Synthesis and Performance Evaluation of Chitosan Prepared from Persian Gulf Shrimp Shell in Removal of Reactive Blue 29 Dye from Aqueous Solution (Isotherm, Thermodynamic and Kinetic Study)

Document Type : Review Article

Authors

1 Medical Toxicology and Drug Abuse Research Center (MTDRC), Birjand University of Medical Sciences, Birjand, I.R. IRAN

2 Department of Environmental Health Engineering, Faulty of Health, Birjand University of Medical Sciences, Birjand, I.R. IRAN

Abstract

This study was aimed to investigate the amount of reactive blue 29 (RB29) dye removal from aqueous solution by Chitosan extracted from Persian Gulf shrimp shell. The effect of parameters such as pH, the concentration of reactive blue 29 dye, contact time, and adsorbent dosage in dye removal was studied. Isotherm, Thermodynamics, and kinetics of adsorption process were also investigated. The results of this study showed that the optimum condition of the adsorption process occurred in 50mg/L of RB29 dye concentration, pH=4, contact time of 90 minutes and adsorbent dosage of 0.2 g/L. The maximum adsorption capacity in optimum condition was estimated to 87.74 mg/g. Lab data displayed that the results were in compliance with Langmuir isotherm. According to the results of thermodynamic studies, standard entropy changes (ΔS°) was 66.67 J/mol K and standard enthalpy changes (ΔH°) was 19158.3 kJ/mol. Also, the standard Gibbs free energy (ΔG°) was negative and kinetics of adsorption process follows the pseudo-second-order model

Keywords

Main Subjects

References

[1] Özacar M., Şengil IA., Adsorption of Reactive Dyes on Calcined Alunite from Aqueous Solutions, Journal of Hazardous Materials, 98(1): 211- 224 (2003).
[2] Yesilada O., Asma D., Cing S., Decolorization of Textile Dyes by Fungal Pellets, Process Biochemistry, 38(6): 933-938 (2003).
[3] Tan KB., Vakili M., Horri BA., Poh PE., Abdullah A.Z., Salamatinia B., Adsorption of Dyes by Nanomaterials: Recent Developments and Adsorption Mechanisms, Separation and Purification Technology, 150: 229-242 (2015).
[4] Wang L.K., Hung Y-T., Lo H.H., Yapijakis C., “Handbook of Industrial and Hazardous Wastes Treatment”, CRC Press, (2004).
[5] Muthukumar M., Karuppiah M.T., Raju GB., Electrochemical Removal of CI Acid Orange 10 from Aqueous Solutions, Separation and Purification Technology, 55(2): 198-205 (2007).
[6] Naghizadeh A., Nabizadeh R., Removal of Reactive Blue 29 Dye with Modified Chitosan in Presence of Hydrogen Peroxide, Journal of Environment Protection Engineering, 42(1): 149-168 (2016).
[7] Annadurai G., Juang R-S., Lee D-J., Use of Cellulose-Based Wastes for Adsorption of Dyes from Aqueous Solutions, Journal of Hazardous Materials, 92(3): 263-274 (2002).
[8] Chiou M-S., Li H-Y., Equilibrium and Kinetic Modeling of Adsorption of Reactive Dye on Cross-Linked Chitosan Beads, Journal of Hazardous Materials, 93(2): 233-248 (2002).
[9] Ahmadi SH., Davar P., Manbohi A., Adsorptive Removal of Reactive Orange 122 from Aqueous Solutions by Ionic Liquid Coated Fe3O4 Magnetic Nanoparticles as an Efficient Adsorbent, Iranian Journal of Chemistry and Chemical Engineering (IJCCE), 35(1): 63-73 (2016).
[10] Zhang L., Cheng Z., Guo X., Jiang X., Liu R., Process Optimization, Kinetics and Equilibrium of Orange G and Acid Orange 7 Adsorptions onto Chitosan/Surfactant, Journal of Molecular Liquids, 197: 353-367 (2014).
[11] Su C-C., Pukdee-Asa M., Ratanatamskul C., Lu M-C., Effect of Operating Parameters on Decolorization and COD Removal of Three Reactive Dyes by Fenton's Reagent Using Fluidized-Bed Reactor, Desalination, 278(1): 211-218 (2011).
[12] Samarghandi M.R., Zarrabi M., Noori Sepehr M., Panahi R., Foroghi M., Removal of Acid Red 14 by Pumice Stone as a Low Cost Adsorbent: Kinetic and Equilibrium Study, Iranian Journal of Chemistry and Chemical Engineering (IJCCE), 31(3): 19-27 (2012).
[13] Lucas M.S., Peres J.A., Decolorization of the Azo Dye Reactive Black 5 by Fenton and photo-Fenton Oxidation, Dyes and Pigments, 71(3): 236-244 (2006).
[14] Shokoohi R., Vatanpoor V., Zarrabi M., Vatani A., Adsorption of Acid Red 18 (AR18) by Activated Carbon from Poplar Wood-A Kinetic and Equilibrium Study, Journal of Chemistry, 7(1): 65-72 (2010).
[15] Ishaq M., Saeed K., Ahmad I., Sultan S., Akhtar S., Coal Ash as a Low Cost Adsorbent for the Removal of Xylenol Orange from Aqueous Solution, Iran. J. Chem. Chem. Eng. (IJCCE), 33(1): 53-58 (2014).
[16] Royer B., Cardoso NF., Lima EC., Vaghetti JC., Simon NM., Calvete T., Veses R.C., Applications of Brazilian Pine-Fruit Shell in Natural and Carbonized Forms as Adsorbents to Removal of Methylene Blue from Aqueous Solutions—Kinetic and Equilibrium Study, Journal of Hazardous Materials, 164(2): 1213-1222 (2009).
[17] Shirzad-Siboni M., Fallah S., Tajasosi S., Removal of Acid Red 18 and Reactive Black 5 Dyes from Aquatic Solution by Using of Adsorption on Azollafiliculoides: a Kinetic Study, Journal of Guilan University of Medical Sciences, 22(88):
42-50 (2014).
[18] Wu C-H., Kuo C-Y., Chang C-L., Decolorization of Azo Dyes Using Catalytic Ozonation, Reaction Kinetics and Catalysis Letters, 91(1): 161-168 (2007).
[19] Ashtekar V., Bhandari V., Shirsath S., Chandra PS., Jolhe P., Ghodke S., Dye Wastewater Treatment: Removal of Reactive Dyes Using Inorganic and Organic Coagulants, J. Ind. Pollut. Control. Pap., 30: 33-42 (2014).
[20] Sakkayawong N., Thiravetyan P., Nakbanpote W., Adsorption Mechanism of Synthetic Reactive Dye Wastewater by Chitosan, Journal of Colloid and Interface Science, 286(1): 36-42 (2005).
[21] Morais L., Freitas O., Goncalves E., Vasconcelos L., Beca C.G., Reactive Dyes Removal from Wastewaters by Adsorption on Eucalyptus Bark: Variables that Define the Process, Water Research, 33(4): 979-988 (1999).
[22] Naghizadeh A., Nasseri S., Mahvi AH., Nabizadeh R., Kalantary RR., Rashidi A., Continuous Adsorption of Natural Organic Matters in a Column Packed with Carbon Nanotubes, Journal of Environmental Health Science and Engineering, 11(1): 11-14 (2013).
[23] Sharma P., Kaur H., Sharma M., Sahore V., A Review on Applicability of Naturally Available Adsorbents for the Removal of Hazardous Dyes from Aqueous Waste, Environmental Monitoring and Assessment, 183(1-4)” 151-195 (2011).
[24] Derakhshani E., Naghizadeh A., Ultrasound Regeneration of Multiwall Carbon Nanotubes Saturated by Humic Acid, Desalination and Water Treatment, 52(40-42): 7468-7472 (2014).
[25] Vakili M., Rafatullah M., Salamatinia B., Abdullah A.Z., Ibrahim MH., Tan KB., Gholami Z., Amouzgar P., Application of Chitosan and Its Derivatives as Adsorbents for Dye Removal from Water and Wastewater: A Review, Carbohydrate Polymers, 113: 115-130 (2014).
[26] Ngah WW., Teong L., Hanafiah M., Adsorption of Dyes and Heavy Metal Ions by Chitosan Composites: A Review, Carbohydrate Polymers, 83(4): 1446-1460 (2011).
[27] Mahmoodi NM., Salehi R., Arami M., Bahrami H., Dye Removal from Colored Textile Wastewater Using Chitosan in Binary Systems, Desalination, 267(1): 64-72 (2011).
[28] Futalan CM., Kan C-C., Dalida ML., Hsien K-J., Pascua C., Wan M-W., Comparative and Competitive Adsorption of Copper, Lead, and Nickel Using Chitosan Immobilized on Bentonite, Carbohydrate Polymers, 83(2): 528-536 (2011).
[29] Jagtap S., Yenkie M., Labhsetwar N., Rayalu S., Defluoridation of Drinking Water Using Chitosan Based Mesoporous Alumina, Microporous and Mesoporous Materials, 142(2): 454-463 (2011).
[30] Ngah WW., Fatinathan S., Yosop N., Isotherm and Kinetic Studies on the Adsorption of Humic Acid Onto Chitosan-H2SO4 Beads, Desalination, 272(1): 293-300 (2011).
[31] Riva R., Ragelle H., des Rieux A., Duhem N., Jérôme C., Préat V., “Chitosan and Chitosan Derivatives in Drug Delivery and Tissue Engineering, Chitosan for Bbiomaterials II”: Springer, 19-44 (2011).
[32] Crini G., Badot P-M., Application of Chitosan, A Natural Aminopolysaccharide, for Dye Removal from Aqueous Solutions by Adsorption Processes Using Batch Studies: A Review of Recent Literature, Progress in Polymer Science, 33(4): 399-447 (2008).
[33] Rinaudo M., Chitin and Chitosan: Properties and Applications, Progress in Polymer Science, 31(7): 603-633 (2006).
[34] Honarkar H., Barikani M., Applications of Biopolymers I: Chitosan, Monatshefte für Chemie-Chemical Monthly, 140(12): 1403-1417 (2009).
[35] Boamah P.O., Huang Y., Hua M., Zhang Q., Wu J., Onumah J., et al, Sorption of Heavy Metal Ions onto Carboxylate Chitosan Derivatives—A Mini-Review, Ecotoxicology and Environmental Safety, 116: 113-120 (2015).
[36] Dehghani M.H., Naghizadeh A., Rashidi A., Derakhshani E., Adsorption of Reactive Blue 29 Dye from Aqueous Solution by Multiwall Carbon Nanotubes, Desalination and Water Treatment, 51(40-42): 7655-7662 (2013).
[37] Rhazi M., Desbrieres J., Tolaimate A., Alagui A., Vottero P., Investigation of Different Natural Sources of Chitin: Influence of the Source and Deacetylation Process on the Physicochemical Characteristics of Chitosan, Polymer International, 49(4): 337-344 (2000).
[38] Percot A., Viton C., Domard A., Optimization of Chitin Extraction from Shrimp Shells, Biomacromolecules, 4(1): 12-18 (2003).
[39] Islam M.M., Masum S.M., Rahman MM., Molla M., Shaikh A., Roy S., Preparation of Chitosan from Shrimp Shell and Investigation of its Properties, International Journal of Basic & Applied Sciences, 11(1): 116-130 (2011).
[40] Naghizadeh A., Ghafouri M., Jafari A., Investigation of Equilibrium, Kinetics and Thermodynamics of Extracted Chitin From Shrimp Shell in Reactive Blue (KB-29) Removal From Aqueous Solution, Desalination and Water Treatment, 70: 355-363 (2017).
[41] Seyedi S.M., Anvaripour B., Motavassel M., Jadidi N., Comparative Cadmium Adsorption from Water by Nanochitosan and Chitosan, International Journal of Engineering and Innovative Technology, 2(9): 145-148 (2013).
[42] Karuppasamy K., Thanikaikarasan S., Antony R., Balakumar S., Shajan X.S., Effect of Nanochitosan on Electrochemical, Interfacial and Thermal Properties of Composite Solid Polymer Electrolytes, Ionics, 18(8): 737-745 (2012).
[43] Ramya R., Sudha P., Mahalakshmi J., Preparation and Characterization of Chitosan Binary Blend, Int. J. Sci. Res. Publ., 2(10): 1-9 (2012).
[44] Vijayalakshmi K., Gomathi T., Sudha P.N., Preparation and Characterization of Nanochitosan/Sodium Alginate/ Microcrystalline Cellulose Beads, Der Pharmacia Lettre, 6(4): 65-77 (2014).
[45] Hasan M., Ahmad A., Hameed B., Adsorption of Reactive Dye onto Cross-Linked Chitosan/Oil Palm Ash Composite Beads, Chemical Engineering Journal, 136(2): 164-172 (2008).
[46] Guibal E., Heterogeneous Catalysis on Chitosan-Based Materials: A Review, Progress in Polymer Science, 30(1): 71-109 (2005).
[47] Guibal E., Touraud E., Roussy J., Chitosan Interactions with Metal Ions and Dyes: Dissolved-State vs. Solid-State Application, World Journal of Microbiology and Biotechnology, 21(6-7): 913-920 (2005).
[48] Cestari A.R., Vieira E.F., Pinto A.A., Lopes E.C., Multistep Adsorption of Anionic Dyes on Silica/Chitosan Hybrid: 1. Comparative Kinetic Data from Liquid-and Solid-Phase Models, Journal of Colloid and Interface Science, 292(2): 363-372 (2005).
[49] Mirmohseni A., Dorraji MS., Figoli A., Tasselli F., Chitosan Hollow Fibers as Effective Biosorbent Toward Dye: Preparation and Modeling, Bioresource Technology, 121: 212-220 (2012).
[50] Li F., Ding C., Adsorption of Reactive Black M-2R on Different Deacetylation Degree Chitosan, Journal of Engineered Fibers and Fabrics, 6(3): 25-31 (2011).
[51] Naghizadeh A., Comparison Between Activated Carbon and Multiwall Carbon Nanotubes in the Removal of Cadmium (II) and Chromium (VI) from Water Solutions, Journal of Water Supply: Research and Technology-AQUA, 64(1): 64-73 (2015)
[52] Naghizadeh A., Shahabi H., Ghasemi F., Zarei A., Synthesis of Walnut Shell Modified with Titanium Dioxide and Zinc Oxide Nanoparticles for Efficient Removal of Humic Acid from Aqueous Solutions, Journal of Water and Health, 14(6): 889-997 (2016).
[53] Kyzas GZ., Bikiaris DN., Lazaridis N.K., Low-Swelling Chitosan Derivatives as Biosorbents for Basic Dyes, Langmuir, 24(9): 4791-4799 (2008).
[54] Wong Y., Szeto Y., Cheung W., McKay G., Adsorption of Acid Dyes on Chitosan—Equilibrium Isotherm Analyses, Process Biochemistry, 39(6): 695-704 (2004).
[55] Radaei E., Moghadam S.A., Arami M., The Study of the Adsorption of Reactive Blue 19 Dye by Activated Carbon from Pomegranate Residue, Water Wastewater J., 4: 27-34 (2012).
[56] Eser A., Tirtom V.N., Aydemir T., Becerik S., Dinçer A., Removal of Nickel (II) Ions by Histidine Modified Chitosan Beads, Chemical Engineering Journal, 210: 590-596 (2012).
[57] Dareini F., Amini M.A., Zarei S.H., Saghi M.H., Removal of Acid Black 1 Dye From Aqueous Solution Using Nano-Iron Particles, Journal of Sabzevar University of Medical Sciences, 782-790 (2014).
[58] Uslu G., Tanyol M., Equilibrium and Thermodynamic Parameters of Single and Binary Mixture Biosorption of Lead (II) and Copper (II) Ions onto Pseudomonas Putida: Effect of Temperature, Journal of Hazardous Materials, 135(1): 87-93 (2006).
[59] Fan L., Luo C., Sun M., Qiu H., Li X., Synthesis of Magnetic β-Cyclodextrin–Chitosan/Graphene Oxide as Nanoadsorbent and Its Application in Dye Adsorption and Removal, Colloids and Surfaces B: Biointerfaces, 103: 601-607 (2013).
[60] Lima I., Ribeiro E., Airoldi C., The Use of Chemical Modified Chitosam with Succinic Anhydride in the Methylene Blue Adsorption, Quím Nova, 29(3): 501-506 (2006).
[61] Hu Z., Zhang J., Chan W., Szeto Y., The Sorption of Acid Dye onto Chitosan Nanoparticles, Polymer, 47(16): 5838-5842 (2006).
[62] Huang X-Y., Bin J-P., Bu H-T., Jiang G-B., Zeng M-H., Removal of Anionic Dye Eosin Y from Aqueous Solution Using Ethylenediamine Modified Chitosan, Carbohydrate Polymers, 84(4): 1350-1356 (2011).
[63] Uzun I., Kinetics of the Adsorption of Reactive Dyes by Chitosan, Dyes and pigments, 70(2): 76-83 (2006).

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