Influence of Ion-plasma treatment of reinforcing fillers on the complex of PCM properties

This paper presents the results of studying samples of glass-carbon plastics based on reinforcing fillers subjected to ion-plasma treatment. The influence of the speed of surface treatment on the complex of physical and mechanical characteristics of glass-fiber-reinforced plastics is shown. According to the results of microstructural studies, it was found that ion-plasma treatment promotes an increase in interfacial interaction at the fiber-matrix interface. The effect of ion-plasma treatment of reinforcing fillers on the properties of PCM samples in a moisture-saturated state is shown.

1. Kablov, E.N., Startsev, O.V., Panin, S.V., Vlagoperenos v ugleplastike s destruktirovannoy poverkhnostiyu [Moisture transfer in CFRP with a destructed surface], Reports of the Academy of Sciences, 2015, V. 461, No 4, pp. 433–436.

2. Kablov, E.N., Valueva, M.I., Zelenina, I.V., Khmelnitsky, V.V., Aleksashin, V.M., Ugleplastiki na osnove benzoksazinovykh oligomerov – perspektivnye materialy [Carbon plastics based on benzoxazine oligomers, promising materials], Trudy VIAM, 2020, No 1 (85), pp. 68–77. URL: http://www.viam-works.ru (reference date: 22/11/2021). DOI: 10.18577/2307/-6046-2020-0-1-68-77.

3. Kablov, E.N., Rol fundamentalnykh issledovaniy pri sozdanii materialov novogo pokoleniya Mendeleevskogo siezda po obshchey i prikladnoy khimii [The role of fundamental research in the creation of new generation materials], Proceedings of 21st Mendeleev Congress on General and Applied Chemistry, St Petersburg, 2019, V. 4, p. 24.

4. Kolpachkov, E.D., Marakhovsky, P.S., Petrova, A.P., Shchur, P.A., Lonsky, S.L. , Chernyaeva, I.Yu., Shvedov, A.V., Issledovanie vliyaniya ionno-plazmennoy obrabotki na svoystva poverkhnosti armiruyushchikh napolniteley [Investigation of the effect of ion-plasma treatment on the properties of the surface of reinforcing fillers], Voprosy Materialovedeniya, 2021, No 3 (107), pp. 136–149.

5. Tikhomirov, A.S., Sorokina, N.E., Avdeev, V.V., Modifitsirovanie poverkhnosti uglerodnogo volokna rastvorami azotnoy kisloty [Surface modification of carbon fiber with nitric acid solutions], Neorganicheskie materialy, 2011, V. 47, No 6, pp. 684–688.

6. Li, J., Sun, F.F., The effect of nitric acid oxidization treatment on the interface of carbon fiberreinforced thermoplastic polystyrene composite, Polym.-Plast. Technol. and Eng., 2009, V. 48. No 7, pp. 711–715.

7. Vazquez-Santos, M.B., Suarez-Garcia, F., Activated Carbon fibers with a high heteroatom content by chemical activation of PBO with phosphoric acid, Langmuir, 2012, No 13, pp. 5850–5860.

8. Fu, R., Liu, L., Huang, W., Studies on the structure of activated carbon fibers activated by phosphoric acid, J. Appl. Polym. Sci., 2003, V. 87, pp. 2253–2261.

9. Pradhan, B.K., Sandle N.K., Effect of different oxidizing agent treatments on the surface properties of activated carbons, Carbon, 1999, V. 37, pp. 1323–1332.

10. Suarez-Garcia, F., Castro-Muniz, A., Tascon, J.M.D., Activated carbon fibers with a high content of surface functional groups by phosphoric acid activation of PPTA, Journal of Colloid and Interface Science, 2011, V. 361, pp. 307–315.