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Optimization of ultrasonic-assisted copper ion removal from polluted water by a natural clinoptilolite nanostructure through a central composite design

Published online by Cambridge University Press:  23 September 2019

Mohsen Sheydaei Open the ORCID record for Mohsen Sheydaei [Opens in a new window] ,
Ali Balanejad Gasemsoltanlu  and
Asadollah Beiraghi
Mohsen Sheydaei*
Affiliation:
Faculty of Chemistry, Kharazmi University, 15719-14911Tehran, Iran
Ali Balanejad Gasemsoltanlu
Affiliation:
Faculty of Chemistry, Kharazmi University, 15719-14911Tehran, Iran
Asadollah Beiraghi
Affiliation:
Faculty of Chemistry, Kharazmi University, 15719-14911Tehran, Iran
*
*Email: mohsen_sheydaei@khu.ac.ir
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Abstract

A natural clinoptilolite nanostructure (CNS) along with ultrasonic irradiation was used to remove Cu2+ ions from polluted water. In the first part of this work, natural clinoptilolite was converted to CNS by ball milling. The natural clinoptilolite and prepared CNS samples were characterized by scanning electron microscopy (SEM), energy-dispersive X-ray spectroscopy, Fourier-transform infrared (FTIR) spectroscopy, X-ray diffraction, N2 adsorption/desorption and pH at the point of zero charge analyses. The SEM images showed the development of CNS from natural clinoptilolite by ball milling. The N2 adsorption/desorption and FTIR spectroscopy confirmed the greater specific surface area, pore volume and number of surface groups of the CNS compared to the natural clinoptilolite. In addition, the crystalline phase of the CNS was the same as the natural clinoptilolite. In the second part of this work, the ultrasonic-assisted sorption of Cu2+ ions from polluted water by CNS was investigated. These experiments were optimized with response surface methodology based on central composite designs. The effects of initial pH of solution, CNS dosage, sonication time and temperature on Cu2+ ion-removal efficiency were investigated. By using a CNS dosage of 500 mg L−1, an initial pH of 6, a sonication time of 12 min and a sonication temperature of 45°C as optimal conditions, 97% of Cu2+ ions were removed from contaminated water. The initial pH was the most effective variable. Ultrasonic-assisted sorption of Cu2+ was more effective than sorption alone, onto the CNS.

Keywords

central composite designcopper removalnatural clinoptilolite nanostructuresorptionultrasonic
Type
Article
Information
Clay Minerals , Volume 54 , Issue 4 , December 2019 , pp. 339 - 347
Copyright
Copyright© Mineralogical Society of Great Britain and Ireland 2019

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Footnotes

Guest Associate Editor: A. Dakovic

References

Abbar, B., Alem, A., Marcotte, S., Pantet, A., Ahfir, N.-D., Bizet, L. & Duriatti, D. (2017) Experimental investigation on removal of heavy metals (Cu2+, Pb2+, and Zn2+) from aqueous solution by flax fibres. Process Safety and Environmental Protection, 109, 639647.CrossRefGoogle Scholar
Aber, S., Ayoubi-Feiz, B. & Salari, D. (2013) Investigation of isothermal and fixed-bed column sorption of Cu(II) onto almond shell. Environmental Engineering and Management Journal, 12, 435441.CrossRefGoogle Scholar
Aber, S., Salari, D. & Ayoubi Feiz, B. (2011) The sorption of copper on almond shell: optimization and kinetics. Water Science & Technology, 63, 13891395.CrossRefGoogle ScholarPubMed
Adamczyk, J., Horny, N., Tricoteaux, A., Jouan, P.Y. & Zadam, M. (2008) On the use of response surface methodology to predict and interpret the preferred c-axis orientation of sputtered AlN thin films. Applied Surface Science, 254, 17441750.CrossRefGoogle Scholar
Al-Makhadmeh, L. & Batiha, M.A. (2016) Removal of iron and copper from aqueous solutions using Jordanian kaolin and zeolitic tuff. Desalination and Water Treatment, 57, 2093020943.Google Scholar
Bourliva, A., Michailidis, K., Sikalidis, C., Filippidis, A. & Betsiou, M. (2013) Lead removal from aqueous solutions by natural Greek bentonites. Clay Minerals, 48, 771787.CrossRefGoogle Scholar
Bourliva, A., Sikalidis, A.K., Papadopoulou, L., Betsiou, M., Michailidis, K., Sikalidis, C. & Filippidis, A. (2018) Removal of Cu2+ and Ni2+ ions from aqueous solutions by adsorption onto natural palygorskite and vermiculite. Clay Minerals, 53, 115.CrossRefGoogle Scholar
Dindarsafa, M., Khataee, A., Kaymak, B., Vahid, B., Karimi, A. & Rahmani, A. (2017) Heterogeneous sono-Fenton-like process using martite nanocatalyst prepared by high energy planetary ball milling for treatment of a textile dye. Ultrasonics Sonochemistry, 34, 389399.CrossRefGoogle ScholarPubMed
Dönmez, M., Camcı, S., Akbal, F. & Yağan, M. (2015) Adsorption of copper from aqueous solution onto natural sepiolite: equilibrium, kinetics, thermodynamics, and regeneration studies. Desalination and Water Treatment, 54, 28682882.CrossRefGoogle Scholar
Entezari, M.H. & Soltani, T. (2008) Simultaneous removal of copper and lead ions from a binary solution by sono-sorption process. Journal of Hazardous Materials, 160, 8893.CrossRefGoogle ScholarPubMed
Irannajad, M., Haghighi, H.K. & Safarzadeh, E. (2016) Kinetic, thermodynamic and equilibrium studies on the removal of copper ions from aqueous solutions by natural and modified clinoptilolites. Korean Journal of Chemical Engineering, 33, 16291639.CrossRefGoogle Scholar
Katsimicha, D., Pentari, D., Pantelaki, O. & Komnitsas, K. (2017) Effect of wet milling on the adsorption capacity of a Greek natural zeolite used for the removal of heavy metals from solutions. Bulletin of the Geological Society of Greece, 47, 953962.CrossRefGoogle Scholar
Khataee, A., Kiranşan, M., Karaca, S. & Arefi-Oskoui, S. (2016) Preparation and characterization of NnO/MMT nanocomposite for photocatalytic ozonation of a disperse dye. Turkish Journal of Chemistry, 40, 546564.CrossRefGoogle Scholar
Lin, S., Zhou, T. & Yin, S. (2017) Properties of thermally treated granular montmorillonite–palygorskite adsorbent (GMPA) and use to remove Pb2+ and Cu2+ from aqueous solutions. Clays and Clay Minerals, 65, 184192.CrossRefGoogle Scholar
Mustafai, F.A., Balouch, A., Abdullah, , Jalbani, N., Bhanger, M.I., Jagirani, M.S., Kumar, A. & Tunio, A. (2018) Microwave-assisted synthesis of imprinted polymer for selective removal of arsenic from drinking water by applying Taguchi statistical method. European Polymer Journal, 109, 133142.CrossRefGoogle Scholar
Pang, Y.L. & Abdullah, A.Z. (2013) Fe3+ doped TiO2 nanotubes for combined adsorption–sonocatalytic degradation of real textile wastewater. Applied Catalysis B: Environmental, 129, 473481.CrossRefGoogle Scholar
Pourtaheri, A. & Nezamzadeh-Ejhieh, A. (2015) Photocatalytic properties of incorporated NiO onto clinoptilolite nano-particles in the photodegradation process of aqueous solution of cefixime pharmaceutical capsule. Chemical Engineering Research and Design, 104, 835843.CrossRefGoogle Scholar
Radaideh, J.A., Barjenbruch, M., Patzer, S. & Shatnawi, Z. (2017) Heavy metals removal using natural Jordanian volcanic tuff. GSTF Journal of Engineering Technology (JET), 2, 18.Google Scholar
Sanchez, A.G., Ayuso, E.A. & De Blas, O.J. (1999) Sorption of heavy metals from industrial waste water by low-cost mineral silicates. Clay Minerals, 34, 469477.CrossRefGoogle Scholar
Sani, H.A., Ahmad, M.B., Hussein, M.Z., Ibrahim, N.A., Musa, A. & Saleh, T.A. (2017) Nanocomposite of ZnO with montmorillonite for removal of lead and copper ions from aqueous solutions. Process Safety and Environmental Protection, 109, 97105.CrossRefGoogle Scholar
Sheydaei, M. & Aber, S. (2013) Preparation of nano-lepidocrocite and an investigation of its ability to remove a metal complex dye. CLEAN – Soil, Air, Water, 41, 890898.CrossRefGoogle Scholar
Song, M.-M., Branford-White, C., Nie, H.-L. & Zhu, L.-M. (2011) Optimization of adsorption conditions of BSA on thermosensitive magnetic composite particles using response surface methodology. Colloids and Surfaces B: Biointerfaces, 84, 477483.CrossRefGoogle ScholarPubMed
Sprynskyy, M., Buszewski, B., Terzyk, A.P. & Namiesnik, J. (2006) Study of the selection mechanism of heavy metal (Pb2+, Cu2+, Ni2+, and Cd2+) adsorption on clinoptilolite. Journal of Colloid and Interface Science, 304, 2128.CrossRefGoogle ScholarPubMed
Stojakovic, D., Milenkovic, J., Daneu, N. & Rajic, N. (2011) A study of the removal of copper ions from aqueous solution using clinoptilolite from Serbia. Clays and Clay Minerals, 59, 277285.CrossRefGoogle Scholar
Sun, W., Meng, Q., Jing, L., He, L. & Fu, X. (2014) Synthesis of long-lived photogenerated charge carriers of Si-modified α-Fe2O3 and its enhanced visible photocatalytic activity. Materials Research Bulletin, 49, 331337.CrossRefGoogle Scholar
Wang, H.Y. & Huang, H.F. (2010) Competitive adsorption of lead, copper and zinc ions on polymeric Al/Fe modified clinoptilolite. Advanced Materials Research, 156–157, 900907.CrossRefGoogle Scholar
Wang, M., Liao, L., Zhang, X., Li, Z., Xia, Z. & Cao, W. (2011) Adsorption of low-concentration ammonium onto vermiculite from Hebei Province, China. Clays and Clay Minerals, 59, 459465.CrossRefGoogle Scholar
Wang, Z., Ma, Y., He, H., Pei, C. & He, P. (2015) A novel reusable nanocomposite: FeOOH/CBC and its adsorptive property for methyl orange. Applied Surface Science, 332, 456462.CrossRefGoogle Scholar
Wu, J., Zhang, H., Oturan, N., Wang, Y., Chen, L. & Oturan, M.A. (2012) Application of response surface methodology to the removal of the antibiotic tetracycline by electrochemical process using carbon-felt cathode and DSA (Ti/RuO2–IrO2) anode. Chemosphere, 87, 614620.CrossRefGoogle ScholarPubMed
Xu, L., Cui, H., Zheng, X., Liang, J., Xing, X., Yao, L., Chen, Z. & Zhou, J. (2018) Adsorption of Cu2+ to biomass ash and its modified product. Water Science and Technology, 2017, 115125.CrossRefGoogle Scholar
Zhang, G., Gao, Y., Zhang, Y. & Guo, Y. (2010) Fe2O3-pillared rectorite as an efficient and stable Fenton-like heterogeneous catalyst for photodegradation of organic contaminants. Environmental Science & Technology, 44, 63846389.CrossRefGoogle ScholarPubMed