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REMOVAL OF BASIC DYES FROM WASTEWATER BY USING NATURAL ZEOLITE: KINETIC AND EQUILIBRIUM STUDIES

Yıl 2017, Cilt: 12 Sayı: 3, 130 - 139, 06.07.2017

Öz

Due to their availability and
low cost, zeolites have found an important role in adsorption applications. In
this study, a natural zeolite, clinoptilolite, was investigated as an adsorbent
to remove basic dyes (methylene blue and rhodamine B) from aqueous solution by
using batch experiment system.
The natural zeolite used in
this experiment is mainly composed of clinoptiloite, quartz and heulandite and
has cation-exchange capacity of 2.76meq.g-1.
Parameters affecting adsorption mechanism such as initial concentration
of dyes (50–300mg/l) and contact time (10–325 minutes) on the dye adsorption
was examined
. From the obtained data it was observed that the
natural zeolite presented higher adsorption capacity for methylene blue than
rhodamine B with the maximal adsorption capacity of 10.776mg.g-1 and
7.348mg.g-1 at 250C for methylene blue and rhodamine B respectively.
The adsorption rate data were analyzed according to pseudo-first-order
and pseudo-second-order kinetic models. Kinetic evaluation indicated that the
basic dye adsorption on natural clinoptilolite followed the pseudo-second-order
model.

Kaynakça

  • 1. Rai, H.S., Bhattacharyya, M.S., Singh, J., Bansal, T.K., Vats, P., and Banerjee, U.C., (2005). Removal of Dyes from the Effluent of Textile and Dyestuff Manufacturing Industry: A Review of Emerging Techniques with Reference to Biological Treatment, Critical Reviews in Environmental Science and Technology, 35, 219-238.
  • 2. O’Neill, C., Hawkes, F.R., Hawkes, D.L., Lourenco, N.D., Pinheiro, H.M., and Delee, W., (1999). Colour in Textile Effluents-sources, Measurement, Discharge Consents and Simulation: A Review, Journal of Chemical Technology and Biotechnology, 74, 1009–1018.
  • 3. Vandevivere, P.C., Bianchi, R., and Verstraete, W., (1998). Treatment and Reuse of Wastewater from the Textile Wet-Processing Industry: Review of Emerging Technologies, Journal of Chemical Technology and Biotechnology, 72, 289–302.
  • 4. Sun, Q. and Yang, L., (2003). The Adsorption of Basic Dyes from Aqueous Solution on Modified Peat-Resin Particle, Water Research, 37, 1535–1544
  • 5. Ravi Kumar, M.N.V., Sridhari, T.R., Bhavani, K.D., and Dutta, P.K., (1998). Trends in Color Removal from Textile Mill Effluents, Bioresource Technology 45(8), 25-34
  • 6. Wang, S., Boyjoo, Y., Choueib, A., and Zhu, Z.H., (2005). Removal of Dyes from Aqueous Solution Using Fly Ash and Red Mud, Water Research, 39, 129–138.
  • 7. Metes, A., Kovacevic, D., Vujevic, D., and Papic, S., (2004), The Role of Zeolites in Wastewater Treatment of Printing Inks, Water Research, 38, 3373-3381.
  • 8. Derbyshire, F., Jagtoyen, M., Andrews, R., Rao, A., Martin-Gullon, I., and Grulke, E., (2001). Carbon Materials in Environmental Applications, In: Radovic, L.R. (Ed.), Chemistry and Physics of Carbon, Marcel Dekker, New York, 27, 1–66.
  • 9. Nandi, B.K., Goswami, A., and Purkait, M.K., (2009). Removal of Cationic Dyes from Aqueous Solutions by Kaolin: Kinetic and Equilibrium Studies, Applied Clay Science, 42, 583-590.
  • 10. Alkan, M., Demirbaş, O., Celikcapa, S., and Doğan, M., (2004). Sorption of Acid Red 57 from Aqueous Solutions onto Sepiolite, Journal of Hazardous Materials, 116, 135–145.
  • 11. Alkan, M., Celikcapa, S., Demirbaş, O., and Doğan, M., (2005). Removal of Reactive Blue 221 and Acid Blue 62 Anionic Dyes from Aqueous Solutions by Sepiolite, Dyes Pigments, 65, 251–259.
  • 12. Gürses, A., Karaca, S., Doğar, C., Bayrak, R., Açıkyıldız, M., and Yalçın, M., (2004). Determination of Adsorptive Properties of Clay/Water System: Methylene Blue Sorption, Journal of Colloid and Interface Science, 269, 310–314.
  • 13. Wang, C.C., Juang, L.C., Hsu, T.C., Lee, C.K., Lee, J.F., and Huang, F.C., (2004). Adsorption of Basic Dyes onto Montmorillonite. Journal of Colloid and Interface Science, 273, 80–86.
  • 14. Al-Bastaki, N. and Banat, F., (2004). Combining Ultrafiltration and Adsorption on Bentonite in a One-Step Process for the Treatment of Colored Waters, Resources Conservation Recycling, 41, 103–113.
  • 15. Özcan, A.S., Erdem, B., and Özcan, A., (2004). Adsorption of Acid Blue193 from Aqueous Solutions onto Na-Bentonite and DTMA-Bentonite, Journal of Colloid and Interface Science, 280, 44–54.
  • 16. Özdemir, O., Armağan, B., Turan, M., and Çelik, M.S., (2004). Comparison of the Adsorption Characteristics of Azo-Reactive Dyes on Mezoporous Minerals, Dyes Pigments, 62, 49–60.
  • 17. Al-Ghouti, M.A., Khraisheh, M.A.M., Allen, S.J., and Ahmad, M.N., (2003). The Removal of Dyes From Textile Wastewater: A Study of the Physical Characteristics and Adsorption Mechanisms of Diatomaceous Earth. Journal of Environmental Management, 69, 229–238.
  • 18. Atun, G., Hisarli, G., Sheldrick, W.S., and Muhler, M., (2003). Adsorptive Removal of Methylene Blue from Colored Effluents on Fuller’s Earth, Journal of Colloid and Interface Science, 261, 32–39.
  • 19. Espantaleon, A.G., Nieto, J.A., Fernandez, M., and Marsal, A., (2003). Use of Activated Clays in the Removal of Dyes and Surfactants from Tannery Waste Waters, Applied Clay Science, 24, 105–110.
  • 20. Orthman, J., Zhu, H.Y., and Lu, G.Q., (2003). Use of Anion Clay Hydrotalcite to Remove Coloured Organics from Aqueous Solutions. Seperation and Purification Technology, 31, 53–59. 21. Lazaridis, N.K., Karapantsios, T.D., and Geogantas, D., (2003). Kinetic Analysis for the Removal of a Reactive Dye from Aqueous Solution onto Hydrotalcite by Adsorption, Water Research, 37, 3023–3033.
  • 22. Shawabkeh, R.A. and Tutunji, M.F., (2003). Experimental Study and Modelling of Basic Dye Sorption by Diatomaceous Clay. Applied Clay Science, 24, 111–120.
  • 23. Neumann, M.G., Gessner, F., Schmitt, C.C., and Sartori, R., (2002). Influence of the Layer Charge and Clay Particle Size on the Interactions Between the Cationic Dye Methylene Blue and Clays in an Aqueous Suspension, Journal of Colloid and Interface Science, 255, 254–259.
  • 24. Ghosh, D. and Bhattacharyya, K.G., (2002). Adsorption of Methylene Blue on Kaolinite, Applied Clay Science, 20, 295–300.
  • 25. Pala, A. and Tokat, E., (2002). Color Removal from Cotton Textile Industry Wastewater in an Activated Sludge System with Various Additives, Water Research, 36, 2920–2925.
  • 26. Harris, R.G., Wells, J.D., and Johnson, B.B., (2001). Selective Adsorption of Dyes and Other Organic Molecules to Kaolinite and Oxide Surfaces, Colloid Surface A: Physicochemical Engineering Aspects, 180, 131–140.
  • 27. Ho, Y.S., Chiang, C.C., and Hsu, Y.C., (2001). Sorption Kinetics for Dye Removal from Aqueous Solution Using Activated Clay, Sepeartion Science and Technology, 36, 2473–2488.
  • 28. Bagane, M. and Guiza, S., (2000). Removal of a Dye from Textile Effluents by Adsorption, Annales de Chimie Science des Materiaux, 25, 615–626.
  • 29. Ramakrishna, K.R. and Viraraghavan, T., (1997). Dye Removal Using Low Cost Adsorbents, Water Science Technology, 36, 189–196.
  • 30. Kacha, S., Ouali, M.S., and Elmaleh, S., (1997). Dye Abatement of Textile Industry Wastewater with Bentonite and Aluminium Salts, Revue des Science de l’eau, 2, 233–248.
  • 31. El-Geundi, M.S., (1997). Adsorbents for Industrial Pollution Control, Adsorption Science Technology, 15, 777–787.
  • 32. Kahr, G. and Madsen, F.T., (1995). Determination of the Cation Exchange Capacity and the Surface Area of Bentonite, Illite and Kaolinite by Methylene Blue Adsorption, Applied Clay Science, 9, 327–336.
  • 33. Gupta, G.S., Shukla, S.P., Prasad, G., and Singh, V.N., (1992). China Clay as an Adsorbent for Dye House Wastewater, Environmental Technology, 13, 925– 936.
  • 34. Armağan, B., Turan, M., and Çelik, M.S., (2004), Equilibrium Studies on the Adsorption of Reactive Azo Ayes into Zeolite, Desalination, 170, 33-39.
  • 35. Meshko, V., Markovska, L., Mincheva, M., and Rodrigues, A.E., (2001). Adsorption of Basic Dyes on Granular Activated Carbon and Natural Zeolite, Water Research, 35, 3357–3366.
  • 36. Calzaferri, G., Bruhwiler, D., Megelski, S., Pfenniger, M., Pauchard, M., Hennessy, B., Maas, H., Devaux, A., and Graf, A., (2000). Playing with Dye Molecules at the Inner and Outer Surface of Zeolite L, Solid States Science, 2, 421–447.
  • 37. Ghobarkar, H., Schaf, O., and Guth, U., (1999). Zeolites from Kitchen to Space, Progress in Solid State Chemistry, 27, 29–73.
  • 38. Wang, S., Li, H., and Xu, L., (2006). Application of Zeolite MCM-22 for Basic Dye Removal from Waste Water, Journal of Colloid and Interface Science, 295, 71-78.
  • 39. Karcher, S., Kornmuller, A., and Jekel, M., (2001). Screening of Commercial Sorbents for the Removal of Reactive Dyes, Dyes Pigments, 51, 111– 125.
  • I. Langmuir, (1916). The Constitution and Fundamental Properties of Solids and Liquids, Journal of the American Chemical Society, 38, 2221–2295.
  • 40. Freundlich, H.M.F., (1906). Uber die Adsorption in Lasungen, Zeitschrift für Physikalische Chemie, 57, 385–470.
  • 41. Hameed, B.H., Din, A.T.M., and Ahmad, A.L., (2007), Adsorption of Methylene Blue onto Bamboo-Based Activated Carbon: Kinetics and Equilibrium Studies, Journal of Hazardous Materials, 141, 819-825.
  • 42. Do, D.D., (1998). Adsorption Analysis Equilibria and Kinetics, Series of Chemical Engineering 2, Imperial College Press, London.
  • 43. Boles, J.R., (1972). Composition, Optical Properties, Cell Dimensions, and Thermal Stability of some Heulandite Group Zeolites, American Mineralogist, 57, 1463-1493,
Yıl 2017, Cilt: 12 Sayı: 3, 130 - 139, 06.07.2017

Öz

Kaynakça

  • 1. Rai, H.S., Bhattacharyya, M.S., Singh, J., Bansal, T.K., Vats, P., and Banerjee, U.C., (2005). Removal of Dyes from the Effluent of Textile and Dyestuff Manufacturing Industry: A Review of Emerging Techniques with Reference to Biological Treatment, Critical Reviews in Environmental Science and Technology, 35, 219-238.
  • 2. O’Neill, C., Hawkes, F.R., Hawkes, D.L., Lourenco, N.D., Pinheiro, H.M., and Delee, W., (1999). Colour in Textile Effluents-sources, Measurement, Discharge Consents and Simulation: A Review, Journal of Chemical Technology and Biotechnology, 74, 1009–1018.
  • 3. Vandevivere, P.C., Bianchi, R., and Verstraete, W., (1998). Treatment and Reuse of Wastewater from the Textile Wet-Processing Industry: Review of Emerging Technologies, Journal of Chemical Technology and Biotechnology, 72, 289–302.
  • 4. Sun, Q. and Yang, L., (2003). The Adsorption of Basic Dyes from Aqueous Solution on Modified Peat-Resin Particle, Water Research, 37, 1535–1544
  • 5. Ravi Kumar, M.N.V., Sridhari, T.R., Bhavani, K.D., and Dutta, P.K., (1998). Trends in Color Removal from Textile Mill Effluents, Bioresource Technology 45(8), 25-34
  • 6. Wang, S., Boyjoo, Y., Choueib, A., and Zhu, Z.H., (2005). Removal of Dyes from Aqueous Solution Using Fly Ash and Red Mud, Water Research, 39, 129–138.
  • 7. Metes, A., Kovacevic, D., Vujevic, D., and Papic, S., (2004), The Role of Zeolites in Wastewater Treatment of Printing Inks, Water Research, 38, 3373-3381.
  • 8. Derbyshire, F., Jagtoyen, M., Andrews, R., Rao, A., Martin-Gullon, I., and Grulke, E., (2001). Carbon Materials in Environmental Applications, In: Radovic, L.R. (Ed.), Chemistry and Physics of Carbon, Marcel Dekker, New York, 27, 1–66.
  • 9. Nandi, B.K., Goswami, A., and Purkait, M.K., (2009). Removal of Cationic Dyes from Aqueous Solutions by Kaolin: Kinetic and Equilibrium Studies, Applied Clay Science, 42, 583-590.
  • 10. Alkan, M., Demirbaş, O., Celikcapa, S., and Doğan, M., (2004). Sorption of Acid Red 57 from Aqueous Solutions onto Sepiolite, Journal of Hazardous Materials, 116, 135–145.
  • 11. Alkan, M., Celikcapa, S., Demirbaş, O., and Doğan, M., (2005). Removal of Reactive Blue 221 and Acid Blue 62 Anionic Dyes from Aqueous Solutions by Sepiolite, Dyes Pigments, 65, 251–259.
  • 12. Gürses, A., Karaca, S., Doğar, C., Bayrak, R., Açıkyıldız, M., and Yalçın, M., (2004). Determination of Adsorptive Properties of Clay/Water System: Methylene Blue Sorption, Journal of Colloid and Interface Science, 269, 310–314.
  • 13. Wang, C.C., Juang, L.C., Hsu, T.C., Lee, C.K., Lee, J.F., and Huang, F.C., (2004). Adsorption of Basic Dyes onto Montmorillonite. Journal of Colloid and Interface Science, 273, 80–86.
  • 14. Al-Bastaki, N. and Banat, F., (2004). Combining Ultrafiltration and Adsorption on Bentonite in a One-Step Process for the Treatment of Colored Waters, Resources Conservation Recycling, 41, 103–113.
  • 15. Özcan, A.S., Erdem, B., and Özcan, A., (2004). Adsorption of Acid Blue193 from Aqueous Solutions onto Na-Bentonite and DTMA-Bentonite, Journal of Colloid and Interface Science, 280, 44–54.
  • 16. Özdemir, O., Armağan, B., Turan, M., and Çelik, M.S., (2004). Comparison of the Adsorption Characteristics of Azo-Reactive Dyes on Mezoporous Minerals, Dyes Pigments, 62, 49–60.
  • 17. Al-Ghouti, M.A., Khraisheh, M.A.M., Allen, S.J., and Ahmad, M.N., (2003). The Removal of Dyes From Textile Wastewater: A Study of the Physical Characteristics and Adsorption Mechanisms of Diatomaceous Earth. Journal of Environmental Management, 69, 229–238.
  • 18. Atun, G., Hisarli, G., Sheldrick, W.S., and Muhler, M., (2003). Adsorptive Removal of Methylene Blue from Colored Effluents on Fuller’s Earth, Journal of Colloid and Interface Science, 261, 32–39.
  • 19. Espantaleon, A.G., Nieto, J.A., Fernandez, M., and Marsal, A., (2003). Use of Activated Clays in the Removal of Dyes and Surfactants from Tannery Waste Waters, Applied Clay Science, 24, 105–110.
  • 20. Orthman, J., Zhu, H.Y., and Lu, G.Q., (2003). Use of Anion Clay Hydrotalcite to Remove Coloured Organics from Aqueous Solutions. Seperation and Purification Technology, 31, 53–59. 21. Lazaridis, N.K., Karapantsios, T.D., and Geogantas, D., (2003). Kinetic Analysis for the Removal of a Reactive Dye from Aqueous Solution onto Hydrotalcite by Adsorption, Water Research, 37, 3023–3033.
  • 22. Shawabkeh, R.A. and Tutunji, M.F., (2003). Experimental Study and Modelling of Basic Dye Sorption by Diatomaceous Clay. Applied Clay Science, 24, 111–120.
  • 23. Neumann, M.G., Gessner, F., Schmitt, C.C., and Sartori, R., (2002). Influence of the Layer Charge and Clay Particle Size on the Interactions Between the Cationic Dye Methylene Blue and Clays in an Aqueous Suspension, Journal of Colloid and Interface Science, 255, 254–259.
  • 24. Ghosh, D. and Bhattacharyya, K.G., (2002). Adsorption of Methylene Blue on Kaolinite, Applied Clay Science, 20, 295–300.
  • 25. Pala, A. and Tokat, E., (2002). Color Removal from Cotton Textile Industry Wastewater in an Activated Sludge System with Various Additives, Water Research, 36, 2920–2925.
  • 26. Harris, R.G., Wells, J.D., and Johnson, B.B., (2001). Selective Adsorption of Dyes and Other Organic Molecules to Kaolinite and Oxide Surfaces, Colloid Surface A: Physicochemical Engineering Aspects, 180, 131–140.
  • 27. Ho, Y.S., Chiang, C.C., and Hsu, Y.C., (2001). Sorption Kinetics for Dye Removal from Aqueous Solution Using Activated Clay, Sepeartion Science and Technology, 36, 2473–2488.
  • 28. Bagane, M. and Guiza, S., (2000). Removal of a Dye from Textile Effluents by Adsorption, Annales de Chimie Science des Materiaux, 25, 615–626.
  • 29. Ramakrishna, K.R. and Viraraghavan, T., (1997). Dye Removal Using Low Cost Adsorbents, Water Science Technology, 36, 189–196.
  • 30. Kacha, S., Ouali, M.S., and Elmaleh, S., (1997). Dye Abatement of Textile Industry Wastewater with Bentonite and Aluminium Salts, Revue des Science de l’eau, 2, 233–248.
  • 31. El-Geundi, M.S., (1997). Adsorbents for Industrial Pollution Control, Adsorption Science Technology, 15, 777–787.
  • 32. Kahr, G. and Madsen, F.T., (1995). Determination of the Cation Exchange Capacity and the Surface Area of Bentonite, Illite and Kaolinite by Methylene Blue Adsorption, Applied Clay Science, 9, 327–336.
  • 33. Gupta, G.S., Shukla, S.P., Prasad, G., and Singh, V.N., (1992). China Clay as an Adsorbent for Dye House Wastewater, Environmental Technology, 13, 925– 936.
  • 34. Armağan, B., Turan, M., and Çelik, M.S., (2004), Equilibrium Studies on the Adsorption of Reactive Azo Ayes into Zeolite, Desalination, 170, 33-39.
  • 35. Meshko, V., Markovska, L., Mincheva, M., and Rodrigues, A.E., (2001). Adsorption of Basic Dyes on Granular Activated Carbon and Natural Zeolite, Water Research, 35, 3357–3366.
  • 36. Calzaferri, G., Bruhwiler, D., Megelski, S., Pfenniger, M., Pauchard, M., Hennessy, B., Maas, H., Devaux, A., and Graf, A., (2000). Playing with Dye Molecules at the Inner and Outer Surface of Zeolite L, Solid States Science, 2, 421–447.
  • 37. Ghobarkar, H., Schaf, O., and Guth, U., (1999). Zeolites from Kitchen to Space, Progress in Solid State Chemistry, 27, 29–73.
  • 38. Wang, S., Li, H., and Xu, L., (2006). Application of Zeolite MCM-22 for Basic Dye Removal from Waste Water, Journal of Colloid and Interface Science, 295, 71-78.
  • 39. Karcher, S., Kornmuller, A., and Jekel, M., (2001). Screening of Commercial Sorbents for the Removal of Reactive Dyes, Dyes Pigments, 51, 111– 125.
  • I. Langmuir, (1916). The Constitution and Fundamental Properties of Solids and Liquids, Journal of the American Chemical Society, 38, 2221–2295.
  • 40. Freundlich, H.M.F., (1906). Uber die Adsorption in Lasungen, Zeitschrift für Physikalische Chemie, 57, 385–470.
  • 41. Hameed, B.H., Din, A.T.M., and Ahmad, A.L., (2007), Adsorption of Methylene Blue onto Bamboo-Based Activated Carbon: Kinetics and Equilibrium Studies, Journal of Hazardous Materials, 141, 819-825.
  • 42. Do, D.D., (1998). Adsorption Analysis Equilibria and Kinetics, Series of Chemical Engineering 2, Imperial College Press, London.
  • 43. Boles, J.R., (1972). Composition, Optical Properties, Cell Dimensions, and Thermal Stability of some Heulandite Group Zeolites, American Mineralogist, 57, 1463-1493,
Toplam 43 adet kaynakça vardır.

Ayrıntılar

Konular Mühendislik
Bölüm Makaleler
Yazarlar

Güzide Meltem Lüle Şenöz

Yayımlanma Tarihi 6 Temmuz 2017
Yayımlandığı Sayı Yıl 2017 Cilt: 12 Sayı: 3

Kaynak Göster

APA Lüle Şenöz, G. M. (2017). REMOVAL OF BASIC DYES FROM WASTEWATER BY USING NATURAL ZEOLITE: KINETIC AND EQUILIBRIUM STUDIES. Technological Applied Sciences, 12(3), 130-139.
AMA Lüle Şenöz GM. REMOVAL OF BASIC DYES FROM WASTEWATER BY USING NATURAL ZEOLITE: KINETIC AND EQUILIBRIUM STUDIES. NWSA. Temmuz 2017;12(3):130-139.
Chicago Lüle Şenöz, Güzide Meltem. “REMOVAL OF BASIC DYES FROM WASTEWATER BY USING NATURAL ZEOLITE: KINETIC AND EQUILIBRIUM STUDIES”. Technological Applied Sciences 12, sy. 3 (Temmuz 2017): 130-39.
EndNote Lüle Şenöz GM (01 Temmuz 2017) REMOVAL OF BASIC DYES FROM WASTEWATER BY USING NATURAL ZEOLITE: KINETIC AND EQUILIBRIUM STUDIES. Technological Applied Sciences 12 3 130–139.
IEEE G. M. Lüle Şenöz, “REMOVAL OF BASIC DYES FROM WASTEWATER BY USING NATURAL ZEOLITE: KINETIC AND EQUILIBRIUM STUDIES”, NWSA, c. 12, sy. 3, ss. 130–139, 2017.
ISNAD Lüle Şenöz, Güzide Meltem. “REMOVAL OF BASIC DYES FROM WASTEWATER BY USING NATURAL ZEOLITE: KINETIC AND EQUILIBRIUM STUDIES”. Technological Applied Sciences 12/3 (Temmuz 2017), 130-139.
JAMA Lüle Şenöz GM. REMOVAL OF BASIC DYES FROM WASTEWATER BY USING NATURAL ZEOLITE: KINETIC AND EQUILIBRIUM STUDIES. NWSA. 2017;12:130–139.
MLA Lüle Şenöz, Güzide Meltem. “REMOVAL OF BASIC DYES FROM WASTEWATER BY USING NATURAL ZEOLITE: KINETIC AND EQUILIBRIUM STUDIES”. Technological Applied Sciences, c. 12, sy. 3, 2017, ss. 130-9.
Vancouver Lüle Şenöz GM. REMOVAL OF BASIC DYES FROM WASTEWATER BY USING NATURAL ZEOLITE: KINETIC AND EQUILIBRIUM STUDIES. NWSA. 2017;12(3):130-9.