Araştırma Makalesi
BibTex RIS Kaynak Göster
Yıl 2020, , 131 - 142, 01.06.2020
https://doi.org/10.36222/ejt.649205

Öz

Kaynakça

  • Richardson, S.D., Kimura, S.Y., Water Analysis: Emerging Contaminants and Current Issues, Analytical Chemistry, 88 (2016), pp.546-582.
  • Schwarzenbach, R.P., Escher, B.I., Fenner, K., Hofstetter, T.B., Johnson, C.A., Von Gunten, U., Wehrli, B., The Challenge of Micropollutants in Aquatic Systems, Science, 313 (2006), pp.1072-1077.
  • Shannon, M.A., Bohn, P.W., Elimelech, M., Georgiadis, J.G., Marinas, B.J., Mayes, A.M., Science and Technology for Water Purification in the Coming Decades, Nature, 452 (2008), pp.301-310.
  • Birhanlı, A., Ozmen, M., Evaluation of the Toxicity and Teratogenity of Six Commercial Textile Dyes using the Frog Embryo Teratogenesis Assay–Xenopus, Drug and Chemical Toxicology, 28 (2005) 51-65.
  • Jadhav, J., Kalyani, D., Telke, A., Phugare, S., Govindwar, S.P., Evaluation of the Efficacy of a Bacterial Consortium for the Removal of Color, Reduction of Heavy Metals, and Toxicity from Textile Dye Effluent, Bioresource Technology, 101 (2010), pp.165-173.
  • Ali, I., New Generation Adsorbents for Water Treatment, Chemical Reviews, 112 (2012), pp.5073-5091.
  • Brillas, E., Martínez-Huitle, C.A., Decontamination of Wastewaters Containing Synthetic Organic Dyes by Electrochemical Methods, an Updated Review, Applied Catalysis B: Environmental, 166 (2015), pp.603-643.
  • Chong, M.N., Jin, B., Chow, C.W., Saint, C., Recent Developments in Photocatalytic Water Treatment Technology: A Review, Water research, 44 (2010), pp.2997-3027.
  • Kumar, S.S., Shantkriti, S., Muruganandham, T., Murugesh, E., Rane, N., Govindwar, S.P., Bioinformatics Aided Microbial Approach for Bioremediation of Wastewater Containing Textile Dyes, Ecological Informatics, 31 (2016), pp.112-121.
  • Li, J., Wang, X., Zhao, G., Chen, C., Chai, Z., Alsaedi, A., Hayat, T., Wang, X., Metal–Organic Framework-Based Materials: Superior Adsorbents for the Capture of Toxic and Radioactive Metal Ions, Chemical Society Reviews, 47 (2018), pp.2322-2356.
  • Kutluay, S., Baytar, O., Şahin Ö., Equilibrium, Kinetic and Thermodynamic Studies for Dynamic Adsorption of Benzene in Gas Phase onto Activated Carbon Produced from Elaeagnus Angustifolia Seeds, Journal of Environmental Chemical Engineering, 7 (2019), pp.102947.
  • Kutluay, S., Baytar, O., Şahin Ö., Adsorption Kinetics, Equilibrium and Thermodynamics of Gas-Phase Toluene onto Char Produced from Almond Shells, Research on Engineering Structures and Materials, 5 (2019), pp.279-298.
  • Khorramfar, S., Mahmoodi, N.M., Arami, M., Gharanjig, K., Equilibrium and Kinetic Studies of the Cationic Dye Removal Capability of a Novel Biosorbent Tamarindus Indica from Textile Wastewater, Coloration Technology, 126 (2010), pp.261-268.
  • Baytar, O., Şahin, Ö., Saka, C., Sequential Application of Microwave and Conventional Heating Methods for Preparation of Activated Carbon from Biomass and Its Methylene Blue Adsorption, Applied Thermal Engineering, 138 (2018), pp.542-551.
  • [Özhan, A., Şahin, Ö., Küçük, M.M., Saka, C., Preparation and Characterization of Activated Carbon from Pine Cone by Microwave-Induced ZnCl2 Activation and Its Effects on the Adsorption of Methylene Blue, Cellulose, 21 (2014), pp.2457-2467.
  • Pavan, F.A., Lima, E.C., Dias, S.L., Mazzocato, A.C., Methylene Blue Biosorption from Aqueous Solutions by Yellow Passion Fruit Waste, Journal of Hazardous Materials, 150 (2008), pp.703-712.
  • Low, L.W., Teng, T.T., Rafatullah, M., Morad, N., Azahari, B., Adsorption Studies of Methylene Blue and Malachite Green from Aqueous Solutions by Pretreated Lignocellulosic Materials, Separation Science and Technology, 48 (2013), pp.1688-1698.
  • Bhattacharyya, K.G., Sharma, A., Kinetics and Thermodynamics of Methylene Blue Adsorption on Neem (Azadirachta Indica) Leaf Powder, Dyes and Pigments, 65 (2005), pp.51-59.
  • Ncibi, M.C., Mahjoub, B., Seffen, M., Kinetic and Equilibrium Studies of Methylene Blue Biosorption by Posidonia Oceanica (L.) Fibres, Journal of Hazardous Materials, 139 (2007), pp.280-285.
  • Vadivelan, V., Kumar, K.V., Equilibrium, Kinetics, Mechanism, and Process Design for the Sorption of Methylene Blue onto Rice Husk, Journal of Colloid and Interface Science, 286 (2005), pp.90-100.
  • Bulut, Y., Aydın, H., A Kinetics and Thermodynamics Study of Methylene Blue Adsorption on Wheat Shells, Desalination, 194 (2006), pp.259-267.
  • Hameed, B., Ahmad, A., Batch Adsorption of Methylene Blue from Aqueous Solution by Garlic Peel, an Agricultural Waste Biomass, Journal of Hazardous Materials, 164 (2009), pp.870-875.
  • Oliveira, L.S., Franca, A.S., Alves, T.M., Rocha, S.D., Evaluation of Untreated Coffee Husks as Potential Biosorbents for Treatment of Dye Contaminated Waters, Journal of Hazardous Materials, 155 (2008), pp.507-512.
  • Hameed, B., Evaluation of Papaya Seeds as a Novel Non-Conventional Low-Cost Adsorbent for Removal of Methylene Blue, Journal of Hazardous Materials, 162 (2009), pp.939-944.
  • Royer, B., Cardoso, N.F., Lima, E.C., Vaghetti, J.C., Simon, N.M., 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 (2009), pp.1213-1222.
  • Ceyhan, A.A., Baytar, O., Güngör, A., Saygınlı, E., Söylemez, C., Removal of Malachite Green from Aqueous Solutions using Formaldehyde Treated Elaegnus Angustifalia Seeds, Selcuk University Journal of Engineering, Science and Technology, (2013).
  • Saka, C., Sahin, Ö., Removal of Methylene Blue from Aqueous Solutions by using Cold Plasma‐and Formaldehyde‐Treated Onion Skins, Coloration Technology, 127 (2011), pp.246-255.
  • Saka, C., Şahin, Ö., Adsoy, H., Akyel, Ş.M., Removal of Methylene Blue from Aqueous Solutions by Using Cold Plasma, Microwave Radiation and Formaldehyde Treated Acorn Shell, Separation Science and Technology, 47 (2012), pp.1542-1551.
  • Amini, M., Abbaspour, K.C., Johnson, C.A., A Comparison of Different Rule-Based Statistical Models for Modeling Geogenic Groundwater Contamination, Environmental Modelling & Software, 25 (2010), pp.1650-1657.
  • Bashir, M.J., Aziz, H.A., Yusoff, M.S., Adlan, M.N., Application of Response Surface Methodology (RSM) for Optimization of Ammoniacal Nitrogen Removal From Semi-Aerobic Landfill Leachate Using Ion Exchange Resin, Desalination, 254 (2010), pp.154-161.
  • Geyikçi, F., Kılıç, E., Çoruh, S., Elevli, S., Modelling of Lead Adsorption from Industrial Sludge Leachate on Red Mud by Using RSM And ANN, Chemical Engineering Journal, 183 (2012), pp.53-59.
  • Hamzaoui, A.H., Jamoussi, B., M'nif, A., Lithium Recovery from Highly Concentrated Solutions: Response Surface Methodology (RSM) Process Parameters Optimization, Hydrometallurgy, 90 (2008), pp.1-7.
  • Kalavathy, H., Regupathi, I., Pillai, M.G., Miranda, L.R., Modelling, Analysis and Optimization of Adsorption Parameters for H3PO4 Activated Rubber Wood Sawdust Using Response Surface Methodology (RSM), Colloids and Surfaces B: Biointerfaces, 70 (2009), pp.35-45.
  • Ghelich, R., Jahannama, M.R., Abdizadeh, H., Torknik, F.S., Vaezi, M.R., Central Composite Design (CCD)-Response Surface Methodology (RSM) of Effective Electrospinning Parameters on PVP-B-Hf Hybrid Nanofibrous Composites for Synthesis of Hfb2-Based Composite Nanofibers, Composites Part B: Engineering, 166 (2019), pp.527-541.
  • Erbay, Z., Icier, F., Optimization of Hot Air Drying of Olive Leaves Using Response Surface Methodology, Journal of Food Engineering, 91 (2009), pp.533-541.
  • Rai, A., Mohanty, B., Bhargava, R., Supercritical Extraction of Sunflower Oil: A Central Composite Design for Extraction Variables, Food Chemistry, 192 (2016), pp.647-659.
  • Pimenta, C.D., Silva, M.B., de Morais Campos, R.L., de Campos Junior, W.R., Desirability and Design of Experiments Applied to the Optimization of the Reduction of Decarburization of the Process Heat Treatment for Steel Wire SAE 51B35, American Journal of Theoretical and Applied Statistics, 7 (2018), pp.35-44.
  • Vargas, A.M.M., Cazetta, A.L., Kunita, M., Silva, T.L., Almeida, V., Adsorption of Methylene Blue on Activated Carbon Produced from Flamboyant Pods ( Delonix Regia): Study of Adsorption Isotherms and Kinetic Models, Chemical Engineering Journal, 168 (2011), pp.722-730.
  • Sari, A., Tuzen, M., Citak, D., Soylak, M., Equilibrium, Kinetic and Thermodynamic Studies of Adsorption of Pb(II) from Aqueous Solution onto Turkish Kaolinite Clay, Journal of Hazardous Materials, 149 (2007), pp.283-291.
  • Dursun, A.Y., Kalayci, Ç.S., Equilibrium, Kinetic and Thermodynamic Studies on the Adsorption of Phenol onto Chitin, Journal of Hazardous Materials, 123 (2005), pp.151-157.
  • Ammendola, P., Raganati, F., Chirone, R., CO2 Adsorption on a Fine Activated Carbon in a Sound Assisted Fluidized Bed: Thermodynamics and Kinetics, Chemical Engineering Journal, 322 (2017), pp.302-313.

OPTIMIZATION OF PROCESS CONDITIONS FOR ADSORPTION OF METHYLENE BLUE ON FORMALDEHYDE-MODIFIED PEANUT SHELLS USING BOX-BEHNKEN EXPERIMENTAL DESIGN AND RESPONSE SURFACE METHODOLOGY

Yıl 2020, , 131 - 142, 01.06.2020
https://doi.org/10.36222/ejt.649205

Öz

This paper presents the use of
formaldehyde-modified peanut shells as bioadsorbent for the adsorption of
methylene blue for the first time. Firstly, the effect of medium pH, which is
one of the important parameters for adsorption process, was determined. Then,
the adsorption process conditions such as adsorption time (30-150 min), initial
concentration (50-200 ppm) and ambient temperature (25-40°C) were optimized by
using response surface methodology (RSM) based on Box-Behnken experimental
design.
The pseudo-first
order and pseudo-second order kinetic models were used to evaluate the
adsorption kinetic in this study under optimized process conditions
. The maximum adsorption
capacity was found under optimum process conditions; 92.25 min adsorption time,
191.87 ppm initial concentration, 39.70°C adsorption temperature. The maximum
adsorption capacity for methylene blue was determined to be 43.84 mg/g using RSM
based on Box-Behnken experimental design. Adsorption kinetic results showed
that the plots of the pseudo-second order kinetic model were fit the
experimental data better when compared to the pseudo-first order model. In
addition, results indicated that formadehite-modified peanut shells could be
used as low cost and effective bioadsorbent for the adsorption of methylene
blue, which is one of the important dyes.

Furthermore, it was concluded that
the RSM based on Box-Behnken experimental design can be applied successfully
for the methylene adsorption process.

Kaynakça

  • Richardson, S.D., Kimura, S.Y., Water Analysis: Emerging Contaminants and Current Issues, Analytical Chemistry, 88 (2016), pp.546-582.
  • Schwarzenbach, R.P., Escher, B.I., Fenner, K., Hofstetter, T.B., Johnson, C.A., Von Gunten, U., Wehrli, B., The Challenge of Micropollutants in Aquatic Systems, Science, 313 (2006), pp.1072-1077.
  • Shannon, M.A., Bohn, P.W., Elimelech, M., Georgiadis, J.G., Marinas, B.J., Mayes, A.M., Science and Technology for Water Purification in the Coming Decades, Nature, 452 (2008), pp.301-310.
  • Birhanlı, A., Ozmen, M., Evaluation of the Toxicity and Teratogenity of Six Commercial Textile Dyes using the Frog Embryo Teratogenesis Assay–Xenopus, Drug and Chemical Toxicology, 28 (2005) 51-65.
  • Jadhav, J., Kalyani, D., Telke, A., Phugare, S., Govindwar, S.P., Evaluation of the Efficacy of a Bacterial Consortium for the Removal of Color, Reduction of Heavy Metals, and Toxicity from Textile Dye Effluent, Bioresource Technology, 101 (2010), pp.165-173.
  • Ali, I., New Generation Adsorbents for Water Treatment, Chemical Reviews, 112 (2012), pp.5073-5091.
  • Brillas, E., Martínez-Huitle, C.A., Decontamination of Wastewaters Containing Synthetic Organic Dyes by Electrochemical Methods, an Updated Review, Applied Catalysis B: Environmental, 166 (2015), pp.603-643.
  • Chong, M.N., Jin, B., Chow, C.W., Saint, C., Recent Developments in Photocatalytic Water Treatment Technology: A Review, Water research, 44 (2010), pp.2997-3027.
  • Kumar, S.S., Shantkriti, S., Muruganandham, T., Murugesh, E., Rane, N., Govindwar, S.P., Bioinformatics Aided Microbial Approach for Bioremediation of Wastewater Containing Textile Dyes, Ecological Informatics, 31 (2016), pp.112-121.
  • Li, J., Wang, X., Zhao, G., Chen, C., Chai, Z., Alsaedi, A., Hayat, T., Wang, X., Metal–Organic Framework-Based Materials: Superior Adsorbents for the Capture of Toxic and Radioactive Metal Ions, Chemical Society Reviews, 47 (2018), pp.2322-2356.
  • Kutluay, S., Baytar, O., Şahin Ö., Equilibrium, Kinetic and Thermodynamic Studies for Dynamic Adsorption of Benzene in Gas Phase onto Activated Carbon Produced from Elaeagnus Angustifolia Seeds, Journal of Environmental Chemical Engineering, 7 (2019), pp.102947.
  • Kutluay, S., Baytar, O., Şahin Ö., Adsorption Kinetics, Equilibrium and Thermodynamics of Gas-Phase Toluene onto Char Produced from Almond Shells, Research on Engineering Structures and Materials, 5 (2019), pp.279-298.
  • Khorramfar, S., Mahmoodi, N.M., Arami, M., Gharanjig, K., Equilibrium and Kinetic Studies of the Cationic Dye Removal Capability of a Novel Biosorbent Tamarindus Indica from Textile Wastewater, Coloration Technology, 126 (2010), pp.261-268.
  • Baytar, O., Şahin, Ö., Saka, C., Sequential Application of Microwave and Conventional Heating Methods for Preparation of Activated Carbon from Biomass and Its Methylene Blue Adsorption, Applied Thermal Engineering, 138 (2018), pp.542-551.
  • [Özhan, A., Şahin, Ö., Küçük, M.M., Saka, C., Preparation and Characterization of Activated Carbon from Pine Cone by Microwave-Induced ZnCl2 Activation and Its Effects on the Adsorption of Methylene Blue, Cellulose, 21 (2014), pp.2457-2467.
  • Pavan, F.A., Lima, E.C., Dias, S.L., Mazzocato, A.C., Methylene Blue Biosorption from Aqueous Solutions by Yellow Passion Fruit Waste, Journal of Hazardous Materials, 150 (2008), pp.703-712.
  • Low, L.W., Teng, T.T., Rafatullah, M., Morad, N., Azahari, B., Adsorption Studies of Methylene Blue and Malachite Green from Aqueous Solutions by Pretreated Lignocellulosic Materials, Separation Science and Technology, 48 (2013), pp.1688-1698.
  • Bhattacharyya, K.G., Sharma, A., Kinetics and Thermodynamics of Methylene Blue Adsorption on Neem (Azadirachta Indica) Leaf Powder, Dyes and Pigments, 65 (2005), pp.51-59.
  • Ncibi, M.C., Mahjoub, B., Seffen, M., Kinetic and Equilibrium Studies of Methylene Blue Biosorption by Posidonia Oceanica (L.) Fibres, Journal of Hazardous Materials, 139 (2007), pp.280-285.
  • Vadivelan, V., Kumar, K.V., Equilibrium, Kinetics, Mechanism, and Process Design for the Sorption of Methylene Blue onto Rice Husk, Journal of Colloid and Interface Science, 286 (2005), pp.90-100.
  • Bulut, Y., Aydın, H., A Kinetics and Thermodynamics Study of Methylene Blue Adsorption on Wheat Shells, Desalination, 194 (2006), pp.259-267.
  • Hameed, B., Ahmad, A., Batch Adsorption of Methylene Blue from Aqueous Solution by Garlic Peel, an Agricultural Waste Biomass, Journal of Hazardous Materials, 164 (2009), pp.870-875.
  • Oliveira, L.S., Franca, A.S., Alves, T.M., Rocha, S.D., Evaluation of Untreated Coffee Husks as Potential Biosorbents for Treatment of Dye Contaminated Waters, Journal of Hazardous Materials, 155 (2008), pp.507-512.
  • Hameed, B., Evaluation of Papaya Seeds as a Novel Non-Conventional Low-Cost Adsorbent for Removal of Methylene Blue, Journal of Hazardous Materials, 162 (2009), pp.939-944.
  • Royer, B., Cardoso, N.F., Lima, E.C., Vaghetti, J.C., Simon, N.M., 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 (2009), pp.1213-1222.
  • Ceyhan, A.A., Baytar, O., Güngör, A., Saygınlı, E., Söylemez, C., Removal of Malachite Green from Aqueous Solutions using Formaldehyde Treated Elaegnus Angustifalia Seeds, Selcuk University Journal of Engineering, Science and Technology, (2013).
  • Saka, C., Sahin, Ö., Removal of Methylene Blue from Aqueous Solutions by using Cold Plasma‐and Formaldehyde‐Treated Onion Skins, Coloration Technology, 127 (2011), pp.246-255.
  • Saka, C., Şahin, Ö., Adsoy, H., Akyel, Ş.M., Removal of Methylene Blue from Aqueous Solutions by Using Cold Plasma, Microwave Radiation and Formaldehyde Treated Acorn Shell, Separation Science and Technology, 47 (2012), pp.1542-1551.
  • Amini, M., Abbaspour, K.C., Johnson, C.A., A Comparison of Different Rule-Based Statistical Models for Modeling Geogenic Groundwater Contamination, Environmental Modelling & Software, 25 (2010), pp.1650-1657.
  • Bashir, M.J., Aziz, H.A., Yusoff, M.S., Adlan, M.N., Application of Response Surface Methodology (RSM) for Optimization of Ammoniacal Nitrogen Removal From Semi-Aerobic Landfill Leachate Using Ion Exchange Resin, Desalination, 254 (2010), pp.154-161.
  • Geyikçi, F., Kılıç, E., Çoruh, S., Elevli, S., Modelling of Lead Adsorption from Industrial Sludge Leachate on Red Mud by Using RSM And ANN, Chemical Engineering Journal, 183 (2012), pp.53-59.
  • Hamzaoui, A.H., Jamoussi, B., M'nif, A., Lithium Recovery from Highly Concentrated Solutions: Response Surface Methodology (RSM) Process Parameters Optimization, Hydrometallurgy, 90 (2008), pp.1-7.
  • Kalavathy, H., Regupathi, I., Pillai, M.G., Miranda, L.R., Modelling, Analysis and Optimization of Adsorption Parameters for H3PO4 Activated Rubber Wood Sawdust Using Response Surface Methodology (RSM), Colloids and Surfaces B: Biointerfaces, 70 (2009), pp.35-45.
  • Ghelich, R., Jahannama, M.R., Abdizadeh, H., Torknik, F.S., Vaezi, M.R., Central Composite Design (CCD)-Response Surface Methodology (RSM) of Effective Electrospinning Parameters on PVP-B-Hf Hybrid Nanofibrous Composites for Synthesis of Hfb2-Based Composite Nanofibers, Composites Part B: Engineering, 166 (2019), pp.527-541.
  • Erbay, Z., Icier, F., Optimization of Hot Air Drying of Olive Leaves Using Response Surface Methodology, Journal of Food Engineering, 91 (2009), pp.533-541.
  • Rai, A., Mohanty, B., Bhargava, R., Supercritical Extraction of Sunflower Oil: A Central Composite Design for Extraction Variables, Food Chemistry, 192 (2016), pp.647-659.
  • Pimenta, C.D., Silva, M.B., de Morais Campos, R.L., de Campos Junior, W.R., Desirability and Design of Experiments Applied to the Optimization of the Reduction of Decarburization of the Process Heat Treatment for Steel Wire SAE 51B35, American Journal of Theoretical and Applied Statistics, 7 (2018), pp.35-44.
  • Vargas, A.M.M., Cazetta, A.L., Kunita, M., Silva, T.L., Almeida, V., Adsorption of Methylene Blue on Activated Carbon Produced from Flamboyant Pods ( Delonix Regia): Study of Adsorption Isotherms and Kinetic Models, Chemical Engineering Journal, 168 (2011), pp.722-730.
  • Sari, A., Tuzen, M., Citak, D., Soylak, M., Equilibrium, Kinetic and Thermodynamic Studies of Adsorption of Pb(II) from Aqueous Solution onto Turkish Kaolinite Clay, Journal of Hazardous Materials, 149 (2007), pp.283-291.
  • Dursun, A.Y., Kalayci, Ç.S., Equilibrium, Kinetic and Thermodynamic Studies on the Adsorption of Phenol onto Chitin, Journal of Hazardous Materials, 123 (2005), pp.151-157.
  • Ammendola, P., Raganati, F., Chirone, R., CO2 Adsorption on a Fine Activated Carbon in a Sound Assisted Fluidized Bed: Thermodynamics and Kinetics, Chemical Engineering Journal, 322 (2017), pp.302-313.
Toplam 41 adet kaynakça vardır.

Ayrıntılar

Birincil Dil İngilizce
Konular Kimya Mühendisliği
Bölüm Araştırma Makalesi
Yazarlar

Sinan Kutluay 0000-0002-6340-0752

Orhan Baytar 0000-0002-2915-202X

Ömer Şahin 0000-0003-4575-3762

Ali Arran Bu kişi benim

Yayımlanma Tarihi 1 Haziran 2020
Yayımlandığı Sayı Yıl 2020

Kaynak Göster

APA Kutluay, S., Baytar, O., Şahin, Ö., Arran, A. (2020). OPTIMIZATION OF PROCESS CONDITIONS FOR ADSORPTION OF METHYLENE BLUE ON FORMALDEHYDE-MODIFIED PEANUT SHELLS USING BOX-BEHNKEN EXPERIMENTAL DESIGN AND RESPONSE SURFACE METHODOLOGY. European Journal of Technique (EJT), 10(1), 131-142. https://doi.org/10.36222/ejt.649205

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