Charge activity of silicon-containing nanophase particles intended for modification of polymer matrices

  • 1 Yanka Kupala Grodno State University – Grodno, Belarus
  • 2 NST Group – Tel Aviv, Israel


The article considers the influence of various technological methods for obtaining nanosized silicate-containing particles. Each of the methods has its advantages and disadvantages, none of them is universal. It is shown that, depending on the methods of formation of particles, their activity changes. Silicon carbide particles obtained as a result of the thermolysis process with preliminary chemical treatment from natural raw materials of organic origin are of interest for further research. These particles have an increased charge activity in relation to other studied classes of charged particles.



  1. Gul V. E., Akutin M. S. Fundamentals of plastics processing. Moscow: Chemistry; 1985. 356 p.
  2. Sarde B, Patil YD. Recent research status on polymer composite used in concretean overview. Mater Today: Proc 2019; 18(37):80– 90.
  3. Valino AD, Dizon JRC, Espera AH, Chen Q, Messman J, Advincula RC. Advances in 3D printing of thermoplastic polymer composites and nanocomposites. Prog Polym Sci 2019; 98:101-162.
  4. Abdul Khalil HPS, Fizree HM, Bhat AH, Jawaid M, Abdullah CK. Development and characterization of epoxy nanocomposites based on nano-structured oil palm ash. Compos B Eng 2013; 53:324–33.
  5. Hsissou R, Bekhta A, Dagdag O, El Bachiri A, Rafik M, Elharfi A. Rheological properties of composite polymers and hybrid nanocomposites. Heliyon 2020; 6:183-187.
  6. Zindani D, Kumar K. An insight into additive manufacturing of fiber reinforced polymer composite. Int J Lightweight Mater Manuf; 2019; 2:267–278.
  7. Rbaa M, Benhiba F, Hssisou R, Lakhrissi Y, Lakhrissi B, Touhami ME, et al. Green synthesis of novel carbohydrate polymer chitosan oligosaccharide grafted on dglucose derivative as bio-based corrosion inhibitor. J Mol Liq; 2021; 322:114-149.
  8. Ahmadijokani F, Shojaei A, Dordanihaghighi S, Jafarpour E, Mohammadi S, Arjmand M. Effects of hybrid carbon-aramid fiber on performance of nonasbestos organic brake friction composites. Wear 2020.
  9. Hsissou R, Benhiba F, Abbout S, Dagdag O, Benkhaya S, Berisha A, et al. Trifunctional epoxy polymer as corrosion inhibition material for carbon steel in 1.0 M HCl: MD simulations, DFT and complexation computations. Inorg Chem Commun; 2020; 115:107-118.
  10. Gorokhovsky G. A. Surface dispersion of dynamically contacting polymers and metals. Kiev: Naukova dumka; 1972. 152 p.
  11. Casale, L., Porter R. Reactions of plymers under stress. Leningrad: Chemistry; 1983. 440 p.
  12. Heinicke G. Tribochemistry. Moscow: Mir; 1987. 583 p.
  13. Li Yadong, Qiang Kegang, Ma Yizhu, Sun Lei, Wu Zhishen, Huagong xuebao=J. Chem. Ind. and Eng. China; 2008; 59(10): 2650-2655.
  14. Hoffman I.V., Svetlichny V.M., Yudin V.E., Journal of General Chemistry; 2007; 77(7):1075-1080.
  15. Mei-li Jiang, Plasma Science and Technology; 2004; 5:34-38.
  16. Magerramov A.M., Ramazanov M.A., Gadzhieva F.V. Influence of electrothermopolarization and discharge treatment on the charge state, strength and photoluminescent properties of nanocompositions based on polypropylene and cadmium sulfide. Electronic processing of materials; 2010; 46(5):120-123.
  17. Eisymont E.I. Thermoplastic composites with increased parameters of operational characteristics obtained by directed energy effects. Minsk: Yanka Kupala Grodno State University; 2015. 23 p.
  18. Rempel A.A. Nanotechnology, properties and application of nanostructured materials. Advances in chemistry; 2007; 76(5):474- 500.
  19. Bhakta P., Barthunia B. Fullerene and its applications: A review. Journal of Indian Academy of Oral Medicine and Radiology; 2020; 32(2). 159 p.
  20. Wang X. [et al.] Enhanced protective coatings based on nanoparticle fullerene C60 for oil & gas pipeline corrosion mitigation. Nanomaterials; 2019; 9(10). 1476 p.
  21. Chang, J., Zhang, Q., Lin, Y., Zhou, C., Yang, W., Yan, L., & Wu, G. Carbon nanotubes grown on graphite films as effective interface enhancement for an aluminum matrix laminated composite in thermal management applications. ACS applied materials & interfaces; 2018; 10(44):38350-38358.
  22. Li, Y., Wang, S., Wang, Q. Enhancement of tribological properties of polymer composites reinforced by functionalized grapheme. Composites Part B: Engineering; 2017; 120:83-91.
  23. Mahmoudi, T., Wang Y., Hahn Y. B. Graphene and its derivatives for solar cells application. Nano Energy; 2018; 47:51- 65.
  24. Vozniakovskii, A. A., Voznyakovskii, A. P., Kidalov, S. V., Osipov, V. Y. Structure and paramagnetic properties of graphene nanoplatelets prepared from biopolymers using self-propagating high-temperature synthesis. Journal of Structural Chemistry; 2020; 61(5):826-834.

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