Preview

Proceedings of the Kabardino-Balkarian State University

Advanced search

STRUCTURAL MODEL OF THE COMBUSTION PROCESS OF POLYMER/CARBON NANOTUBE NANOCOMPOSITES

https://doi.org/10.31143/2221-7789-2025-4-10-13

EDN: YLXKWW

Abstract

A structural model is considered that allows us to determine the dependence of the fire resis- tance of polymer/carbon nanotube nanocomposites on a fundamental structural characteristic – the Hurst ex- ponent. This characteristic demonstrates the decisive influence of the structural state of the nanocomposite, expressed by the structural state of carbon nanotube aggregates, on the combustion process of these nanomate- rials. The Hurst exponent is easily controlled by varying the carbon nanotube content.

About the Authors

I. I. Dolbin
Russian State University of Tourism and Service
Russian Federation


I. V. Dolbin
Kh.M Berbekova Kabardino-Balkarian State University
Russian Federation


Vad. A. Kvashin
Kh.M Berbekova Kabardino-Balkarian State University
Russian Federation


U. D. Chavdar
Kh.M Berbekova Kabardino-Balkarian State University
Russian Federation


References

1. Karmanov A.P., Matveyev D.V., Monakov Yu.B. Dynamics of Polymerization of Monomeric Precursors of Guaiacyl Lignins // Reports of the Academy of Sciences. 2001. Vol. 380, No. 5. Pp. 635–638.

2. Atlukhanova L.B., Kozlov G.V. Fractal Dynamics of Cross-Linking of Epoxy Polymers in the Presence of Carbon Nanotubes // Dynamics of Complex Systems – 21st Century. 2019. V. 13, No. 1. Pp. 13–16.

3. Dolbin I.V., Kozlov G.V., Mikitaev A.K. Structural model of fire resistance of polymer-organoglina nanocomposites // High Temperature Thermophysics. 2015. V. 53, No. 4. Pp. 585–588.

4. Kozlov G.V., Dolbin I.V., Karnet Yu.N., Vlasov A.N., Dolbin I.I. Modeling of carbon nanotubes (nanofibers) as macromolecular tussles – the model of a freely articulated chain // Mechanics of Composite Materials and Structures. 2025. Vol. 31, No. 1. Pp. 74–81.

5. Dolbin I.I., Kumysheva Yu.A., Kazancheva L.A., Dolbin I.V., Davydova V.V. Proportionality of the Content of Nanofiller and Interfacial Regions in Polymer Nanocomposites // Izvestiya of Kabardino-Balkarian State University.

6. Feder E. Fractals. M.: Mir, 1991. 256 p.

7. Kozlov G.V., Dolbin I.V., Magomedov Gus.M. Regularities of the Aggregation of 2D-Nanoparticle in Polymer Nanocomposites // Physics and Chemistry of Glass. 2023. Vol. 49, No. 4. Pp. 471–476.

8. Jeong W., Kessler M.P. Toughness enhancement in ROMP functionalized carbon nano- tube/polydicyclopentadiene composites // Chem. Mater. 2008. V. 20, N 22. P. 7060–7068.

9. Zeleny L.M., Milovanov A.V. Fractal Topology and Strange Kinetics: From Percolation Theory to Problems of Space Electrodynamics // Advances in Physical Sciences. 2004. V. 174, N 8. P. 809–842.

10. Kozlov G.V., Zaikov G.E., Mikitaev A.K. Fractal Analysis of Gas Transfer in Polymers. Theory and Practical Applications. Moscow: Nauka, 2009. 199 p.


Review

For citations:


Dolbin I.I., Dolbin I.V., Kvashin V.A., Chavdar U.D. STRUCTURAL MODEL OF THE COMBUSTION PROCESS OF POLYMER/CARBON NANOTUBE NANOCOMPOSITES. Proceedings of the Kabardino-Balkarian State University. 2025;15(4):10-13. https://doi.org/10.31143/2221-7789-2025-4-10-13. EDN: YLXKWW

Views: 80

JATS XML


Creative Commons License
This work is licensed under a Creative Commons Attribution 4.0 License.


ISSN 2221-7789 (Print)