Research Article
BibTex RIS Cite

Fast Adsorption of Methylene Blue By Filter Coffee Waste

Year 2020, Volume: 15 Issue: 4, 111 - 120, 26.10.2020

Abstract

In this study, removal of a cationic dye methylene blue by filter coffee grounds as a potential waste was investigated. Systematically, the effect of initial dye concentration, pH and contact time on the adsorption efficiency were determined. Isotherm and kinetic models were studied. Langmuir and Freundlich model were calculated for adsorption of methylene blue. Langmuir model is better fit than Freundlich model (R2=0.9892). The maximum adsorption capacity of filter coffee waste were 312.515 mg/g. Scanning electron microscope (SEM) images were used to record the surface characteristics and morphological features of filter coffee waste. This study emphases that filter coffee waste can effectively remove methylene blue from aqueous solution.

References

  • Liu, J., Guo, D., Zhou, Y., Wu, Z., Li, W., Zhao, F., and Zheng, X., (2011). Identification of Ancient Textiles from Yingpan, Xinjiang, By Multiple Analytical Techniques. J. Archaeol. Science. 38:1763-1770.
  • Nassar, N.N. and Ringsered A., (2011). Rapid Adsorption of Methylene Blue from Aqueous Solutions by Goethite Nanoadsorbents. Environmental Engineering Science. 29:8.
  • Liu, J., Wang, N., Zhang, H., and Baeyens J., (2019). Adsorption of Congo Red dye on FexCo3-xO4nanoparticles. Journal of Environmental Management. 238:473-483.
  • Khorasani, A.C. and Shojaosadati, S.A., (2019). Magmetic Pectin- Chlorella Vulgarisbiosorbent for the Adsorption of Dyes. Journal of Environmental Chemical Engineering. 7:103062.
  • Siddique, M.R., Farooq, A., Khalid, A., Farooq, Q., Mahmood, U., Farooq, I.A., and Raja Saleem, F.S., (2009). Thermal-pressure-Mediated Hydrolysis of Reactive Blue 19 Dye. J. Hazard Material. 172(2):1007-1012.
  • Chaudhari, A.U., Paul, D., Dhotre, D., and Kodam, K.M., (2017). Effective Biotransformation and Detoxification of Anthraquinone Dye Reactive Blue 4 by Using Aerobic Bacterial Granules. Water Resources. 122:603-613.
  • Gupta, V.K., (2009). Application of Low-cost Adsorbents for Dye Removal – a Review. Journal Environ Management. 90(8):2313-2342.
  • Jamshidi, M., Ghaedi, M., Dashtian, K., Ghaedi, A.M., Hajati, S., Goudarzi, A., and Alipanahpour, E., (2016). Highly Efficient Simultaneous Ultrasonic Assisted Adsorption of Brilliant Green and Eosin B onto ZnS Nanoparticles Loaded Activated Carbon: Artificial Neural Network Modeling and Central Composite Design Optimization. Spectrochim Acta A. 153:257-267.
  • Mosleh, S., Rahimi, M.R., Ghaedi, M., Dashtian, K., and Hajati, S., (2016). Photocatalytic Degradation of Binary Mixture of toxic dyes by HKUST-1 MOF and HKUST-1-SBA-15 in a rotating packed bed reactor under blue LED illumination: central composite design optimization. RSC Adv, 6 (21): 17204-17214.
  • Mosleh, S., Rahimi, M.R., Ghaedi, M., Dashtian, K., Hajati, S., (2016). BiPO4/Bi2S3-HKUST-1-MOF as a Novel Blue Light-Driven Photocatalyst for Simultaneous Degradation of Toluidine Blue and Auramine-O Dyes in a New Rotating Packed Bed Reactor: Optimization And Comparison to a Conventional Reactor. RSC Adv. 6(68):63667-63680.
  • Mosleh, S., Rahimi, M.R., Ghaedi, M., Dashtian, K., Hajati, S., and Wang, S., (2017). Ag3PO4/AgBr/Ag-HKUST-1-MOF Composites as Novel Blue LED Light Active Photocatalyst for Enhanced Degradation of Ternary Mixture of Dyes in a Rotating Packed Bed Reactor. Chem Eng Process. 114:24-38.
  • Mondal, S., (2008). Methods of Dye Removal from Dye House Effluent—An Overview, Environmental Engineering Science. 25:3.
  • Cestari, A.R., Vieira, E.F., Vieira, G.S., Costa, L.P., Tavares, A.M., and Loh W., (2009). The Removal of Reactive Dyes from Aqueous Solutions Using Chemically Modified Mesoporous Silica in the Presence of Anionic Surfactant—The Temperature Dependence and a Thermodynamic Multivariate Analysis. Journal of Hazardous Material. 161(1):307-316.
  • Kallel, F., Bouaziz, F., Chaari, F., Belghith, L., Ghorbel, R., and Chaabouni, S.E., (2016). Interactive Effect of Garlic Straw on the Sorption and Desorption of Direct Red 80 from Aqueous Solution. Process Saf. Environ. Protect. 102:30-43.
  • Ma, Z., Liu, D., Zhu, Y., Li, Z., Li, Z., Tian, H., and Liu H., (2016). Graphene Oxide/chitin Nanofibril Composite Foams as Column Adsorbents for Aqueous Pollutants. Carbohydr. Polym. 144:230-237.
  • Zhou, L., Zhou, H., Hu, Y., Yan, S., and Yang, J., (2019). Adsorption Removal of Cationic Dyes from Aqueous Solutions Using Ceramicadsorbents Prepared from Industrial Waste Coal Gangue. Journal of Environmental Management. 234:245-252.
  • Deniz, F., (2013). Dye Removal by Almond Shell Residues: Studies on Biosorption Performance and Process Design. Mater. Sci. Eng. C. 33(5):2821-2826.
  • Oguntimein, G.B., (2015). Biosorption of Dye from Textile Wastewater Effluent onto Alkali Treated Dried Sunflower Seed Hull and Design of a Batch Adsorber. Journal of Environmental Chemical Engineering. 3(4):2647-2661.
  • Lee, L.Y., Gan, S., Yin, M.S., Tan, S.S., Lim, X.J.L., and Lam, Y.F., (2016). Effective Removal of Acid Blue 113 Dye Using Overripe Cucumis Sativus Peel as an Eco-Friendly Biosorbent from Agricultural Residue. J. Clean. Prod. 113:194-203.
  • Wong, H.H., Tumari, N., Ngadi, N.B., Mohamed, O., Hassan, R., Mat, N.A., and Saidina, A., (2019). Adsorption of Anionic Dyes on Spent Tea Leaves Modified with Polyethyleneimine (PEI-STL). J. Clean. Prod. 206:394-406.
  • Irem, S.Q., Mahmood Khan, E., Islam, A., Jamal Hashmat, M., Anwar ul Haq, M., and Afzal, M.T., (2013). Enhanced Removal of Reactive Navy Blue Dye Using Powdered Orange Waste. Ecol. Eng. 58:399-405.
  • Kwon, E.E., Yi, H., and Jeon, Y.J., (2013). Sequential co-Production of Biodiesel and Bioethanol with Spent Coffee Grounds. Bioresour Technol. 136:475-480.
  • Dai, Y., Zhang, D., and Zhang, K., (2016). Nitrobenzene-Adsorption Capacity of NaOH-modified Spent Coffee Ground from Aqueous Solution. Journal of Taiwan Institute of Chemical Engineering Journal. 68:232-238. https://en.wikipedia.org/wiki/Methylene_blue, Availabre: 20.03.2019.
  • Baek, M.H., Ijagbemi, C.O., Se-Jin, O., and Kim, D.S., (2010) Removal of Malachite Green from Aqueous Solution Using Degreased Coffee Bean. Journal of Hazardous Materials. 176:820–828.
  • Aksu, Z. and Donmez, G., (2003). A comparative Study on the Biosorption Characteristicsof Some Yeasts for Remazol Blue Reactive Dye. Chemosphere. 50(8):1075-1083.
  • Lou T., Yan, X., and Wang X., (2019). Chitosan Coated Polyacrylonitrile Nanofibrous Mat for dye Adsorption. International Journal of Biological Macromolecules. 135:919-925.
  • Gamoudi, S. and Srasra, E., (2019). Adsorption of Organic Dyes by HDPyþ-modified Clay: Effect of Molecular Structure on the Adsorption. Journal of Molecular Structure. 1193:522-531.
  • Magdy, Y.H. and Altaher, H., (2018). Kinetic Analysis of the Adsorption of Dyes from High Strength Wastewater Oncement Kiln Dust. Journal of Environmental Chemical Engineering. 6:834-841.
  • Zuorro, A., Lavecchia, R., and Natali, S., (2014). Magnetically Modified Agro-industrial Wastes as Efficient and Easily Recoverable Adsorbents For Water Treatment. Chemical Engineering Transactions. 38:349-354.
  • Nitayaphat, W., Jintakosol, T., Engkaseth, K., and Wanrakakit, Y., (2015). Removal of Methylene Blue from Aqueous Solution by Coffee Residues. Chiang Mai J. Sci. 42:407-416.
  • Orfanos, A., Manariotis, I.D., and Karapanagioti, H.K., (2015). Sorption of Methylene Blue onto Food Industry by Products. Int. Biochar Initiat. Article ID:7046.
  • Kulkarni, M.R., Revanth, T., Acharya, A., and Bhat, P., (2017). Resource-Efficient Technologies. Removal of Crystal Violet Dye from Aqueous Solution Using Water Hyacinth: Equilibrium, Kinetics and Thermodynamics Study. Resource-Efficient Technologies. 3:71-77.
Year 2020, Volume: 15 Issue: 4, 111 - 120, 26.10.2020

Abstract

References

  • Liu, J., Guo, D., Zhou, Y., Wu, Z., Li, W., Zhao, F., and Zheng, X., (2011). Identification of Ancient Textiles from Yingpan, Xinjiang, By Multiple Analytical Techniques. J. Archaeol. Science. 38:1763-1770.
  • Nassar, N.N. and Ringsered A., (2011). Rapid Adsorption of Methylene Blue from Aqueous Solutions by Goethite Nanoadsorbents. Environmental Engineering Science. 29:8.
  • Liu, J., Wang, N., Zhang, H., and Baeyens J., (2019). Adsorption of Congo Red dye on FexCo3-xO4nanoparticles. Journal of Environmental Management. 238:473-483.
  • Khorasani, A.C. and Shojaosadati, S.A., (2019). Magmetic Pectin- Chlorella Vulgarisbiosorbent for the Adsorption of Dyes. Journal of Environmental Chemical Engineering. 7:103062.
  • Siddique, M.R., Farooq, A., Khalid, A., Farooq, Q., Mahmood, U., Farooq, I.A., and Raja Saleem, F.S., (2009). Thermal-pressure-Mediated Hydrolysis of Reactive Blue 19 Dye. J. Hazard Material. 172(2):1007-1012.
  • Chaudhari, A.U., Paul, D., Dhotre, D., and Kodam, K.M., (2017). Effective Biotransformation and Detoxification of Anthraquinone Dye Reactive Blue 4 by Using Aerobic Bacterial Granules. Water Resources. 122:603-613.
  • Gupta, V.K., (2009). Application of Low-cost Adsorbents for Dye Removal – a Review. Journal Environ Management. 90(8):2313-2342.
  • Jamshidi, M., Ghaedi, M., Dashtian, K., Ghaedi, A.M., Hajati, S., Goudarzi, A., and Alipanahpour, E., (2016). Highly Efficient Simultaneous Ultrasonic Assisted Adsorption of Brilliant Green and Eosin B onto ZnS Nanoparticles Loaded Activated Carbon: Artificial Neural Network Modeling and Central Composite Design Optimization. Spectrochim Acta A. 153:257-267.
  • Mosleh, S., Rahimi, M.R., Ghaedi, M., Dashtian, K., and Hajati, S., (2016). Photocatalytic Degradation of Binary Mixture of toxic dyes by HKUST-1 MOF and HKUST-1-SBA-15 in a rotating packed bed reactor under blue LED illumination: central composite design optimization. RSC Adv, 6 (21): 17204-17214.
  • Mosleh, S., Rahimi, M.R., Ghaedi, M., Dashtian, K., Hajati, S., (2016). BiPO4/Bi2S3-HKUST-1-MOF as a Novel Blue Light-Driven Photocatalyst for Simultaneous Degradation of Toluidine Blue and Auramine-O Dyes in a New Rotating Packed Bed Reactor: Optimization And Comparison to a Conventional Reactor. RSC Adv. 6(68):63667-63680.
  • Mosleh, S., Rahimi, M.R., Ghaedi, M., Dashtian, K., Hajati, S., and Wang, S., (2017). Ag3PO4/AgBr/Ag-HKUST-1-MOF Composites as Novel Blue LED Light Active Photocatalyst for Enhanced Degradation of Ternary Mixture of Dyes in a Rotating Packed Bed Reactor. Chem Eng Process. 114:24-38.
  • Mondal, S., (2008). Methods of Dye Removal from Dye House Effluent—An Overview, Environmental Engineering Science. 25:3.
  • Cestari, A.R., Vieira, E.F., Vieira, G.S., Costa, L.P., Tavares, A.M., and Loh W., (2009). The Removal of Reactive Dyes from Aqueous Solutions Using Chemically Modified Mesoporous Silica in the Presence of Anionic Surfactant—The Temperature Dependence and a Thermodynamic Multivariate Analysis. Journal of Hazardous Material. 161(1):307-316.
  • Kallel, F., Bouaziz, F., Chaari, F., Belghith, L., Ghorbel, R., and Chaabouni, S.E., (2016). Interactive Effect of Garlic Straw on the Sorption and Desorption of Direct Red 80 from Aqueous Solution. Process Saf. Environ. Protect. 102:30-43.
  • Ma, Z., Liu, D., Zhu, Y., Li, Z., Li, Z., Tian, H., and Liu H., (2016). Graphene Oxide/chitin Nanofibril Composite Foams as Column Adsorbents for Aqueous Pollutants. Carbohydr. Polym. 144:230-237.
  • Zhou, L., Zhou, H., Hu, Y., Yan, S., and Yang, J., (2019). Adsorption Removal of Cationic Dyes from Aqueous Solutions Using Ceramicadsorbents Prepared from Industrial Waste Coal Gangue. Journal of Environmental Management. 234:245-252.
  • Deniz, F., (2013). Dye Removal by Almond Shell Residues: Studies on Biosorption Performance and Process Design. Mater. Sci. Eng. C. 33(5):2821-2826.
  • Oguntimein, G.B., (2015). Biosorption of Dye from Textile Wastewater Effluent onto Alkali Treated Dried Sunflower Seed Hull and Design of a Batch Adsorber. Journal of Environmental Chemical Engineering. 3(4):2647-2661.
  • Lee, L.Y., Gan, S., Yin, M.S., Tan, S.S., Lim, X.J.L., and Lam, Y.F., (2016). Effective Removal of Acid Blue 113 Dye Using Overripe Cucumis Sativus Peel as an Eco-Friendly Biosorbent from Agricultural Residue. J. Clean. Prod. 113:194-203.
  • Wong, H.H., Tumari, N., Ngadi, N.B., Mohamed, O., Hassan, R., Mat, N.A., and Saidina, A., (2019). Adsorption of Anionic Dyes on Spent Tea Leaves Modified with Polyethyleneimine (PEI-STL). J. Clean. Prod. 206:394-406.
  • Irem, S.Q., Mahmood Khan, E., Islam, A., Jamal Hashmat, M., Anwar ul Haq, M., and Afzal, M.T., (2013). Enhanced Removal of Reactive Navy Blue Dye Using Powdered Orange Waste. Ecol. Eng. 58:399-405.
  • Kwon, E.E., Yi, H., and Jeon, Y.J., (2013). Sequential co-Production of Biodiesel and Bioethanol with Spent Coffee Grounds. Bioresour Technol. 136:475-480.
  • Dai, Y., Zhang, D., and Zhang, K., (2016). Nitrobenzene-Adsorption Capacity of NaOH-modified Spent Coffee Ground from Aqueous Solution. Journal of Taiwan Institute of Chemical Engineering Journal. 68:232-238. https://en.wikipedia.org/wiki/Methylene_blue, Availabre: 20.03.2019.
  • Baek, M.H., Ijagbemi, C.O., Se-Jin, O., and Kim, D.S., (2010) Removal of Malachite Green from Aqueous Solution Using Degreased Coffee Bean. Journal of Hazardous Materials. 176:820–828.
  • Aksu, Z. and Donmez, G., (2003). A comparative Study on the Biosorption Characteristicsof Some Yeasts for Remazol Blue Reactive Dye. Chemosphere. 50(8):1075-1083.
  • Lou T., Yan, X., and Wang X., (2019). Chitosan Coated Polyacrylonitrile Nanofibrous Mat for dye Adsorption. International Journal of Biological Macromolecules. 135:919-925.
  • Gamoudi, S. and Srasra, E., (2019). Adsorption of Organic Dyes by HDPyþ-modified Clay: Effect of Molecular Structure on the Adsorption. Journal of Molecular Structure. 1193:522-531.
  • Magdy, Y.H. and Altaher, H., (2018). Kinetic Analysis of the Adsorption of Dyes from High Strength Wastewater Oncement Kiln Dust. Journal of Environmental Chemical Engineering. 6:834-841.
  • Zuorro, A., Lavecchia, R., and Natali, S., (2014). Magnetically Modified Agro-industrial Wastes as Efficient and Easily Recoverable Adsorbents For Water Treatment. Chemical Engineering Transactions. 38:349-354.
  • Nitayaphat, W., Jintakosol, T., Engkaseth, K., and Wanrakakit, Y., (2015). Removal of Methylene Blue from Aqueous Solution by Coffee Residues. Chiang Mai J. Sci. 42:407-416.
  • Orfanos, A., Manariotis, I.D., and Karapanagioti, H.K., (2015). Sorption of Methylene Blue onto Food Industry by Products. Int. Biochar Initiat. Article ID:7046.
  • Kulkarni, M.R., Revanth, T., Acharya, A., and Bhat, P., (2017). Resource-Efficient Technologies. Removal of Crystal Violet Dye from Aqueous Solution Using Water Hyacinth: Equilibrium, Kinetics and Thermodynamics Study. Resource-Efficient Technologies. 3:71-77.
There are 32 citations in total.

Details

Primary Language English
Journal Section Articles
Authors

Fatma Karadağ

Serpil Savcı 0000-0003-2015-2223

Publication Date October 26, 2020
Published in Issue Year 2020 Volume: 15 Issue: 4

Cite

APA Karadağ, F., & Savcı, S. (2020). Fast Adsorption of Methylene Blue By Filter Coffee Waste. Ecological Life Sciences, 15(4), 111-120.
AMA Karadağ F, Savcı S. Fast Adsorption of Methylene Blue By Filter Coffee Waste. Ecological Life Sciences. October 2020;15(4):111-120.
Chicago Karadağ, Fatma, and Serpil Savcı. “Fast Adsorption of Methylene Blue By Filter Coffee Waste”. Ecological Life Sciences 15, no. 4 (October 2020): 111-20.
EndNote Karadağ F, Savcı S (October 1, 2020) Fast Adsorption of Methylene Blue By Filter Coffee Waste. Ecological Life Sciences 15 4 111–120.
IEEE F. Karadağ and S. Savcı, “Fast Adsorption of Methylene Blue By Filter Coffee Waste”, Ecological Life Sciences, vol. 15, no. 4, pp. 111–120, 2020.
ISNAD Karadağ, Fatma - Savcı, Serpil. “Fast Adsorption of Methylene Blue By Filter Coffee Waste”. Ecological Life Sciences 15/4 (October 2020), 111-120.
JAMA Karadağ F, Savcı S. Fast Adsorption of Methylene Blue By Filter Coffee Waste. Ecological Life Sciences. 2020;15:111–120.
MLA Karadağ, Fatma and Serpil Savcı. “Fast Adsorption of Methylene Blue By Filter Coffee Waste”. Ecological Life Sciences, vol. 15, no. 4, 2020, pp. 111-20.
Vancouver Karadağ F, Savcı S. Fast Adsorption of Methylene Blue By Filter Coffee Waste. Ecological Life Sciences. 2020;15(4):111-20.