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Batch and Column Studies on Nickle and Cadmium Removal Using Iranian Clay-based Geopolymer | ||
| Pollution | ||
| دوره 7، شماره 2، تیر 2021، صفحه 341-354 اصل مقاله (883.99 K) | ||
| نوع مقاله: Original Research Paper | ||
| شناسه دیجیتال (DOI): 10.22059/poll.2021.310600.905 | ||
| نویسندگان | ||
| Somayeh Bakhtiari* ؛ Asma Zeidabadinejad؛ Hanieh Abbaslou؛ Alireza Ghanizadeh | ||
| Department of Civil Engineering, Sirjan University of Technology, Sirjan, Iran | ||
| چکیده | ||
| The production rate of industrial and agricultural waste is increasing due to population growth. Soil is the most important receiver of industrial and agricultural waste. Contaminants such as heavy metals in various waste after reception by the soil, immediately become part of the cycle that has different impacts on the environment. Geopolymer, as a chemical stabilizer has the potential to stabilize heavy metals in the soil. In this research, several geopolymers for the stabilization of heavy metals in soil were synthesized. Silicon dioxide (SiO2) and aluminosilicate (Al2SiO4) must be used to produce the geopolymers. Rice husk ash was used as the SiO2 source. Also, Iranian zeolite and sepiolite, and red clay soil were utilized as the source of Al2SiO4. The synthesized geopolymers were investigated for the adsorption of nickel and cadmium. Also, batch and column studies of using geopolymers for the chemical stabilization of heavy metals in soil were conducted. The results revealed a high adsorption capacity of the geopolymers. The zeolite, sepiolite, and red clay geopolymer-soil samples adsorbed 100% of the heavy metals (i.e., Ni and Cd) at a concentration of 100 ppm. The zeolite geopolymer adsorbent adsorbed 57% and 96% of Ni and Cd at a concentration of 1000 ppm, respectively. In general, it was concluded that the use of geopolymer compounds in soils with high heavy metal adsorption capacity could be an efficient approach to prevent groundwater resource pollution. | ||
| کلیدواژهها | ||
| heavy metals؛ leaching؛ adsorption؛ zeolite؛ sepiolite | ||
| مراجع | ||
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Aljeboreea, A. M, Alshirifib, A.N, Ayad F. and Alkaim A.F. (2017). Kinetics and equilibrium study for the adsorption of textile dyes on coconut shell activated carbon, Arabian J. Chem., 10; S3381-S33393. Andrejkovičová S., Sudagar, A., Rocha, J., Patinha, C., Hajjaji, W., da Silva, E. F., Velosa, A. and Rocha, F. (2016). The effect of natural zeolite on microstructure. mechanical and heavy metals adsorption properties of metakaolin based geopolymers. Appl. Clay. Sci., 126; 141-152. Araujo, C. S., Almeida, I. L., Rezende, H. C., Marcionilio, S. M., Léon, J. J. and de Matos, T. N. (2018). Elucidation of mechanism involved in adsorption of Pb (II) onto lobeira fruit (Solanum lycocarpum) using Langmuir, Freundlich and Temkin isotherms. Micro chem. J., 137; 348-354. Ayawei, N., Ebelegi, A.N. and Wankasi, D. (2017). Modelling and Interpretation of Adsorption Isotherms J. Chem., Article ID 3039817. Bai, C., and Colombo, P. (2018). Processing, properties and applications of highly porous geopolymers; A review. Ceramics. Int., 44(14); 16103-16118. Bohli, T., Villaescusa, I., and Ouederni, A. (2013). Comparative Study of Bivalent Cationic Metals Adsorption Pb(II), Cd(II), Ni(II) and Cu(II) on Olive Stones Chemically Activated Carbon. J. Chem. Eng. Proc. Tech., 4(4);1-7. Borna, M. O., Pirsaheb. M., Niri, M. V., Mashizie, R .K., Kakavandi, B., Zare, M. R. and Asadi, A. (2016). Batch and column studies for the adsorption of chromium (VI) on low-cost Hibiscus Cannabinus kenaf, a green adsorbent. J. Taiwan. Inst. Chem. Eng., 68; 80-89. Ciosek, A. L and Luk, G. K. (2017). An Innovative Dual-Column System for Heavy Metallic Ion Sorption by Natural Zeolite. Appl Sci., 7(8); 795. Cristelo, N., Glendinning, S., Miranda. T., Oliveira, D. and Silva, R. (2012). Soil stabilisation using alkaline activation of fly ash for self compacting rammed earth construction. Const. Build. Mater., 36; 727-735. Dawood, S., Sen, T.K. and Phan, C. (2018). Performance and dynamic modelling of biocharand kaolin packed bed adsorption column foraqueous phase methylene blue (MB) dye removal, Env. Tech., Accepted manuscript. Desta, M. B. (2013). Batch sorption experiments: Langmuir and Freundlich isotherm studies for the adsorption of textile metal ions onto teff straw (Eragrostis tef) agricultural waste. J. Therm., Article ID 375830. Ding, Y. C., Cheng, T .W. and Dai, Y. S. (2017). Application of geopolymer paste for concrete repair. Struct.Concrete., 18(4); 561-570. Duxson, P., Fernández-Jiménez, A., Provis, J. L., Lukey, G.C., Palomo, A. and van Deventer, J.S.J. (2007). Geopolymer technology: the current state of the art. J. Mater. Sci., 42(9); 2917-2933. El-Eswed, B. I., Yousef. R.I, Alshaaer, M., Hamadneh, I., Al-Gharabli, S.I. and Khalili, F. (2017). Stabilization/solidification of heavy metals in kaolin/zeolite based geopolymers. International J. Min Process., 137; 34-42. El-Eswed, B.I., Aldagag, O.M. and Khalili, F. I. (2017). Efficiency and mechanism of stabilization/solidification of Pb(II), Cd(II), Cu(II), Th(IV) and U(VI) in metakaolin based geopolymers. Appl. Clay Sci., 140; 148-156. He. J., Jie, Y., Zhang, J., Yu, Y. and Zhang, G. (2013). Synthesis and characterization of red mud and rice husk ash-based geopolymer composites. Cement. Conc. Comp., 37; 108-118. Pollution 2021, 7(2): 341-354 353 Kalavathy, M .H., Karthikeyan, T., Rajgopal, S. and Miranda, L. R. (2005). Kinetic and isotherm studies of Cu (II) adsorption onto H3PO4-activated rubber wood sawdust. J. Colloid. Interf. Sci., 292(2); 354-362. Kara, L., Yilmazer, D. and Akar, S. T. (2017). Metakaolin based geopolymer as an effective adsorbent for adsorption ofzinc(II) and nickel(II) ions from aqueous solutions. Appl. Clay Sci., 139; 54–63. Kara, I., Tunc, D., Sayin, F. and Akar, S. T. (2018), Study on the performance of metakaolin based geopolymer for Mn(II) and Co(II) removal. Appl. Clay Sci., 161; 184-193. Li, J. and Poon, C. S. (2017). Innovative solidification/stabilization of lead contaminated soil using incineration sewage sludge ash. Chemosphere., 173; 143-152. Liang, Y., Cao, X., Zhao, L. and Arellano, E. (2014). Biochar- and phosphate-induced immobilization of heavymetals in contaminated soil and water: implicationon simultaneous remediation of contaminated soil and groundwater. Environ. Sci. Pollut. Res., 21; 4665–4674. Lirer, S., Liguori, B., Capasso, I., Flora, A. and Caputo, D. (2017). Mechanical and chemical properties of composite materials made of dredged sediments in a fly-ash based geopolymer. J. Env. Manag., 191; 1-7. Maghchiche, A., Haouam, A. and Immirzi, B. (2010). Use of polymers and biopolymers for water retaining and soil stabilization in arid and semiarid regions. Journal of Taibah University for science., 4(1); 9-16. Majeed, M.R. (2017), Removal efficiency of heavy metals from aqueous solutions by albedo of pomelo fruit. Current Res. Micro. Biotech., 5(6);1336-1344 Nguyen, H. T., Pham, V.T.H. Dang, T. P. and Dao, T.K., (2018) Leachability of heavy metals in geopolymer-based materials synthesized from red mud and rice husk ash. AIP Conference Proceedings, AIP Publishing. Park, C.K. (2000). Hydration and solidification of hazardous wastes containing heavy metalsusing modified cementitious materials, Cement. Conc. Res., 30; 429 – 435. Phair, J.W. and Van Deventer, J.S.J. (2001). Effect of silicate activator pH on the leaching and material characteristics of waste-based inorganic polymers. Miner. Eng., 14(3); 289-304. Podder, M. and Majumder, C. (2016). Fixed-bed column study for As (III) and As (V) removal and recovery by bacterial cells immobilized on sawdust/MnFe2O4 composite. Biochem. Eng. J., 105; 114-135. Stabnikov, V., Chu, J., Myo, A.N. and Ivanov, V. (2013) Immobilization of sand dust and associated pollutants using bioaggregation. Water. Air. Soil Poll., 224(9); 1631. Sun, S., Lin, J., Zhang, P., Fang, L., Ma, R., Quan, Z. and Song, X. (2018). Geopolymer synthetized from sludge residue pretreated by the wet alkalinizing method: Compressive strength and immobilization efficiency of heavy metal. Cons. Build. Mater., 170; 619-626. Swain, K. (2015). Stabilization of soil using geopolymer and biopolymer. A Thesis Submitted in Partial Fulfilment of the Requirements for the Degree of Master of Technology (Research) In Civil Engineering (Geotechnical engineering). Department of Civil engineering national institute of technology, Rourkela. Tchakoute, H.K., Rüscher, C.H., Kong, S., Kamseu, E. and Leonelli, C. (2016), Geopolymer binders from metakaolin using sodium waterglass from waste glass and rice husk ash as alternative activators: A comparative study. Cons. Build. Mater., 114; 276-289. Ulloa, N.A., Baykara, H., Cornejo, M.H., Rigail, A., Paredes, C. and Villalba, J.L. (2018). Application-oriented mix design optimization and characterization of zeolite-based geopolymer mortars. Cons. Build. Mater., 174; 138-149. Verdolotti, L., Iannace, S., Lavorgna, M. and Lamanna, R. (2008). Geopolymerization reaction to consolidate incoherent pozzolanic soil. J. Mater. Sci., 43(3); 865-873. Vu, T.H. and Gowripalan, N. (2018). Mechanisms of Heavy Metal Immobilisation using Geopolymerisation Techniques–A review. J. Adv. Con. Tech., 16(3); 124-135. 354 Bakhtiari et al. Zhang, M., Zhao, M., Zhang, G., Nowak, P., Coen, A. and Tao, M. (2015). Calcium-free geopolymer as a stabilizer for sulfate-rich soils. Appl. Clay. Sci., 108; 199-207. Zhang, C., Luo, Q., Geng, C. and Li, Z. (2010). Stabilization treatment of contaminated soil: afield-scaleapplication in Shanghai, China .Front. Environ. Sci. Engin. China., 4(4); 395–404. Zwolak, A., Sarzyńska, M., Szpyrka, E. and Stawarczyk, K. (2019). Sources of Soil Pollution by Heavy Metals and TheirAccumulation in Vegetables: a Review. Water. Air. Soil. Poll., 230; 164. | ||
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