Extraction of Copper Ions with Composite Sorbents Based on Chitosan from Aqueous Solutions of Electrolytes in the Presence of a Surfactant
- Authors: Gabrin V.A.1, Nikiforova T.E.1
-
Affiliations:
- Ivanovo State University of Chemical Technology
- Issue: Vol 59, No 4 (2023)
- Pages: 364-372
- Section: ФИЗИКО-ХИМИЧЕСКИЕ ПРОЦЕССЫ НА МЕЖФАЗНЫХ ГРАНИЦАХ
- URL: https://journals.rcsi.science/0044-1856/article/view/139712
- DOI: https://doi.org/10.31857/S0044185623700535
- EDN: https://elibrary.ru/YBUBMS
- ID: 139712
Cite item
Abstract
The results of studying the sorption of copper(II) ions by composite sorbents based on chitosan and mineral reinforcing fillers from aqueous solutions of electrolytes and solutions containing dodecyldimethylamine-N-oxide are presented. It is shown that the composite sorbents “chitosan–glauconite” and “chitosan–zeolite” are characterized by a larger increase in the sorption capacity for Cu(II) ions in solutions containing surfactants than the composites “chitosan–silicon dioxide” and “chitosan–montmorillonite.” The adsorption characteristics of the composite sorbents were compared with those of the initial hydrogel chitosan sorbent. IR spectra, diffraction patterns, and micrographs of the surface of the samples were obtained.
Keywords
About the authors
V. A. Gabrin
Ivanovo State University of Chemical Technology
Email: gabrinvictoria@gmail.com
153000, Ivanovo, Russia
T. E. Nikiforova
Ivanovo State University of Chemical Technology
Author for correspondence.
Email: tatianaenik@mail.ru
153000, Ivanovo, Russia
References
- Rehman M., Liu L., Wang Q. et al. // Environmental Science and Pollution Research. 2019. V. 26. P. 18003–18016.
- Na Y., Lee J., Lee S.H. et al. // Polymer-Plastics Technology and Materials. 2020. V. 59. P. 1768545.
- Saheed I.O., Oh W.Da, Suah F.B.M. // J. Hazardous Materials 2021. V. 408. P. 124889.
- Fufaeva V.A., Filippov D.V. // Chem. Chem. Tech. 2021. V. 64 (5). https://doi.org/10.6060/IVKKT.20216405.6354
- Shayegan H., Ali G.A.M., Safarifard V. // Chemistry Select. 2020. V. 5. P. 04107.
- Zamora-Ledezma C. // Environ. Technol. Innov. 2021. V. 22. P. 101504.
- Shrestha R. // J. Environmental Chemical Engineering. 2021. V. 9. P. 105688.
- Krishnan S. // Environmental Technology & Innovation. 2021. V. 22. P. 101525.
- Rathi B.S., Kumar P.S., Vo D.V.N. // Science of the Total Environment. 2021. P. 797. P. 149134.
- Kostag M., El Seoud O.A. // Carbohydrate Polymer Technologies and Applications. 2021. V. 2. P. 100079.
- Mishra J., Saini R., Singh D. // IOP Conference Series: Materials Science and Engineering. 2021. V. 1168. P. 012027.
- Tang S. // Chemical Engineering J. 2020. V. 393. P. 124728.
- Qiao L., Li S., Li Y. et al. // J. Cleaner Production. 2020. V. 253. P. 120017.
- Pap S. // Environmental Science and Pollution Research. 2020. V. 27. P. 9790–9802.
- Filippov D.V., Fufaeva V.A., Shepelev M.V. // Russian J. Inorganic Chemistry. 2022. https://doi.org/10.1134/S0036023622030081
- Wang F., Sun Y., Guo X. et al. // J. Sol-Gel Science and Technology. 2020. V. 96. P. 360–369.
- Upadhyay U., Sreedhar I., Singh S.A. et al. // Carbohydrate Polymers. 2021. V. 251. P. 117000.
- Fan X., Wang X., Cai Y. et al. // J. Hazardous Materials. 2022. V. 423. P. 127191.
- Kayan G.Ö., Kayan A. // J. Polymers and the Environment. 2021. V. 29. P. 3477–3496.
- Kusrini E. // International J. Technology. 2021. V. 12. P. 275–286.
- Lin Z., Yang Y., Liang Z. et al. // Polymers. 2021. V. 13. P. 1891.
- Fufaeva V.A., Nikiforova T.E. // Protection of Metals and Physical Chemistry of Surfaces. 2022. V. 58. P. 262–268.
Supplementary files
![](/img/style/loading.gif)