash, Desalination, 212 (1), 282–293.

[43] Langmuir, I., 1918, The adsorption of gases on plane surfaces of glass, mica and platinum, J. Am. Chem. Soc., 40 (9), 1361–1403.

[44] Freundlich, H.M.F., 1906, Over the adsorption in solution, J. Phys. Chem., 57, 385–471.

[45] Ramachandran, P., Vairamuthu, R., and Ponnusamy, S., 2011, Adsorption isotherms, kinetics, thermodynamics and desorption studies of Reactive Orange 16 on activated carbon derived from Ananas Comosus (L.) carbon, ARPN J. Eng. Appl. Sci., 6 (11), 15–26.

[46] Asaolu, S.S., Adefemi, S.O., Ibigbami, O.A., and Adekeye, D.K., 2020, Kinetics, isotherm and thermodynamic properties of the basement complex of clay deposit in Ire-Ekiti Southwestern Nigeria for heavy metals removal, Nat. Environ. Pollut. Technol., 19 (3), 897–907.

[47] De la Rosa, G., Reynel-Avila, H.E., Bonilla-Petriciolet, A., Cano-Rodríguez, I., Velasco-Santos, C., and Martínez-Hernández, A.L., 2008, Recycling poultry feathers for Pb removal from wastewater: Kinetic and equilibrium studies, Int. J. Chem. Mol. Eng., 2 (11), 338–346.

[48] Temkin, M.I., and Pyzhev, V., 1940, Kinetics of ammonia synthesis on promoted iron catalyst, Acta Physicochim. URSS, 12, 327–356.

[49] Lagergren, S., 1898, Zur theorie der sogenannten adsorption gelöster stoffe (About the theory of so-called adsorption of soluble substances), K. Sven. Vetensk.Akad. Handl., 24, 1–39.

[50] Roginsky, S.Z., and Zeldovich, J., 1934, An equation for the kinetics of activated adsorption, Acta Physicochim. URSS, 1, 554–559.



DOI: https://doi.org/10.22146/ijc.59480

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