Adsorption of Copper (II) Ions on a Montmorillonite Clay and its Application as Heterogeneous Catalyst for Knoevenagel Condensation Reaction
Subject Areas : Journal of Chemical Health Risks
Hanane Essebaai
1
,
zakaria Benzekri
2
,
Houda Serrar
3
,
Ahmed Lebkiri
4
,
Said Boukhris
5
,
Said Marzak
6
,
ElHousseine Rifi
7
1 - Laboratory of Organic Synthesis and Extraction Processes, Department of Chemistry, Faculty of Sciences, Ibn Tofail University, Kénitra, Morocco
2 - Laboratory of Organic, Organometallic and Theoretical Chemistry, Faculty of Science, Ibn Tofaïl University,
Kenitra, Morocco
3 - Laboratory of Organic, Organometallic and Theoretical Chemistry, Faculty of Science, Ibn Tofaïl University,
Kenitra, Morocco
4 - Laboratory of Organic Synthesis and Extraction Processes, Department of Chemistry, Faculty of Sciences, Ibn Tofail University, Kénitra, Morocco.
5 - Laboratory of Organic, Organometallic and Theoretical Chemistry, Faculty of Science, Ibn Tofaïl University,
Kenitra, Morocco
6 - Laboratory of Organic Synthesis and Extraction Processes, Department of Chemistry, Faculty of Sciences, Ibn Tofail University, Kénitra, Morocco.
7 - Laboratory of Organic Synthesis and Extraction Processes, Department of Chemistry, Faculty of Sciences, Ibn Tofail University, Kénitra, Morocco.
Keywords:
Abstract :
1. Tizaoui K., Benguella B., Makhoukhi B., 2019. Selective Adsorption of Heavy Metals (Co2+, Ni2+, and Cr3+) from Aqueous Solutions onto Natural Marne Clay. Desalination Water Treat. 142, 252–259.
2 .Calagui M.J.C., Senoro D.B., Kan C.C., Salvacion J.W., Futalan C.M., Wan M.W., 2014. Adsorption of Indium (III) Ions from Aqueous Solution Using Chitosan-Coated Bentonite Beads. J Hazard Mater.277, 120–126.
3. Bouna L., Ait El Fakir A., Abdeljalil B., Draoui K., Villain S., Guinneton F., 2020. Physico-Chemical Characterization of Clays from Assa-Zag for Valorization in Cationic Dye Methylene Blue Adsorption. Mater. Today Proc. 22, 22-27.
4. Alshameri A., He H., Zhu J., Xi Y., Zhu R., Ma L., Tao Q., 2018. Adsorption of Ammonium by Different Natural Clay Minerals: Characterization, Kinetics and Adsorption Isotherms. Appl Clay Sci. 159, 83–93.
5. Ouaddari H., Beqqour D., Bennazha J., El Amrani I.E., Albizane A., Solhy A., Varma R.S., Natural Moroccan Clays: Comparative Study of Their Application as Recyclable Catalysts in Knoevenagel Condensation. Sustain Chem Pharm. 10, 1–8.
6. Lamberth C., Godineau E., Smejkal T., Trah S., 2012. ChemInform Abstract: A New Knoevenagel-Type Synthesis of Fully Substituted γ-Hydroxybutenolides. Tetrahedron Lett. 53, 4117–4120.
7.Heydari R., Tahamipour B., 2011. Highly Regioselective Synthesis of Dicyano-8a,10,11-Trihydropyrrolo[1,2-a][1,10]Phenanthrolines via a Domino-Knoevenagel-Cyclization. Chin Chem Lett. 22(11), 1281–1284.
8. Tietze L.F., Rackelmann N., 2004. Domino Reactions in the Synthesis of Heterocyclic Natural Products and Analogs. Pure Appl Chem. 76(11), 1967–1983.
9. Vijender M., Kishore P., Satyanarayana B., 2008. Zirconium Tetrachloride-SiO2 Catalyzed Knoevenagel Condensation: A Simple and Efficient Protocol for the Synthesis of Substituted Electrophilic Alkenes. Arkivoc. 13, 122–128.
10. Alandis N.M., Mekhamer W., Aldayel O., Hefne J.A.A., Alam M., 2019. Adsorptive
Applications of Montmorillonite Clay for the Removal of Ag(I) and Cu(II) from Aqueous Medium. J Chem. 1-7.
11.Rosati O., Lanari D., Scavo R., Persia D., Marmottini F., Nocchetti M., Curini M., Piermatti O., 2018. Zirconium Potassium Phosphate Methyl and/or Phenyl Phosphonates as Heterogeneous Catalysts for Knoevenagel Condensation under Solvent Free Conditions. Microporous Mesoporous Mater. 268, 251–259.
12. Çi̇Men O., Koç Ş., Sari A., 2013. Rare earth element (REE) geochemistry and genesis of oil shales around Daghacilair village, Goynuk-Bolu, TurkeyURKEY. Oil Shale. 30 (3), 419.
13. Gionis V., Kacandes G.H., Kastritis I.D., 2006. Chryssikos G.D., On the Structure of Palygorskite by Mid-and near-Infrared Spectroscopy. Am Mineral. 91(7), 1125–1133.
14. Suarez M., Garcia-Romero E.,2006. FTIR Spectroscopic Study of Palygorskite: Influence of the Composition of the Octahedral Sheet. Appl Clay Sci. 31 (1–2), 154–163.
15. Blanco C., González F., Pesquera C., Benito I., Mendioroz S., Pajares J.A., 1989. Differences between One Aluminic Palygorskite and Another Magnesic by Infrared Spectroscopy. Spectrosc Lett. 22(6), 659–673.
16. Yan W., Liu D., Tan D., Yuan P., Chen M., 2012. FTIR Spectroscopy Study of the Structure Changes of Palygorskite under Heating. Spectrochim. Acta A Mol Biomol Spectrosc. 97, 1052–1057.
17. Jiang M., Jin X., Lu X.Q., Chen Z., 2010. Adsorption of Pb (II), Cd (II), Ni (II) and Cu (II) onto Natural Kaolinite Clay. Desalination . 252 (1–3), 33–39.
18. Essebaai H., Ismi I., Lebkiri A., Marzak S., 2019. Kinetic and Thermodynamic Study of Adsorption of Copper (II) Ion on Moroccan Clay. Mediterr J Chem. 9 (2), 102–115.
19. Van Tran T., Nguyen D.T.C., Le H.T., Tu T.T., Le N.D., Lim K.T., Bach L.G., Nguyen T.D., 2019. MIL-53 (Fe)-Directed Synthesis of Hierarchically Mesoporous Carbon and Its Utilization for Ciprofloxacin Antibiotic Remediation. J Environ Chem Eng. 7(1), 102881.
20. Nartowska E., 2019. The Effects of Potentially Toxic Metals (Copper and Zinc) on Selected Physical and Physico-Chemical Properties of Bentonites. Heliyon . 5(10), e02563.
21. Ndzana G.M., Huang L., Zhang Z., Zhu J., Liu F., Bhattacharyya R., 2019. The Transformation of Clay Minerals in the Particle Size Fractions of Two Soils from Different Latitude in China. Catena . 175, 317–328.
22. Lagergren S.,1899. Zur Theorie der sogenannten Adsorption gelöster Stoffe. Physik Ch. 32, 174–75.
23. Ho Y.S., McKay G., 1999. Pseudo-Second Order Model for Sorption Processes. Process Biochem. 34(5), 451–465.
24. Fu J., Xin Q., Wu X., Chen Z., Yan Y., Liu S., Wang M., Xu Q., 2016. Selective Adsorption and Separation of Organic Dyes from Aqueous Solution on Polydopamine Microspheres. J Colloid Interface Sci. 461, 292–304.
25. Mahmoodi N.M., 2015. Surface Modification of Magnetic Nanoparticle and Dye Removal from Ternary Systems. J Ind Eng Chem. 27, 251–259.
26. Bentahar S., Dbik A., El Khomri M., El Messaoudi N., Lacherai A., 2017. Adsorption of Methylene Blue, Crystal Violet and Congo Red from Binary and Ternary Systems with Natural Clay: Kinetic, Isotherm, and Thermodynamic. J Environ Chem Eng. 5 (6), 5921–5932.
27. Weber W.J., Morris J.C.,1963. Kinetics of Adsorption on Carbon from Solution. J Sanit Eng Div. 89(2), 31–60.
28. Chowdhury S., Misra R., Kushwaha P., Das P., 2011. Optimum Sorption Isotherm by Linear and Nonlinear Methods for Safranin onto Alkali-Treated Rice Husk. Bioremediation J. 15(2), 77–89.
29. Benderdouche N., Bestani B., Hamzaoui M., 2018. The Use of Linear and Nonlinear Methods for Adsorption Isotherm Optimization of Basic Green 4-Dye onto Sawdust-Based Activated Carbon. J Mater Env Sci. 9, 1110–1118.
30. Jeppu G.P., Clement T.P., 2012. A Modified Langmuir-Freundlich Isotherm Model for Simulating PH-Dependent Adsorption Effects. J Contam Hydrol. 129, 46–53.
31. Chen X., 2015. Modeling of Experimental Adsorption Isotherm Data. Information. 6(1), 14–22.
32. Kapoor A., Yang R.T., 1989 Correlation of Equilibrium Adsorption Data of Condensible Vapours on Porous Adsorbents. Gas Sep. Purif. 3(4), 187–192.
33. Kausar A., Naeem K., Hussain T., Bhatti H.N., Jubeen F., Nazir A., Iqbal M., 2019. Preparation and Characterization of Chitosan/Clay Composite for Direct Rose FRN Dye Removal from Aqueous Media: Comparison of Linear and Non-Linear Regression Methods. J Mater Res Technol. 8(1), 1161–1174.
34. Amrhar O., Nassali H., Elyoubi M.S., 2015. Application of Nonlinear Regression Analysis to Select the Optimum Absorption Isotherm for Methylene Blue Adsorption onto Natural Illitic Clay. Bull Société R Sci Liège. 84, 116–130.
35. Vasanth Kumar K.,,Sivanesan S., 2005. Comparison of linear and non-linear method in estimating the sorption isotherm parameters for safranin onto activated carbon. Journal of Hazardous Materials B123, 288–292.
