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Removal of Iron from Aqueous Solution by using Typha australis Leaves as Low Cost Adsorbent | ||
Pollution | ||
دوره 8، شماره 2، تیر 2022، صفحه 397-406 اصل مقاله (762.69 K) | ||
نوع مقاله: Original Research Paper | ||
شناسه دیجیتال (DOI): 10.22059/poll.2021.324884.1107 | ||
نویسندگان | ||
Fatimetou Mohamed N’Dah1؛ Mohamed Sid’Ahmed Kankou1؛ Mohamed Abdallahi Bollahi2؛ Abdoulaye Demba N’diaye* 1 | ||
1Unité de Recherche Eau, Pollution et Environnement, Département de Chimie, Faculté des Sciences et Technique, Université de Nouakchott Al Aasriya, BP 880, Nouakchott, Mauritanie | ||
2Laboratoire de Chimie, Service de Toxicologie et de Contrôle de Qualité, Institut National de Recherches en Santé Publique, BP 695, Nouakchott, Mauritanie | ||
چکیده | ||
Iron removal from aqueous solution via ultrasound-assisted adsorption using Typha australis leaves as low cost adsorbent had been studied. The effects of various experimental parameters like mass of the Typha australis adsorbent and contact time have been investigated using a batch experiment. The adsorption kinetic data were analyzed using the Pseudo First Order (PFO) and Pseudo Second Order (PSO) models. The adsorption modeling was carried out using the Langmuir, Freundlich and Redlich-Peterson adsorption models. For kinetic study, the adsorption process fitted the PSO model and agreed with chemisorption. Both the Langmuir and Redlich–Peterson models were found to fit the adsorption isotherm data well, but the Redlich– Peterson model was better. The maximum adsorption capacity from the Langmuir model (qmax) was 0.84 mg/g. The results of the present work showed that the Typha australis leaf, without any treatment has a good potential for iron removal from aqueous solutions via ultrasound-assisted adsorption. | ||
کلیدواژهها | ||
ultrasound-assisted adsorption؛ nonlinear method؛ kinetics؛ isotherms | ||
مراجع | ||
Adekola, F.A., Hodonou, D.S.S. and Adegoke, H.I. (2016). Thermodynamic and kinetic studies of biosorption of iron and manganese from aqueous medium using rice husk ash. Appl Water Sci, 6:319–330.
Almasian, A., Giahi, M., Chizari Fard, G., Dehdast, S. A. and Maleknia, L. (2018). Removal of heavy metal ions by modified PAN/PANI-nylon core-shell nanofibers membrane: Filtration performance, antifouling and regeneration behavior. Chemical Engineering Journal, 351, 1166–1178.
Barrera-Díaz C., Colín-Cruz A., Ureña-Nuñez F., Romero-Romo M. and Palomar-Pardavé M. (2010). Cr (VI) Removal from Wastewater Using Low Cost Sorbent Materials: Roots of Typha Latifolia and Ashes; Environmental Technology; 25, 8.Freundlich, H.M.F.(1959). Over the adsorption in solution, J. Phys. Chem; 63, 1024-1036.
Gopi Kiran, M., Pakshirajan, K. and Das, G. (2017). A new application of anaerobic rotating biological contactor reactor for heavy metal removal under sulfate reducing condition. Chemical Engineering Journal, 321, 67–75.
Ho, Y.S. (2006). Review of second-order models for adsorption systems. J. Hazard. Mater. B., 136, 681–689.
Inglezakisa, V.J.; Doulab, M.K.; Aggelatou, V. and Zorpas, A.A. (2010). Removal of iron and manganese from underground water by use of natural minerals in batch mode treatment. Desalin. Water Treat., 18, 341–346.
Islam, M.S., M.K. Ahmed, M. Raknuzzaman, M. Habibullah -Al- Mamun, Islam M.K. (2015). Heavy metal pollution in surface water and sediment: a preliminary assessment of an urban river in a developing country, Ecol. Indicat. 48, 282–291.
Izadi, A., Mohebbi, A., Amiri, M. and Izadi, N. (2017). Removal of iron ions from industrial copper raffinate and electrowinning electrolyte solutions by chemical precipitation and ion exchange. Minerals Engineering, 113, 23–35.
Kwakye-Awuah, B., Sefa-Ntiri, B., Von-Kiti, E., Nkrumah, I. and Williams, C. (2019). Adsorptive Removal of Iron and Manganese from Groundwater Samples in Ghana by Zeolite Y Synthesized from Bauxite and Kaolin. Water, 11, 1912.
Langmuir, I.J.(1918). The adsorption of gases on planes surfaces of glass, mica and platinum. J. Am. Chem. Soc.40, 1361-1403.
Martín-Domínguez, A., Rivera-Huerta, M. L., Pérez-Castrejón, S., Garrido-Hoyos, S. E., Villegas-Mendoza, I. E., Gelover-Santiago, S. L., … and Buelna, G. (2018). Chromium removal from drinking water by redox-assisted coagulation: Chemical versus electrocoagulation. Separation and Purification Technology, 200, 266–272.
Miller, J.L. (2013). Iron deficiency anemia: a common and curable disease, Cold Spring Harbor Perspectives in Medicine 3 (7).
Moradi, E, Rahimi, R. and Safarifard, V. (2019). Sonochemically synthesized microporous metal– organic framework representing unique selectivity for detection of Fe3+ ions, Polyhedron, 159, 251–258.
Nagel-Hassemer, M.E., Lapolli, F. R. and Recio, M.N.L. (2013). Simultaneous adsorption of iron and manganese from aqueous solutions employing an adsorbent coal, Environmental Technology, 34:2, 275-282.
Nair, V., Panigrahy, A. and Vinu, R. (2014). Development of novel chitosan- lignincomposites for adsorption of dyes and metal ions from wastewater. Chem. Eng.J. 254, 491–502.
N’diaye, A.D., Aoulad El Hadj Ali, Y., Bollahi, M.A., Stitou, M., Kankou M.S.A. and Fahmi D. (2020a). Adsorption of Methylene Blue from aqueous solution using Senegal River Typha australis. Mediteranean Journal of Chemisty, 10 (1), 22-32.
N’diaye, A.D., Aoulad El Hadj Ali Y., El Moustapha Abdallahi, O., Bollahi, M.A., Stitou, M., Kankou, M., Fahmi, D. (2020b). Sorption of Malachite Green from aqueous solution using Typha australis leaves as a low cost sorbent. Journal of Environmental Treatment Techniques, 8, 3, 1023-1028.
Redlich, O. and Peterson, D.L.(1959). A Useful Adsorption Isotherm; J. Phys. Chem. 63, 6, 1024.
Rosa, M. A., Egido, J. A. and Márquez, M. C. (2017). Enhanced electrochemical removal of arsenic and heavy metals from mine tailings. Journal of the Taiwan Institute of Chemical Engineers, 78, 409–415.
Sukrampal, Kumar, R. and Patil, S.A. (2020). Removal of heavy metals using bioelectrochemical systems. Integrated Microbial Fuel Cells for Wastewater Treatment, 49–71.
Tian, J., Chang, H., Gao, S. and Zhang, R. (2020). How to fabricate a negatively charged NF membrane for heavy metal removal via the interfacial polymerization between PIP and TMC? Desalination, 491, 114499.
Wang, L., Wang, Y., Cui, L., Gao, J., Guo, Y. and Cheng, F. (2020). Sustainable approaches for advanced removal of iron from CFA sulfuric acid leach liquor by solvent extraction with P507. Separation and Purification Technology, 251, 117371.
Zare-Dorabei, R, Ferdowsi, S.M, Barzin, A. and Tadjarodi, A. (2016). Highly efficient simultaneous ultrasonic-assisted adsorption of Pb (II), Cd (II), Ni (II) and Cu (II) ions from aqueous solutions by graphene oxide modified with 2, 2′-dipyridylamine: central composite design optimization, Ultrason. Sonochem., 32, 265–276.
Zhang, Y., Wang, Y., Zhang, H., Li, Y., Zhang, Z. and Zhang, W. (2020). Recycling spent lithium-ion battery as adsorbents to remove aqueous heavy metals: Adsorption kinetics, isotherms, and regeneration assessment. Resources, Conservation and Recycling, 156, 104688. | ||
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