Simulation of carbon nanotubes as macromolecular tangles. Melt viscosity

Kozlov, G.; Dolbin, I.

doi:10.31857/S004036440003383-5

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Teplofizika vysokikh temperatur

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Simulation of carbon nanotubes as macromolecular tangles. Melt viscosity

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Simulation of carbon nanotubes as macromolecular tangles. Melt viscosity

PII

S004036440003383-5-1

DOI

10.31857/S004036440003383-5

Publication type

Article

Status

Published

Authors

G. Kozlov

Affiliation: Kabardino-Balkarian State University. H.M. Berbekova
Address: Russian Federation

I. Dolbin

Affiliation: Kabardino-Balkarian State University. H.M. Berbekova
Address: Russian Federation

Journal name

Teplofizika vysokikh temperatur

Edition

Volume 56 Issue 5

Pages

848-850

Abstract

Keywords

Received

27.12.2018

Publication date

27.12.2018

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GOST	Kozlov G., Dolbin I. Simulation of carbon nanotubes as macromolecular tangles. Melt viscosity // Teplofizika vysokikh temperatur – 2018. – V. 56. – Issue 5 C. 848-850 [Electronic resource]. URL: http://ras.jes.su/tvt/s004036440003383-5-1-en (circulation date: 25.04.2024). DOI: 10.31857/S004036440003383-5
MLA	Kozlov, G., Dolbin, I. "Simulation of carbon nanotubes as macromolecular tangles. Melt viscosity." Teplofizika vysokikh temperatur 56.5 (2018):848-850. DOI: 10.31857/S004036440003383-5
APA	Kozlov G., Dolbin I. (2018). Simulation of carbon nanotubes as macromolecular tangles. Melt viscosity. Teplofizika vysokikh temperatur 56(5), pp.848-850 DOI: 10.31857/S004036440003383-5

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1. Eletskij A. V. Mekhanicheskie svojstva uglerodnykh nanotrubok // UFN. 2007. T. 177. № 3. S. 223.

2. Schaefer D. W., Justice R. S. How nano are nanocompostes? // Macromolecules. 2007. V. 40. № 24. P. 8501.

3. Kozlov G. V., Yanovskij Yu. G., Zhirikova Z. M., Aloev V. Z., Karnet Yu. N. Geometriya uglerodnykh nanotrubok v srede polimernykh kompozitnykh matrits // Mekhanika kompozitsionnykh materialov i konstruktsij. 2012. T. 18. № 1. S. 131.

4. Kozlov G. V., Dolbin I. V. Vliyanie real'nogo urovnya anizotropii uglerodnykh nanotrubok na stepen' usileniya polimernykh nanokompozitov // Izv. vuzov. Fizika. 2 17. T. 60. № 6. S. 72.

5. Komarov B. A., Dzhavadyan Eh. A., Irzhak V. I., Ryabenko A. G., Lesnichaya V. A., Zvereva G. I., Krestinin A. V. Ehpoksiaminnye kompozity so sverkhmalymi kontsentratsiyami odnoslojnykh uglerodnykh nanotrubok // Vysokomolek. soed. A. 2011. T. 53. № 6. S. 897.

6. Muthukumar M. Dynamics of polymeric fractals // J. Chem. Phys. 1985. V. 83. № 6. P. 3161.

7. Mikitaev A. K., Kozlov G. V., Zaikov G. E. Polimernye nanokompozity: mnogoobrazie strukturnykh form i prilozheniya. M.: Nauka, 2009. 278 s.

8. Bridge B. Theoretical modeling of the critical volume fraction for percolation conductivity of fibre-loaded conductive polymer composites // J. Mater. Sci. Lett. 1989. V. 8. № 2. P. 102.

9. Family F. Fractal dimension and grand universality of critical phenomena // J. Stat. Phys. 1984. V. 36. № 5/6. P. 881.

10. Shogenov V. N., Kozlov G. V. F raktal'nye klastery v fiziko-khimii polimerov. Nal'chik: Poligrafservis i T, 2002. 268 s.

11. Isaacson J., Lubensky T. C. Flory exponents for generalized polymer problems // J. Phys. Lett. (Paris). 1980. V. 41. № 19. P. L469.

12. Kozlov G. V., Sanditov D. S. Angarmonicheskie ehffekty i fiziko-mekhanicheskie svojstva polimerov. Novosibirsk: Nauka, 1994. 261 s.

13. Dolbin I. V., Kozlov G. V., Mikitaev A. K. Strukturnaya model' ognestojkosti nanokompozitov polimer-organoglina // TVT. 2015. T. 53. № 4. S. 585.