1. JCCT
  2. All Volumes and Issues
  3. Volume 6, Number 1, 2012
  4. The Behaviour Features of Polymer Nanocomposites Filled with Calcium Carbonate

The Behaviour Features of Polymer Nanocomposites Filled with Calcium Carbonate

JCCT.
2012;
Volume 6, Number 1
Authors: 

Georgiy Kozlov, Zarema Aphashagova, Akhmed Malamatov and Gennady Zaikov

The most typical behaviour features of polymer nanocomposites filled with dispersed calcium carbonate were considered. The quantitative analysis was carried out within the frameworks of structural model: the cluster model of polymers amorphous state structure and fractal analysis. It has been shown that all changes of the considered nanocomposites properties were defined by polymeric matrix structure variations, which are due to nanofiller introduction.

polymer
nanocomposite
elasticity modulus
interfacial adhesion
yield
plasticity
fractal analysis

[1] Suwanprateeb J.: Composites A, 2000, 31A, 353.
[2] Osman A., Atallah A. and Suter U.: Polymer, 2004, 43, 1177.
[3] Misra R., Nerikar P., Bertrand K. and Murphy D.: Mater. Sci. Eng., 2004, 384A, 284.
[4] Parsons E., Boyce M., Parks D. and Weinberg M.: Polymer, 2005, 46, 2257.
[5] Tanniru M. and Misra R.: Mater. Sci. Eng., 2005, 405A, 178.
[6] Tanniru M. and Misra R.: Mater. Sci. Eng., 2007, 424A, 53.
[7] Deshmane C., Yuan Q. and Misra R.: Mater. Sci. Eng., 2007, 452-453A, 592.
[8] Zebarjad S. and Sajjadi S.: Mater. Sci. Eng., 2008, 475A, 365.
[9] Yang K., Yang Q., Li G. et al.: Mater. Lett., 2006, 60, 805.
[10] Ma C., Mai Y., Rong M. et al.: Composites Sci. Techn., 2007, 67, 2997.
[11] Chen N., Wan C., Zhang Yo. and Zhang Yi.: Polymer Test., 2004, 23, 169.
[12] Xie X.-L., Liu Q.-X., Li R.K.-Y. et al.: Polymer, 2004, 45, 6665.
[13] Jin F.-L. and Park S.-J.: Mater. Sci. Eng., 2008, 478A, 406.
[14] Phillips D. and Harris B.: [in:] Richardson M. (Ed.) Polymer Engineering Composites. Applied Science Publishers LTD, London 1978.
[15] Sultanov N., Dzhangurazov B. and Mikitaev A.: Mater. Int. Forum by Nanotechnologies “Rusnanotech-08”. Moscow, 3-5 December 2008, 527.
[16] Mikitaev A. and Kozlov G.: Fraktal’naya Mekhanika Polimernykh Materialov. Izd-vo Kabardino-Balkarskii Gos. Univ., Nal’chik 2008. 
[17] Balankin A.: Sinergetika Deformiruemogo Tela. Izd-vo Ministerstva oborony SSSR, Moskwa 1991. 
[18] Kozlov G. and Sanditov D.: Angarmonicheskie Effekty i Fiziko-Mekhanicheskie Svoistva Polimerov. Nauka, Novosibirsk 1994.
[19] Aphashagova Z., Kozlov G., Burya A. and Mikitaev A.: Materialovedenie, 2007, 9, 10.
[20] Wu S.: J. Polymer Sci. B, 1989, 27, 723.
[21] Aharoni S.: Macromolecules, 1983, 16, 1722.
[22] Mills N.: J. Appl. Polymer Sci., 1971, 15, 2791.
[23] Malamatov A., Kozlov G. and Mikitaev M.: Mekhanismy Usileniya Polimernykh Nanokompositov. Izd-vo Rossijskogo Khim.-Tekhn. Univ. im. D.I. Mendeleeva, Moskwa 2006.
[24] Kozlov G. and Novikov V.: Uspekhi Fizich. Nauk, 2001, 171, 717.
[25] Tugov I. and Shaulov A.: Vysokomolec. Soed. B, 1990, 32, 527.
[26] Aharoni S.: Macromolecules, 1985, 18, 2624.
[27] Kausch H.: Polymer Fracture. Springer-Verlag, Berlin-Heidelberg-New York, 1978.
[28] Kozlov G. and Zaikov G.: Structure of the Polymer Amorphous State. Brill Academic Publishers, Utrecht-Boston 2004.