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RAS Chemistry & Material ScienceРадиохимия Radiochemistry

  • ISSN (Print) 0033-8311
  • ISSN (Online) 3034-5693

Interference of Strontium and Yttrium Cations and Surfactants in Competitive Adsorption onto Activated Carbon: A Radioatracer Study

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PII
S30345693S0033831125020052-1
DOI
10.7868/S3034569325020052
Publication type
Article
Status
Published
Authors
M.G. Chernysheva
  • Affiliation: Department of Chemistry, Moscow State University
O.A. Kangina
  • Affiliation: Department of Chemistry, Moscow State University
E.Ya. Spivak
  • Affiliation: Department of Chemistry, Moscow State University
A.V. Gopin
  • Affiliation: Department of Chemistry, Moscow State University
Г. А. Бадун
  • Affiliation: Department of Chemistry, Moscow State University
Volume/ Edition
Volume 67 / Issue number 2
Pages
143-149
Abstract
The interference of Sr(II) and Y(III) cations with cationic, anionic, and nonionic surfactants during competitive adsorption on lignin-produced activated carbon was studied. Dodecyltrimethylammonium bromide, sodium dodecylsulfate, and decaethylene glycol monododecyl ether (Brij-35) were used as surfactants. The radiotracers Sr/Y and tritium were used to trace the equilibrium concentration of metal cations and the surface concentrations of the surfactants, respectively. Tritium-labeled surfactants were obtained using the tritium thermal activation technique. Liquid scintillation spectrometry was used to determine the concentration of all substances. The SpectraDec software was used for joint measurement of Sr/Y and tritium radioactivity. It was shown that the presence of a surfactant affects the adsorption of strontium and yttrium onto activated carbon produced by thermochemical activation with orthophosphoric acid. The formation of a low-solubility precipitate with an anionic surfactant increased the adsorption of both cations, reduced their desorption, and promoted the sorption of the anionic surfactant itself. The nonionic surfactant (containing oxyethyl groups) did not affect the adsorption of strontium and yttrium cations but helped retain them on the carbon surface, preventing desorption. The cationic surfactant competed with strontium and yttrium cations for active sites on the activated carbon surface: adsorption of all components decreased, while desorption of cations increased.
Keywords
стронций иттрий радиоактивные индикаторы активированный уголь адсорбция поверхностно-активные вещества
Date of publication
08.04.2025
Year of publication
2025
Number of purchasers
0
Views
16

References

  1. 1. Ioannidis I., Pashalidis I., Mulla B., Kotanidis G., Ioannou K., Constantinides G. et al. // Materials. 2023. Vol. 16. Article 7479.
  2. 2. Lu S., Sun Y., Chen C. Adsorption of radionuclides on carbon-based nanomaterials // Interface Sci. Technol. Elsevier, 2019. P. 141–215.
  3. 3. Lobacheva O., Dzhevaga N., Danilov A. // J. Ecol. Eng. 2016. Vol. 17. P. 38–42.
  4. 4. Chakraborty A., Pal A., Saha B.B. // Materials. 2022. Vol. 15. Article 8818.
  5. 5. Куницын С.А., Горбунова М.И., Красавина Е.И., Румянцев Н.А. // Радиохимия. 2019. T. 61. C. 18–26.
  6. 6. Данилин Л.Д., Дроздецкий В.С. // Радиохимия. 2007. T. 49. C. 283–286.
  7. 7. Süss M., Pfrepper G. // Radiochim. Acta. 1981. Vol. 29. P. 33–40.
  8. 8. Mestre A.S., Pires J., Nogueira J.M.F., Parra J.B., Carvalho A.P., Ania C.O. // Bioresource Technol. 2009. Vol. 100. P. 1720–1726.
  9. 9. Лишай Н.В., Савицкая Т.А., Цыганкова Н.Г., Гришина Л.Д., Чен Д. // Ж. Белорус. гос. ун-та. Химия. 2021. Т. 1. С. 58–74.
  10. 10. Liu C., Su Z., Xu L., Zhang L., Xie T., Wang Y. // Chin. J. Geochem. 2013. Vol. 32. P. 269–272.
  11. 11. Mahmoud M.R., El-Deen G.E.S., Soliman M.A. // Ann. Nucl. Energy. 2014. Vol. 72. P. 134–144.
  12. 12. Абрамзон А.А. Поверхностно-активные вещества: Свойства и применение. Л.: Химия, 1981. 304 с.
  13. 13. Бадун Г.А., Чернышева М.Г. // Радиохимия. 2023. Т. 65. С. 158–171.
  14. 14. Капелла О.А., Чернышева М.Г., Бадун Г.А., Лишай А.В., Цыганкова Н.Г., Савицкая Т.А., Гришина Л.Д. // Коллоид. журн. 2024. Т. 86. № 1. С. 37–41.
  15. 15. Савицкая Т.А., Невар Т.Н., Цыганкова Н.Г., Кривова М.Г., Резинков И.В., Шахно А.Е., Везещее А.И., Гришина Л.Д. // Свиридовские чтения: Сб. статей. Минск: БГУ, 2015. Вып. 11. С. 132–143.
  16. 16. Badun G.A., Chernysheva M.G., Ksenofontov A.L. // Radiochim. Acta. 2012. Vol. 100. P. 401–408.
  17. 17. Чернышева М.Г. Новый подход к определению структурных особенностей комплексов белок–лиганд на межфазных границах и в объеме раствора (на примере лизоцима): Дис. ... д.х.н. М.: МГУ им. М.В. Ломоносова, 2022. 193 с.
  18. 18. Zhang U., Xing Y., Xia Y., Guo F., Ding S., Tan J. et al. // ACS Omega. 2020. Vol. 5. P. 20630–20637.
  19. 19. Hu Q., Zhang Z. // J. Mol. Liq. 2019. Vol. 277. P. 646–648.
  20. 20. Nguyen C., Do D.D. // Carbon. 2001. Vol. 39. P. 1327–1336.
  21. 21. Schott H. // J. Colloid Interface Sci. 1997. Vol. 192. P. 458–462.
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