Hostname: page-component-cd9895bd7-gvvz8 Total loading time: 0 Render date: 2024-12-23T16:08:39.208Z Has data issue: false hasContentIssue false

Removal of cationic and anionic dyes using purified and surfactant-modified Tunisian clays: Kinetic, isotherm, thermodynamic and adsorption-mechanism studies

Published online by Cambridge University Press:  18 June 2018

S. Gamoudi*
Affiliation:
Laboratoire de Matériaux Composites et Minéraux Argileux, Centre National des Recherches en Sciences des Matériaux, Technopole de Borj Cedria, Tunisia
E. Srasra
Affiliation:
Laboratoire de Matériaux Composites et Minéraux Argileux, Centre National des Recherches en Sciences des Matériaux, Technopole de Borj Cedria, Tunisia
*

Abstract

Purified and surfactant-modified Tunisian clays were investigated for their capacity to remove cationic and anionic dyes (crystal violet, CV and methyl orange, MO) from aqueous solution. The samples were characterized by X-ray diffraction (XRD), Fourier transform infrared spectroscopy (FTIR), and potentiometric acid-base titration. Batch-sorption experiments were carried out to evaluate the influence of pH, contact time, initial dye concentration and temperature on the adsorption of dyes. Pseudo-first order, pseudo-second order, intra-particle diffusion and Elovich kinetic models were considered to evaluate the kinetic parameters. To understand the interaction of the dye with the adsorbent, Langmuir, Freundlich, Temkin and Dubinin-Radushkevish isotherms were applied. Thermodynamics studies were conducted to calculate the changes in free energy (Δ°G), enthalpy (Δ°H) and entropy (Δ°S). A difference in the maximum adsorption capacity was observed, suggesting that the retention of dyes was influenced by structure, functional groups of dyes and surface properties of the adsorbents. Moreover, different mechanisms may control the removal of dyes. The purified Tunisian clays are excellent adsorbents for removal of the cationic dye CV and its modified form is suitable for removal of the anionic dye, MO, from aqueous solution.

Type
Article
Copyright
Copyright © Mineralogical Society of Great Britain and Ireland 2018 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

Footnotes

This paper was presented during session: ‘ES-02 Environmental applications of clay minerals’ at the International Clay Conference 2017.

Guest Associate Editor: Claudio Cameselle

References

REFERENCES

Abdel Messih, M.F., Ahmed, M.A., Soltan, A. & Anis, S.S. (2017) Facile approach for homogeneous dispersion of metallic silver nanoparticles on the surface of mesoporous titania for photocatalytic degradation of methylene blue and indigo carmine dyes. Journal of Photochemistry and Photobiology A: Chemistry, 335, 4051.Google Scholar
Adams, E.Q. & Rosenstein, L. (1914) The color and ionization of crystal-violet. Journal of American Chemical Society, 36, 14521473.Google Scholar
Anirudhan, T.S. & Ramachandran, M. (2015) Adsorptive removal of basic dyes from aqueous solutions by surfactant modified bentonite clay (organoclay): Kinetic and competitive adsorption isotherm. Process Safety and Environmental Protection, 95, 215225.Google Scholar
Arshadi, M., Mousavinia, F., Amiri, M.J. & Faraji, A.R. (2016) Adsorption of methyl orange and salicylic acid on a nano-transition metal composite: Kinetics, thermodynamic and electrochemical studies. Journal of Colloid and Interface Science, 483, 118131.Google Scholar
Baskaralingam, P., Pulikesi, M., Elango, D., Ramamurthi, V. & Sivanesan, S. (2006) Adsorption of acid dye onto organobentonite. Journal of Hazardous Materials B, 128, 138144.Google Scholar
Belhouchat, N., Zaghouane-Boudiafa, H. & Viseras, C. (2016) Removal of anionic and cationic dyes from aqueous solution with activated organo-bentonite/sodium alginate encapsulated beads. Applied Clay Science, 135, 915Google Scholar
Bors, J., Dultz, St. & Riebe, B. (1999) Retention of radionuclides by organophilic bentonites. Engineering Geology, 54, 195206.Google Scholar
Bors, J., Patzko, A. & Dekany, I. (2001) Adsorption behavior of radioiodides in hexadecyl-pyridinium–humate complexes. Applied Clay Science, 19, 2737.Google Scholar
Bouraada, M., Ouali, M.S. & Menorval, C.L. (2016) Dodecylsulfate and dodecybenzenesulfonate intercalated hydrotalcites as adsorbent materials for the removal of BBR acid dye from aqueous solutions. Journal of Saudi Chemical Society, 20, 397404.Google Scholar
Chen, H., Zhao, J., Wu, J. & Dai, G. (2011) Isotherm, thermodynamic, kinetics and adsorption mechanism studies of methyl orange by surfactant modified silkworm exuviae. Journal of Hazardous Materials, 192, 246254.Google Scholar
Chen, Z., Wang, T., Jin, X., Chen, Z., Mallavarapu, M. & Ravendra, N. (2013) Multifunctional kaolinite-supported nanoscale zero-valent iron used for the adsorption and degradation of crystal violet in aqueous solution. Journal of Colloid and Interface Science, 398, 5966.Google Scholar
Chien, S.H. & Clayton, W.R. (1980) Application of Elovich equation to the kinetics of phosphate release and sorption in soils. Soil Science Society of America Journal, 44, 265268.Google Scholar
Deng, L., Shi, Z., Peng, X. & Zhou, S. (2016) Magnetic calcinated cobalt ferrite/magnesium aluminum hydrotalcite composite for enhanced adsorption of methyl orange. Journal of Alloys and Compounds, 688, 101112.Google Scholar
Depci, T., Kul, Q.Z., Onal, Y., Disli, E., Alkan, S. & Turkmenoglu, Z.F. (2012) Adsorption of crystal violet from aqueous solution on activated carbon derived from Gölbaşi lignite. Physicochemical Problems of Mineral Processing, 48, 253270.Google Scholar
Dubinin, M.M. & Radushkevich, L.V. (1947) Equation of the characteristic curve of activated charcoal. Proceedings of the Academy of Sciences of the USSR. Physical Chemical Section, 55, 331333.Google Scholar
Elmoubarki, R., Mahjoubi, F.Z., Tounsadi, H., Moustadraf, J., Abdennouri, M., Zouhri, A., El Albani, A. & Barka, N. (2015) Adsorption of textile dyes on raw and decanted Moroccan clays: Kinetics, equilibrium and thermody namics. Water Resources and Industry, 9, 1629.Google Scholar
Eren, E. (2009) Investigation of a basic dye removal from aqueous solution onto chemically modified Unye bentonite. Journal of Hazardous Materials, 16, 8893.Google Scholar
Errais, E., Duplaya, J., Elhabiri, M., Khodjac, M., Ocampod, R., Baltenweck-Guyote, R. & Darragi, F. (2012) Anionic RR120 dye adsorption onto raw clay: surface properties and adsorption mechanism. Colloids and Surfaces A, 403, 6978.Google Scholar
Esteves, B.M., Rodrigues, C.S.D., Boaventura, R.A.R., Maldonado-Hodar, F.J. & Madeira, L.M. (2016) Coupling of acrylic dyeing wastewater treatment by heterogeneous Fenton oxidation in a continuous stirred tank reactor with biological degradation in a sequential batch reactor. Journal of Environmental Management, 166, 193203.Google Scholar
Freitas, A.F., Mendes, M.F. & Coelho, G.L.V. (2007) Thermodynamic study of fatty acids adsorption on different adsorbents. The Journal of Chemical Thermodynamics, 39, 10271037.Google Scholar
Freundlich, H.M.F. (1906) Über dies adsorption in Lösungen. Zeitschrift für Physikalische Chemie, 57, 385470.Google Scholar
Gamoudi, S., Frini-Srasra, N. & Srasra, E. (2012) Kinetic and equilibrium studies of fluoride sorption onto surfactant-modified smectites. Clay Minerals, 47, 429440.Google Scholar
Gholami, M., Vardini, M.T. & Mahdavinia, G.R. (2016) Investigation of the effect of magnetic particles on the Crystal Violet adsorption onto a novel nanocomposite based on Carrageenan-g-poly(methacrylic acid). Carbohydrate Polymers, 136, 772781.Google Scholar
Gil, A., Assis, F.C.C., Albeniz, S. & Korili, S.A. (2011) Removal of dyes from wastewaters by adsorption on pillared clays. Chemical Engineering Journal, 168, 10321040.Google Scholar
Giles, C.H., MacEwan, T.H., Nakhwa, S.N. and Smith, D. (1960) 786. Studies in adsorption. Part XI. A system of classification of solution adsorption isotherms, and its use in diagnosis of adsorption mechanisms and in measurement of specific surface areas of solids. Journal of the Chemical Society, 0, 39733993.Google Scholar
Gupta, V.K., Carrott, P.J.M. & Ribeiro Carrott, M.M.L. (2009) Low-cost adsorbents: Growing approach to wastewater treatment – a review. Reviews in Environmental Science and Technology, 39, 783842.Google Scholar
Guz, L., Curutchet, G., Torres Sanchez, R.M. & Candal, R. (2014) Adsorption of crystal violet on montmorillonite (or iron modified montmorillonite) followed by degradation through Fenton or photo-Fenton type reactions. Journal of Environmental Chemical Engineering, 2, 23442351.Google Scholar
Hamdi, N. & Srasra, E. (2014) Acid-base properties of organosmectite in aqueous suspension. Applied Clay Science, 99, 16.Google Scholar
Hamidzadeh, S., Torabbeigi, M. & Shahtaheri, S.J. (2015) Removal of crystal violet from water by magnetically modified activated carbon and nanomagnetic iron oxide. Journal of Environmental Health Science & Engineering, 13, 814.Google Scholar
Hassanzadeh-Tabrizi, S.A., Motlagh, M.M. & Salahshour, S. (2016) Synthesis of ZnO/CuO nanocomposite immobilized on γ-Al2O3 and application for removal of methyl orange. Applied Surface Science, 384, 237243.Google Scholar
He, H., Zhou, Q., Frost, R.L., Wood, B.J., Duong, L.V. & Kloprogge, J.T. (2007) A X-ray photoelectron spectroscopy study of HDTMAB distribution within organoclays. Spectrochimica Acta Part A, 66, 11801188.Google Scholar
Ho, Y.S. & Mckay, G. (1999) Batch lead(II) removal from aquous solution by peat: equilibrium and kinetics. Process Safety and Environmental Protection, 77, 165173.Google Scholar
Ho, Y.S., Chiang, C.C. & Hsu, Y.C. (2001) Sorption kinetics for dye removal from aqueous solution using activated clay. Journal Separation Science and Technology, 36, 2473–88.Google Scholar
Hu, E., Xinbo, W., Songmin, S., Xiao-ming, T., Shou-Xiang, J. & Lu, G. (2016) Catalytic ozonation of simulated textile dyeing wastewater using mesoporous carbon aerogel supported copper oxide catalyst. Journal of Cleaner Production, 112, 47104718.Google Scholar
Istratie, R., Stoia, M., Pacurariu, C. & Locovei, C. (2016) Single and simultaneous adsorption of methyl orange and phenol onto magnetic iron oxide/carbon nanocomposites. Arabian Journal of Chemistry. https://doi.org/10.1016/j.arabjc.2015.12.012Google Scholar
Jian-min, R., Wu, S. & Jin, W. (2010) Adsorption of Crystal Violet onto BTEA- and CTMA-bentonite from aqueous solutions. World Academy of Science, Engineering and Technology, 41, 330335.Google Scholar
Keyhanian, F., Shariati, S., Faraji, M. & Hesabi, M. (2011) Magnetite nanoparticles with surface modification for removal of methyl violet from aqueous solutions. Arabian Journal of Chemistry, 9, S348S354.Google Scholar
Kono, H. & Kusumoto, R. (2015) Removal of anionic dyes in aqueous solution by flocculation with cellulose ampholytes. Journal of Water Process Engineering, 7, 8393.Google Scholar
Kuppusamy, S., Thavamani, P., Megharaj, M., Venkateswarlu, K. & Lee, Y.B. & Naidu, R. (2016) Potential of Melaleuca diosmifolia as a novel, non-conventional and low-cost coagulating adsorbent for removing both cationic and anionic dyes. Journal of Industrial and Engineering Chemistry, 37, 198207.Google Scholar
Lafi, R. & Hafiane, A. (2016) Removal of methyl orange (MO) from aqueous solution using cationic surfactants modified coffee waste (MCWs). Journal of the Taiwan Institute of Chemical Engineers, 58, 424433.Google Scholar
Lagergren, S. (1898) About the theory of so-called adsorption of soluble substances. Kungliga Svenska Vetenskapsakademiens Handlingar, 24, 139.Google Scholar
Langmuir, I. (1916) The constitution and fundamental properties of solids and liquids. Journal of the American Chemical Society, 38, 22212295.Google Scholar
Leodopoulos, Ch., Doulia, D., Gimouhopoulos, K. & Triantis, T.M. (2012) Single and simultaneous adsorption of methyl orange and humic acid onto bentonite. Applied Clay Science, 70, 8490.Google Scholar
Li, H., Sun, Z., Zhang, L., Tian, Y., Cui, G. & Yan, S. (2016a) A cost-effective porous carbon derived from pomelo peel for the removal of methyl orange from aqueous solution. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 489, 191199.Google Scholar
Li, H., Liu, S., Zhao, J. & Feng, N. (2016b) Removal of reactive dyes from wastewater assisted with kaolin clay by magnesium hydroxide coagulation process. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 494, 222227.Google Scholar
Lin, Y., He, X., Han, G., Tian, Q. & Hu, W. (2011) Removal of Crystal Violet from aqueous solution using powdered mycelia biomass of Ceriporia lacerata P2. Journal of Environmental Sciences, 23, 20552062Google Scholar
Ling, F., Fang, L., Lu, Y., Gao, J., Wu, F., Zhou, M. & Hu, B. (2016) A novel CoFe layered double hydroxides adsorbent: High adsorption amount for methyl orange dye and fast removal of Cr(VI). Microporous and Mesoporous Materials, 234, 230238.Google Scholar
Liu, M., Chen, Q., Lu, K., Huang, W., , Z., Zhou, C., Yu, S. & Gao, C. (2017) High efficient removal of dyes from aqueous solution through nanofiltration using diethanolamine-modified polyamide thin-film composite membrane. Separation and Purification Technology, 173, 135143.Google Scholar
Luo, Z., Gao, M., Ye, Y. & Yang, S. (2015) Modification of reduced-charge montmorillonites by a series of Gemini surfactants: Characterization and application in methyl orange removal. Applied Surface Science, 324, 807816.Google Scholar
Ma, J., Cui, B., Dai, J. & Li, D. (2011) Mechanism of adsorption of anionic dye from aqueous solutions onto organobentonite. Journal of Hazardous Materials, 186, 17581765.Google Scholar
Moawed, E.A., Abulkibash, A.B. & El-Shahat, M.F. (2015) Synthesis and characterization of iodo polyurethane foam and its application in removing of aniline blue and crystal violet from laundry wastewater. Journal of Taibah University for Science, 9, 8088.Google Scholar
Mokhtari, P., Ghaedi, M., Dashtian, K., Rahimi, M.R. & Purkait, M.K. (2016) Removal of methyl orange by copper sulfide nanoparticles loaded activated carbon: Kinetic and isotherm investigation. Journal of Molecular Liquids, 219, 299305.Google Scholar
Monash, P. & Pugazhenthi, G. (2009) Adsorption of crystal violet dye from aqueous solution using mesoporous materials synthesized at room temperature. Adsorption, 15, 390405.Google Scholar
Monash, P. & Pugazhenthi, G. (2010) Removal of Crystal Violet dye from aqueous solution using calcined and uncalcined mixed clay adsorbents. Separation Science and Technology, 45, 94104.Google Scholar
Muthukumaran, C., Sivakumar, V.M. & Thirumarimurugan, M. (2016) Adsorption isotherms and kinetic studies of crystal violet dye removal from aqueous solution using surfactant modified magnetic nanoadsorbent. Journal of the Taiwan Institute of Chemical Engineers, 63, 354362.Google Scholar
Özan, S.A., Erdem, B. & Özcan, A. (2004) Adsorption of Acid Blue 193 from aqueous solutions onto Na-bentonite and DTMA-bentonite. Journal of Colloid and Interface Science, 280, 4454.Google Scholar
Özcan, A.S., Erdem, B. & Özcan, A. (2005) Adsorption of Acid Blue 193 from aqueous solutions onto BTMA-bentonite. Colloids and Surfaces: Physicochemical and Engineering Aspects, 266, 7381.Google Scholar
Pelaez-Cid, A.A., Herrera-Gonzalez, A.M., Villanueva, M.S. & Bautista Hernandez, A. (2016) Elimination of textile dyes using activated carbons prepared from vegetable residues and their characterization. Journal of Environmental Management, 181, 269278.Google Scholar
Reynolds, P.C. & Hower, J. (1970) The nature of interlayering in mixed-layer illite-montmorillonites. Clays and Clay Minerals, 18, 2536.Google Scholar
Robati, D., Mirza, B., Rajabi, M., Moradi, O., Tyagi, I., Agarwal, S. & Gupta, V.K. (2016) Removal of hazardous dyes-BR 12 and methyl orange using graphene oxide as an adsorbent from aqueous phase. Chemical Engineering Journal, 284, 687697.Google Scholar
Rodrigues, C.S.D., Carabineiro, S.A.C., Maldonado-Hódar, F.J. & Madeira, L.M. (2017) Wet peroxide oxidation of dye-containing wastewaters using nanosized Au supported on Al2O3. Catalysis Today, 280, 165175.Google Scholar
Ruan, X., Chen, Y., Chen, H., Qian, G. & Frost, R.L. (2016) Sorption behavior of methyl orange from aqueous solution on organic matter and reduced graphene oxides modified Ni–Cr layered double hydroxides. Chemical Engineering Journal, 297, 295303.Google Scholar
Saeed, A., Sharif, M. & Muhammad, I. (2010) Application potential of grapefruit peel as dye sorbent: Kinetics, equilibrium and mechanism of crystal violet adsorption. Journal of Hazardous Materials, 179, 564572.Google Scholar
Santos, S.C.R., Oliveira, A.F.M. & Boaventura, R.A.R. (2016) Bentonitic clay as adsorbent for the decolourisation of dyehouse effluents. Journal of Cleaner Production, 126, 667676.Google Scholar
Sarma, G.K., Gupta, S.S. & Bhattacharyya, K.G. (2016) Adsorption of crystal violet on raw and acid-treated montmorillonite, K10, in aqueous suspension. Journal of Environmental Management, 171, 110.Google Scholar
Schroth, B.L. & Sposito, G. (1997) Surface charge properties of kaolinite. Clay and Clay Minerals, 45, 8591.Google Scholar
Subbaiah, M.V. & Kim, D.S. (2016) Adsorption of methyl orange from aqueous solution by aminated pumpkin seed powder: Kinetics, isotherms, and thermodynamic studies. Ecotoxicology and Environmental Safety, 128, 109117.Google Scholar
Tahir, S.S. & Naseem, R. (2006) Removal of a cationic dye from aqueous solutions by adsorption onto bentonite clay. Chemosphere, 63, 18421848.Google Scholar
Tahir, H., Hammed, U., Sultan, M. & Jahanze, Q. (2010) Batch adsorption technique for the removal of malachite green and fast green dyes by using montmorillonite clay as adsorbent. African Journal of Biotechnology, 82068214.Google Scholar
Tang, L., Cai, Y., Yang, G., Liu, Y., Zeng, G., Zhou, Y., Li, S., Wang, J., Zhang, S., Fang, Y. & He, Y. (2014) Cobalt nanoparticles-embedded magnetic ordered mesoporous carbon for highly effective adsorption of rhodamine B. Applied Surface Science, 314, 746753.Google Scholar
Tawarah, K.M. & Abu-Shamleh, H.M. (1991) A spectrophotometric study of the tautomeric and acid base equilibria of methyl orange and methyl yellow in aqueous acidic solutions. Dyes and Pigments, 16, 241251.Google Scholar
Temkin, M. & Pyzhev, V. (1940) Recent modifications to Langmuir isotherms. Acta Physiochimica USSR, 12, 217225.Google Scholar
Vasconcelos, V.M., Ribeiro, F.L., Migliorini, F.L., Alves, S.A., Steter, J.R., Baldan, M.R., Ferreira, N.G. & Lanza, M.R.V. (2015) Electrochemical removal of Reactive Black 5 azo dye using non-commercial boron-doped diamond film anodes. Electrochimica Acta, 178, 484493.Google Scholar
Van olphen, H. (1963) An Introduction to Clay Colloid Chemistry. Interscience Publishers, New York, London.Google Scholar
Vimonses, V. (2009) Kinetic study and equilibrium isotherm analysis of Congo red adsorption by clay materials. Chemical Engineering Journal, 148, 354364.Google Scholar
Weber, J.W.J. & Morris, J.C. (1963) Kinetics of adsorption on carbon from solution. Journal of the Sanitary Engineering Division, 89, 3159.Google Scholar
Xing, X., Chang, P., Lv, G., Jiang, W., Jean, J., Liao, L. & Li, Z. (2016) Ionic-liquid-crafted zeolite for the removal of anionic dye methyl orange. Journal of the Taiwan Institute of Chemical Engineers, 59, 237243.Google Scholar
Yan, L., Qin, L., Yu, H., Li, S., Shan, R. & Du, B. (2015) Adsorption of acid dyes from aqueous solution by CTMAB modified bentonite: Kinetic and isotherm modeling. Journal of Molecular Liquids, 211, 10741081.Google Scholar
Yan, J., Zhu, Y., Qiu, F., Zhao, H., Yang, D., Wang, J. & Wen, W. (2016) Kinetic, isotherm and thermodynamic studies for removal of methyl orange using a novel-cyclodextrin functionalized graphene oxide-isophorone diisocyanate composites. Chemical Engineering Research and Design, 106, 168177.Google Scholar
Yeap, K.L., Teng, T.T., Poh, B.T., Morad, N. & Lee, K.E. (2014) Preparation and characterization of coagulation/flocculation behavior of a novel inorganic-organic hybrid polymer for reactive and disperse dyes removal. Chemical Engineering Journal, 243, 305314.Google Scholar
Zhang, L., Zhang, H., Guo, W. & Tian, Y. (2014) Removal of malachite green and crystal violet cationic dyes from aqueous solution using activated sintering process red mud. Applied Clay Science, 94, 8593.Google Scholar