Influence of ion-plasma fibers treatment and silica nanoparticles on porous structure of Polikon anion-exchange membranes

封面

如何引用文章

全文:

开放存取 开放存取
受限制的访问 ##reader.subscriptionAccessGranted##
受限制的访问 订阅或者付费存取

详细

The physicochemical properties and characteristics of the porous structure of “Polikon A” composite anion-exchange membranes, obtained by the method of polycondensation filling of polyester fiber, are studied. It is established that the total porosity, the specific surface area and specific moisture capacity of “Polikon A” composite membranes are comparable with these characteristics for the “Polikon K” membranes and are significantly higher than for the heterogeneous ion-exchange MA-40 membrane. It is found that the method of preparing silica nanoparticles, as well as preliminary ion-plasma treatment of fibers, significantly influence on the porous structure of the Polikon A membranes based on lavsan.

全文:

受限制的访问

作者简介

D. Terin

Yuri Gagarin State Technical University of Saratov; Saratov State University

Email: shkirskaya@mail.ru
俄罗斯联邦, Politekhnicheskaya st., 77, Saratov, 410054; Astrakhanskaya st., 83, Saratov, 410012

М. Kardash

Yuri Gagarin State Technical University of Saratov

Email: shkirskaya@mail.ru
俄罗斯联邦, Politekhnicheskaya st., 77, Saratov, 410054

N. Kononenko

Kuban State University

Email: shkirskaya@mail.ru
俄罗斯联邦, Stavropolskaya st., 149, Krasnodar, 350040

S. Shkirskaya

Kuban State University

编辑信件的主要联系方式.
Email: shkirskaya@mail.ru
俄罗斯联邦, Stavropolskaya st., 149, Krasnodar, 350040

Yu. Volfkovich

Frumkin Institute of Physical Chemistry and Electrochemistry Russian Academy of Sciences

Email: shkirskaya@mail.ru
俄罗斯联邦, Leninsky Prospekt, 31, building 4, Moscow, 119071

V. Sosenkin

Frumkin Institute of Physical Chemistry and Electrochemistry Russian Academy of Sciences

Email: shkirskaya@mail.ru
俄罗斯联邦, Leninsky Prospekt, 31, building 4, Moscow, 119071

参考

  1. Strathmann H. // Desalination. 2010. V. 264. № 3. P. 268.
  2. Valero F., Arbós R. // Desalination. 2010. V. 253. № 1–3. P. 170.
  3. Ge L., Wu B., Yu D., Mondal A.N., Hou L., Afsar N.U., Li Q., Xu T., Miao J., Xu T. // Chinese J. Chem. Eng. 2017. V. 25. № 11. P. 1606.
  4. Gurreri L., Tamburini A., Cipollina A., Micale G. // Membranes (Basel). 2020. V. 10. № 7. P. 146.
  5. Al-Amshawee S., Yunus M.Y.B.M., Azoddein A.A.M., Hassell D.G., Dakhil I.H., Hasan H.A. // Chem. Eng. J. 2020. Vol. 380. P. 122231.
  6. Campione A., Gurreri L., Ciofalo M., Micale G., Tamburini A., Cipollina A. // Desalination. 2018. V. 434. P. 121.
  7. Meng J., Shi Х., Wang S., Hu Z., Koseoglu-Imer D.Y., Lens P.N.L., Zhan X. // J. Water Process Engineering. 2024. V. 65. P. 105855.
  8. Merkel A., Vavro M., Čopák L., Dvořák L., Ahrné L., Ruchti C. // Membranes. 2022. V. 13. P. 29.
  9. Faucher M., Serre É., Langevin M.-È., Mikhaylin S., Lutin F., Bazinet L. // J. Memb. Sci. 2018. V. 555. P. 105.
  10. Geoffroy T.R., Bernier M.E., Thibodeau J., Francezon N., Beaulieu L., Mikhaylin S., Langevin M.E., Lutin F., Bazinet L. // J. Memb. Sci. 2022. V. 641. P. 119856.
  11. Мембраны и мембранные технологии / Отв. ред. А.Б. Ярославцев. М.: Научный мир, 2013. 612 с.
  12. Sata T. Ion Exchange Membranes: Preparation, Characterization, Modification and Application. The Royal Society of Chemistry, Gateshead, 2004. 314 p.
  13. Apel P.Yu., Bobreshova O.V., Volkov A.V., Volkov V.V., Nikonenko V.V., Stenina I.A., Filippov A.N., Yampolskii Yu.P., Yaroslavtsev A.B. // Membranes and Membrane Technologies. 2019. V. 1. № 2. P. 45.
  14. Meng J., Shi L., Hu Y., Wang Z., Hu Z., Zhan X. // Bioresour. Technol. 2024. V. 402. P. 130770.
  15. Апель П.Ю., Велизаров С., Волков А.В., Елисеева Т.В., Никоненко В.В., Паршина А.В., Письменская Н.Д., Попов К.И., Ярославцев А.Б. // Мембраны и мембранные технологии. 2022. Т. 12. № 2. С. 81.
  16. Bokhary A., Tikka A., Leitch M., Liao B. // J. Membr. Sci. Res. 2018. V. 4. P. 181.
  17. Apel P.Yu., Biesheuvel P.M., Bobreshova O.V., Borisov I.L., Vasil’eva V.I., Volkov V.V., Grushevenko E.A., Nikonenko V.V., Parshina A.V., Pismenskaya N.D., Ryzhkov I.I., Sharafan M.V., Yaroslavtsev A.B. // Membranes and Membrane Technologies. 2024. V. 6. № 3. P. 133.
  18. Кардаш М.М., Терин Д.В. // Мембраны и мембранные технологии. 2016. Т. 6. № 2. С. 152.
  19. Кардаш М.М., Кононенко Н.А., Фоменко М.А., Тюрин И.А., Айнетдинов Д.В. // Мембраны и мембранные технологии. 2016. Т. 6. № 1. С. 41.
  20. Tyurin I.A., Kardash M.M., Terin D.V. // Sci. Research and Innovation. 2020. № 1. P. 31.
  21. Rouquerol J., Baron G., Denoyel R., et al. // Pure and Applied Chem. 2012. V. 84. № 1. P. 107.
  22. Kononenko N., Nikonenko V., Grande D., Larchet C., Dammak L., Fomenko M., Volfkovich Yu. // Adv. Colloid and Interface Sci. 2017. V. 246. P. 196.
  23. Кардаш М.М., Вольфкович Ю.М., Тюрин И.А., Кононенко Н.А., Олейник Д.В., Черняева М.А. // Мембраны и мембранные технологии. 2013. Т. 3. № 1. С. 50.
  24. Демина О.А., Березина Н.П., Сата Т., Демин А.В. // Электрохимия. 2002. Т. 38. № 8. С. 1002.
  25. Kardash M.M., Terin D.V., Druzhinina T.V. // Fibre Chemistry. 2019. V. 51. № 4. P. 227.
  26. Кардаш М.М., Тураев Т.А., Тюрин И.А., Терин Д.В. // Химические волокна. 2024. № 4. С. 21.
  27. Terin D., Kardash M., Ainetdinov D., Turaev T., Sinev I. // Membranes. 2023. V. 13. № 8. P. 742.
  28. Купцов А.Х., Жижин Г.Н. Фурье-спектры комбинационного рассеяния и инфракрасного поглощения полимеров. М.: Физматлит, 2001. 656 с.
  29. Swierenga H., de Weijer A.P., Buydens L.M.C. // Jour. Chemometrics. 1999. V. 13. № 3–4. P. 237.
  30. Zhu C., Tong N., Song L., Zhang G. // Int. Symposium on Photonics and Optoelectronics. 2015. P. 96560E (1–5).
  31. Ellis G., Román F., Marco C., Gómez M., Fatou J. // Spectrochimica Acta Part A. 1995. V. 51. P. 2139.
  32. Strilets I.D., Kardash M.M., Terin D.V., Druzhinina T.V., Tsyplyayev S.V. // Membranes and Membrane Technologies. 2020. V. 2. № 5. P. 325.
  33. Grabowski A., Zhang G., Strathmann H., Eigenberger G. // Sep. Purif. Technol. 2008. V. 60. P. 86.
  34. Jordan M.L., Valentino L., Nazyrynbekova N., Palakkal V.M., Kole S., Bhattacharya D., Lin Y.J., Arges C.G. // Mol. Syst. Des. Eng. 2020. V. 5. P. 922.
  35. Park S., Kwak R. // Water Res. 2020. V. 170. P. 115310.

补充文件

附件文件
动作
1. JATS XML
下载
2. Fig. 1. Integral (a, b) and differential (c, d) curves of water distribution by binding energies and effective pore radii in “Polycon A” membranes. The curve numbers in the figure correspond to the serial number of the sample in Table 1.

下载 (400KB)
索引源数据
3. Fig. 2. Integral (a) and differential (b) curves of the distribution of the surface of meso- and macropores by pore radii in “Polycon A” membranes. The curve numbers in the figure correspond to the serial number of the sample in Table 1.

下载 (189KB)
索引源数据
4. Fig. 3. Raman spectrum of polyester fibers of the “Lavsan” fabric before and after ion-plasma treatment.

下载 (99KB)
索引源数据
5. Fig. 4. Specific electrical conductivity of the “Polycon A” and MA-40 membranes in 0.1 M NaCl solution. The column numbers in the figure correspond to the serial number of the sample in Table 1.

下载 (217KB)
索引源数据

版权所有 © Russian Academy of Sciences, 2025