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Tytuł artykułu

Comparison of Copper and Cobalt Ions Sorption from Aqueous Solutions on Selected Sorbents

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Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
In this paper, the sorption capacity of Norit SX2 activated carbon, ground rice husks and C‑160 ion exchange resin in relation to the Cu2+ and Co2+ ions was compared. The studied sorption processes were described using the Langmuir adsorption model. The C‑160 ion exchange resin was characterized by the highest affinity for both Cu2+ and Co2+ ions. It was shown that rice husk and active carbon are efficient sorbents in diluted solutions. The copper recovery for activated carbon, ion exchanger and rice husk was high. The efficiency of this process was 98.1%; 92.3% and 88.9%, respectively. Reducing the volume of acid used for regeneration allowed the solution to be concentrated and facilitated element recovery. Regeneration for cobalt occurred to a lesser extent.
Słowa kluczowe
Rocznik
Strony
84--90
Opis fizyczny
Bibliogr. 23 poz., rys., tab.
Twórcy
  • AGH University of Science and Technology, Faculty of Mining and Geoengineering, al. Mickiewicza 30, 30-059 Krakow, Poland
  • AGH University of Science and Technology, Faculty of Mining and Geoengineering, al. Mickiewicza 30, 30-059 Krakow, Poland
  • AGH University of Science and Technology, Faculty of Mining and Geoengineering, al. Mickiewicza 30, 30-059 Krakow, Poland
Bibliografia
  • 1. Ahmad A.L., Ooi B.S. 2010. A study on acid reclamation and copper recovery using low pressure nanofiltration membrane. Chemical Engineering Journal, 156, 257–263.
  • 2. Al Moharbi S.S., Devi M.G., Sangeetha B.M., Jahan S. 2020. Studies on the removal of copper ions from industrial effluent by Azadirachta indica powder. Applied Water Science, 10 (23), 1–10.
  • 3. Al‑Saydeh S.A., El‑Naasa M.H., Zaidib S.J. 2017. Copper removal from industrial wastewater: A comprehensive review. Journal of Industrial and Engineering Chemistry, 56, 35–44.
  • 4. Bansal R.C., Goyal M. 2009. Adsorption on activated carbon. Scientific Publishers WNT, Warsaw (in Polish).
  • 5. Bielański A. 2020. Basics of inorganic chemistry. Scientific Publishers PWN, Warsaw (in Polish).
  • 6. Bożęcka A., Sanak‑Rydlewska S. 2018. The use of ion exchangers for removing cobalt and nickel ions from water solutions. Archives of Mining Sciences, 63(3), 633–646.
  • 7. Bożęcka A., Surdek A., Bożęcki P. 2018. Assessment of suitability of selected sorbents for removal of Co2+ ions from aqueous solutions. Przemysl Chemiczny, 97(9), 1565–1568 (in Polish).
  • 8. Dil E.A., Ghaedi M., Ghezelbash G.R., Asfaram A., Purkait M.K. 2017. Highly efficient simultaneous biosorption of Hg2+, Pb2+ and Cu2+ by Live yeast Yarrowia lipolytica 70562 following response surface methodology optimization: Kinetic and isotherm study. Journal of Industrial and Engineering Chemistry, 48, 162–172.
  • 9. Duru, C.E., Duru, I.A., Ogbonna, C.E., Enedoh, M.C., Emele, P. 2019. Adsorption of copper ions from aqueous solution onto natural and pretreated maize husk: adsorption efficiency and kinetic studies. Journal of Chemical Society of Nigeria, 44(5), 798–803.
  • 10. Edebali S., Pehlivan E. 2016. Evaluation of chelate and cation exchange resins to remove copper ions. Powder Technology, 301, 520–525.
  • 11. Jack F., Bostock J., Tito D., Harrison B., Brosnan J. 2014. Electrocoagulation for the removal of copper from distillery waste streams. Journal of the Institute of Brewing, 120, 60–64.
  • 12. Catalog card Purolite C‑160 http://www.purolite.com/product/c160, 10.07.2020.
  • 13. Kołodyńska D., Krukowska‑Ba J., Kazmierczak‑Razna J., Pietrzak R. 2017. Uptake of heavy metal ions from aqueous solutions by sorbents obtained from the spent ion exchange resins. Microporous and Mesoporous Materials, 244, 127–136.
  • 14. Kovacova Z., Demcak S., Balintova M. 2019. Removal of copper, zinc and iron from water solutions by spruce sawdust adsorption. Economics and Environment, 3, 64–74.
  • 15. Li J., Wang X., Wang H., Wang S., Hayat T., Alsaedi A., Wang X. 2017. Functionalization of biomass carbonaceous aerogels and their application as electrode materials for electro‑enhanced recovery of metal ions. Environmental Science: Nano, 4, 1114–1123.
  • 16. Lundström M., Liipo J, Taskinen P., Aromaa J. 2016. Copper precipitation during leaching of various copper sulfide concentrates with cupric chloride in acidic solutions. Hydrometallurgy, 166, 136–142.
  • 17. Nischitha, S. Y., Karpagam, J., Parimala, C. 2017. Adsorption studies on copper removal from industrial sludge. International Journal of Engineering Research and Modern Education, Special Issue, 167–170.
  • 18. Ogórek M., Gąsior Ł, Pierzchała O., Daszkiewicz R., Lenartowicz M. 2017. Role of copper in the process of spermatogenesis. Postepy Higieny i Medycyny Doswiadczalnej, 71, 662–680 (in Polish).
  • 19. Prakash N., Arungalai Vendan S. 2016. Biodegradable polymer based ternary blends for removal of trace metals from simulated industrial wastewater. International Journal of Biological Macromolecules, 83, 198–208.
  • 20. Seńczuk W. red. 2017. Contemporary toxicology, Medical Publisher PZWL, Warsaw (in Polish).
  • 21. Shahamirifard S.A.R., Ghaedi M., Rahimi M.R., Hajati S., Montazerozohori M., Soylak M. 2016. Simultaneous extraction and preconcentration of Cu2+, Ni2+ and Zn2+ ions using Ag nanoparticle‑loaded activated carbon: Response surface methodology. Advanced Powder Technology, 27, 426–435.
  • 22. Singh S.A., Shukla S.R. 2016. Adsorptive removal of cobalt ions on raw and alkali‑treated lemon peels. International Journal of Environmental Science And Technology, 13, 165–178.
  • 23. Tran A.T.K., Zhang Y., Jullok N., Meesschaert B., Pinoy L., Van der Bruggen B. 2012. RO concentrate treatment by a hybrid system consisting of a pellet reactor and electrodialysis. Chemical Engineering Science, 79, 228–238.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-efa90768-1061-4cee-8d61-32d4a134309c
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