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BIODEGRADABLE COMPOSITIONS BASED ON POLYOLEFINS AND ELASTOMERS

Abstract

The article identifies an important environmental problem – the ever-increasing amount of waste of synthetic polymeric materials and their harmful effects on the environment. At the same time, according to the authors, at the present time, the most relevant is to impart biodegradability properties to large-tonnage traditional polymers (polyethylene, polypropylene, etc.). The above analysis of literature data shows that the most optimal option for solving this problem and increasing the ability of polymers to degrade and biodegrade is the development of polymer-based composites with the addition of natural components.

About the Authors

I. A. Varyan
G.V. Plekhanov Russian University of Economics
Russian Federation


N. N. Kolesnikova
N.M. Emanuel Institute of Biochemical Physics, Russian Academy of Sciences
Russian Federation


A. A. Popov
G.V. Plekhanov Russian University of Economics
Russian Federation


References

1. Goldfein M.D., Zaikov G.E., Kochnev A.M. Fundamentals of a Modern Strategy for Solving Problems Related to Polymer Pollution of the Earth // Bulletin of Kazan Technological University. 2014. Vol. 17, No. 13. Pp. 234–237.

2. Buchachenko A.L. Nanochemistry – a Direct Path to High Technologies of the New Century. // Advances in Chemistry. 2003. Vol. 72, No. 5. Pp. 419–437.

3. Berezkin I.S., Grubnik A.V. Problems of plastic waste recycling and theoretical justification of creating alternative technologies for plastic recycling // Bulletin of Kherson National Technical University. 2016. No. 2 (57). Pp. 37–41.

4. Long Yu. Biodegradable Polymer Mixtures and Composites from Renewable Sources. St. Petersburg: Scientific Foundations and Technologies Publishing House, 2012. 464 p.

5. Leshina A. Plastics of Biological Origin // Chemistry and Life. 2012. No. 9. Pp. 79–95.

6. Alanis R., Kennedy J. Advances in Polymeric Biomaterials Series: Absorbable and Biodegradable Polymers // Carbohydr. Polym. 2005. V. 62, N 3. P. 301–302.

7. Pekhtasheva E.L., Neverov A.N., Zaikov G.E., Stoyanov O.V. Biodegradation and bioprotection of materials. Who is responsible for it? // Bulletin of Kazan Technological University. 2012. Vol. 15, No. 8. Pp. 222–233.

8. Sakaeva E.Kh., Mekhonoshina A.V. Research of Biodegradation of Polymer Materials Waste // Transport. Transport Facilities. Ecology. 2017. No. 1. Pp. 97–105.

9. Krutko E.T., Prokopchuk N.R., Globa A.I. Technology of Biodegradable Polymer Materials. Minsk: BGTU Publishing House, 2014. 105 p.

10. Anisimov A.A., Smirnov V.F., Veselov A.P. Microorganisms damage polymers // On the edge of chemistry and biology. Moscow: Znanie, 1982. 64 p.

11. Kotova I. B., Taktarova Yu. V., Tsavkelova E. A., Egorova M. A. Microbial degradation of plastic and ways to intensify it // Microbiology. 2021. Vol. 90, No. 6. Pp. 627–659.

12. Kostin, A. Bioplastics: Prospects in Russia // Plastiks. 2015. No. 3. Pp. 44–50.

13. Korotneva I.S., Dmitriev K.E., Mukhin A.S. Biodegradable Polymer Composite Materials Based on Synthetic Polymers and Natural Components // From Chemistry to Technology Step by Step. 2020. Vol. 1, No. 1. Pp. 81–89.

14. Bezyazykaya R.A., Kiprya A.V., Sokurenko E.L. Application of biodegradable polymer materials for solving environmental problems // Fire and technosphere safety: problems and ways of improvement. 2021. Vol. 1, No. 8. Pp. 41–42.

15. Kozlov G.V., Ovcharenko E.N., and Mikitaev A.K. Structure of the Amorphous State of Polymers. Moscow: D.I. Mendeleev Russian Chemical Society, 2009. 392 p.

16. Gariyeva F.R., Karimova A.Kh. Research of the Ways of Obtaining and Properties of Potential Biodegradable Polymers Based on Polyethylene // Bulletin of Kazan Technological University. 2013. Vol. 16, No. 23. Pp. 121–123.

17. Legonkova O.A., Selitskaya O.V. Microbiological Destruction of Composite Polymer Materials in Soils // Soil Science. 2009. No. 1. Pp. 71–78.

18. Bondaletova L.I., Bondaletov V.G. Polymer Composite Materials. Part 1: Textbook. Tomsk: TPU Publishing House, 2013. 118 p.

19. Rogovina S.Z., Lomakin S.M., Aleksanyan K.V., Prut E.V. Biodegradable Polymer Materials Based on Polylactide // Chemical Physics. 2012. Vol. 31, No. 6. P. 54.

20. Smikovskaya R.S., Kuznetsova O.P., Volik V.G., Prut E.V. Structure and Properties of Biocomposites Based on Keratin and Thermoplastic Polymers // Chemical Physics. 2020. Vol. 39, No. 5. P. 72.

21. Legonkova O.A. Packaging materials made of biodegradable materials based on polylactide and starch // Food Industry. 2009. No. 6. Pp. 12–13.

22. Sherieva M.L., Shustov G.B., and Shetov R.A. Biodegradable starch-based compositions // Plastic Masses. 2004. No. 10. Pp. 29–31.

23. Rybkina S.P. Biodegradable packaging materials based on polysaccharides (starch) // Plastic Masses. 2012. No. 2. Pp. 61–64.

24. Daglen B.C., Tyler D.R. Photodegradable plastics: end-of-life design principles // Green Chem Lett Rev. 2010. V. 3. N. 2. P. 69–82.

25. Ivanov V.B., Solina E.V. Influence of temperature on photodestruction of colored polymers // All Materials. Encyclopedic Reference Book. 2018. No. 9. Pp. 2–7.

26. Rabek J.F. Photosensitized Degradation of Polymers // Ultraviolet Light Induced Reactions in Polymers. 1976. V. 18. P. 255–271.

27. Gafurov S.D., Boboev T.B., Istamov F.Kh. Influence of thermomechanical effect on light resistance of polyethylene // Applied Physics. 2018. No. 3. Pp. 70–73.

28. Barikani M., Oliaei E., Seddiqi H., Honarkar H. Preparation and application of chitin and its derivatives: a review // Iran. Polym. J. 2014. V. 23. P. 307–326.

29. Smirnov V.F., Smirnova L.A., Mochalova A.E., Kryazhev D.V., Tserova N.E., Zotov K.A. Destruction of compositions based on chitosan copolymers with vinyl monomers by micromycetes // Biotechnology. 2011. No. 4. Pp. 47–56.

30. Varlamov V.P., Ilyina A.V., Shagdarova B.Ts., Lunkov A.P., Mysyakina I.S. Chitin/Chitosan and Its Derivatives: Fundamental and Applied Aspects // Advances in Biological Chemistry. 2020. Vol. 60. Pp. 317–368.

31. Leskova S.A. Problems of Polyolefin Biodegradation: The Case of Polyethylene // Innovations. Science. Education. 2021. No. 40. Pp. 309–315.

32. Kolesnikova N.N., Lukanina Yu.K., Popov A.A. Biodegradable composite materials based on polyethylene and wood flour // Deformation and Destruction of Materials. 2012. No. 7. P. 33.

33. Dehant I., Danz R., Kimmer V., and Schmolke R. Infrared Spectroscopy of Polymers. Moscow: Khimiya Publishing House, 1976. 472 p.

34. Vikhareva I.N., Zaripov I.I., Kinzyabulatova D.F., Minigazimov N.S., Aminova G.K. Biodegradable Polymer Materials and Modifying Additives: Current State. Part I // Nanotechnology in Construction. 2020. Vol. 12, No. 6. Pp. 320–325.

35. Mazitova A.K., Aminova G.K., Zaripov I.I., Vikhareva I.N. Biodegradable Polymer Materials and Modifying Additives: Current State. Part II // Nanotechnology in Construction. 2021. Vol. 13, No. 1. Pp. 32–38.

36. Mazitova A.K., Aminova G.K., Builova E.A., Zaripov I.I., Vikhareva I.N. Biodegradable Polymer Materials and Modifying Additives: Current State. Part III // Nanotechnology in Construction. 2021. Vol. 13, No. 2. Pp. 73–78.

37. Alekseev E.I. Influence of natural rubber additives on the properties of high-pressure polyethylene // Bulletin of the Technological University. 2017. Vol. 20, No. 8. Pp. 20–22.

38. Mastalygina E., Varyan I., Kolesnikova N., Gonzalez M.I.C., Popov A. Effect of natural rubber in polyethylene composites on morphology, mechanical properties and biodegradability // Polymers. 2020. V. 12, N 437.

39. Yusupov R.R., Yanov V.V., Zenitova L.A. Composite Materials Based on Polypropylene and Natural Rubber // Bulletin of the Technological University. 2017. Vol. 20, No. 21. Pp. 20–23.

40. Rose K., Steinbuchel A. Biodegradation of natural rubber and related compounds: recent insights into a hardly understood catabolic capability of microorganisms // Applied and Environmental Microbiology. 2005. V. 71, N 6. P. 2803.

41. Varyan I., Mastalygina E., Kolesnikova N., Popov. A. Physical-mechanical properties of polyethylene-natural rubber blends // Journal of Physics: Conference Series. 2018. V. 1129. Р. 012036.

42. I.A. Varyan, E.E. Mastalygina, N.N. Kolesnikova, and Anatoly A. Popov. Impact of natural rubber on biological fouling and degradation of polyethylene composites // AIP Conference Proceedings 2018. V. 1981. P. 020119.

43. Grigoriadi A.S., Tsvetkov V.O., Bazunova A.A., Zakharov V.P. Assessment of the biological activity of soil and its participation in the destruction of polymer composites based on secondary polypropylene and a filler from plant raw materials // Izvestiya of the Ufa Scientific Center of the Russian Academy of Sciences. 2018. Vol. 3, No. 1. Pp. 95–101.

44. Fomin S.V., Burkov A.A., Iordansky A.L. Research of the structure and properties of biodegradable polymer compositions based on poly-3-hydroxybutyrate and polyisobutylene // Bulletin of Kazan Technological University. 2013. Vol. 16, No. 9. Pp. 115–119.


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For citations:


Varyan I.A., Kolesnikova N.N., Popov A.A. BIODEGRADABLE COMPOSITIONS BASED ON POLYOLEFINS AND ELASTOMERS. Proceedings of the Kabardino-Balkarian State University. 2022;12(6):17-22. (In Russ.)

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