Amphiphilic properties of 2-(acrylamido)dodecanesulfonic acid and its water-soluble copolymers with alkoxyoligo(ethylene glycol)methacrylates

The surface-active properties (in aqueous solutions and water-hexane mixtures) of the amphiphilic sulfo-containing macromonomer 2-(acrylamido)dodecanesulfonic acid (AAС₁₂SА) were studied; copolymers of this surfomer with oligo(ethylene glycol)methacrylates were synthesized. Тhe effect of the content of sulfonic units in the obtained molecular brushes on their thermosensitive properties in water and water-salt solutions was determined.

1. Badi, N. Non-linear PEG-based thermoresponsive polymer systems / N. Badi // Prog. Polym. Sci. – 2017. – Vol. 66. – P. 54–79. 2. Liu, M. Conformation-function relationships for the comb-shaped polymer pOEGMA / M. Liu, J.C. Leroux, M.A. Gauthier // Prog. Polym. Sci. –2015. – Vol. 48. – P. 111–121.

2. Orekhov, D.V. Molecular brushes based on copolymers of alkoxy oligo(ethylene glycol) methacrylates and dodecyl(meth) acrylate: features of synthesis by conventional free radical polymerization / D.V. Orekhov, D.M. Kamorin, A.S. Simagin // Polymer Bulletin. – 2021. – Vol. 78. – P. 5833–5850.

3. Sivokhin, A.Р. Amphiphilic thermoresponsive copolymer bottlebrushes: synthesis, characterization, and study of their selfassembly into flower-like micelles / A.Р. Sivokhin, D.V. Orekhov, O.A. Kazantsev et al. // Polymer Journal. – 2021. – Vol. 53. – Р. 655–665.

4. Lutz, J.-F. Thermo-Switchable Materials Prepared Using the OEGMA-Platform / J.-F. Lutz // Adv. Mater. – 2011. – Vol. 23, N19. – P. 2237–2243.

5. Matsumoto, M. Self-assembly of amphiphilic block pendant polymers as microphase separation materials and folded flower micelles / M. Matsumoto, M. Takenaka, M. Sawamoto, T. Terashima // Polym. Chem. – 2019. – Vol. 10. – P. 4954–4961.

6. Sun, L. Synthesis of polymeric micelles with dual-functional sheddable PEG stealth for enhanced tumor-targeted drug delivery / L. Sun, H. Wei, X.S. Zhang et al. // Polym. Chem. – 2020. – Vol. 11. – P. 4469–4476.

7. Cho, H.Y. Synthesis of Poly(OEOMA) Using Macromonomers via “Grafting-Through” ATRP / H.Y. Cho, P. Krys, K. Szczesniak et al. // Macromolecules. – 2015. – Vol. 48, N18. – P. 6385–6395.

8. Ильгач, Д.М. Использование методов контролируемой радикальной полимеризации для синтеза полимерных щеток / Д.М. Ильгач, Т.К. Мелешко, А.В. Якиманский // Высокомолекулярные соединения. Серия C. – 2015. – Т. 57, №1. – С. 6–24.

9. Pelras, T. Synthesis and applications of compartmentalised molecular polymer brushes / T. Pelras, C.S. Mahon, M. Mullner // Angewandte Chemie International Edition. – 2018. – Vol. 57, N 24. – P. 6982–6994.

10. Orekhov, D.V. Assembly of oligo(ethylene glycol)- and amine-containing methacrylic esters in water and water-hexane mixtures / D.V. Orekhov, D.M. Kamorin, M. Rumyantsev et al. // Colloids and Surfaces A: Physicochemical and Engineering Aspects. – 2015. – Vol. 481. – P. 20–30.

11. Орехов, Д.В. Амфифильные свойства алкоксиолигоэтиленгликольметакрилатов и сополимеров на их основе / Д.В. Орехов, К.В. Ширшин, М.В. Савинова и др. // Пластические массы. – 2019. – №7-8. – С. 38–41. 13. Goh, E. Cross-Linked Poly(methacrylic acid-co-poly(ethylene oxide) methyl ether methacrylate) Microspheres and Microgels Prepared by Precipitation Polymerization: A Morphology Study / E. Goh, H. Stöver // Macromolecules. – 2002. – Vol. 35, N 27. – P. 9983–9989.

12. Куренков В.Ф. Полиакриламидные флокулянты // Соровский образовательный журнал. – 1997. – №7. – С. 55–63.

13. Куренков, А.В. Седиментация суспензии каолина сополимерами 2-акриламидо-2-метилпропансульфоната натрия с акрилатом натрия / А.В. Куренков, В.Ф. Куренков, Ф.И. Лобанов // Журнал прикладной химии. – 2009. – Т. 82, №11. – С. 1894–1898.

14. Bouhamed, H. Alumina interaction with AMPS–MPEG copolymers produced by RAFT polymerization: Stability and rheological behavior / H. Bouhamed, S. Boufi, A. Magnin // Journal of Colloid and Interface Science. – 2009. – Vol. 333, N1. – P. 209–220.

15. Erzengin, S. G. Applications of sulfonate-carboxylate copolymers in cement / S.G. Erzengin, A. Bodur, S.P. Ozkorucuklu et al. // Advances in Cement Research. – 2016. – Vol. 28, N 10. – P. 630–642.

16. Xue, J. The Development and Application of the Acrylamide Kind Polymers for Tertiary Oil Recovery in China / J. Xue, D. Guo, Q. Hou // International Journal of Petroleum Technology. – 2018. – Vol. 5. – P. 19–29.

17. Якимцова, Л.Б. Термическая устойчивость сополимеров метакриламида и 2-акриламидо-2-метилпропансульфоната натрия / Л.Б. Якимцова, П.А. Никишев, А.П. Бочко // Полимерные материалы и технологии. – 2020. – Т. 6, №3. – С. 60–65.

18. Chen, L. Experimental study of calcium-enhancing terpolymer hydrogel for improved oil recovery in ultrodeep carbonate reservoir / L. Chen, X. Zhu, M. Fu et al. // Colloids and Surfaces A: Physicochemical and Engineering Aspects. – 2019. – Vol. 570. – P. 251–259.

19. Cai, S. Molecular interaction of poly (acrylamide‐co‐2‐acrylamido‐ dodecyl sulfonate) with dual responsiveness and application in oily emulsion wastewater / S. Cai, Y. Wang, X. He // Journal of Applied Polymer Science. – 2021. – Vol. 139, N 4. – P. 51528.

20. Sun, J. Synthesis and evaluation of a novel hydrophobically associating polymer based on acrylamide for enhanced oil recovery / J. Sun, W. Du, X. Pu et al. // Chemical Papers. – 2015. – Vol. 69, N12. – P. 1598–1607.

21. Wu, X. Self-assembly of a series of random copolymers bearing amphiphilic side chains / X. Wu, Y. Qiao, H. Yang, J. Wang // Journal of Colloid and Interface Science. – 2010. – Vol. 349, N2. – P. 560–564.