The Synthesis of Nanocomposites with Use of Cellulose

Authors

  • G. K. Maylieva The South Kazakhstan State University named after M.O. Auezov, 5 Tauke khan St., Shymkent, Kazakhstan
  • A. A. Mirzaeva The South Kazakhstan State University named after M.O. Auezov, 5 Tauke khan St., Shymkent, Kazakhstan
  • G. E. Satayeva The South Kazakhstan State University named after M.O. Auezov, 5 Tauke khan St., Shymkent, Kazakhstan
  • J. Jandosov The Institute of Combustion Problems, 172 Bogenbay Batyr St., 050012, Almaty, Kazakhstan
  • Z. A. Mansurov The Institute of Combustion Problems, 172 Bogenbay Batyr St., 050012, Almaty, Kazakhstan

DOI:

https://doi.org/10.18321/ectj130

Abstract

This work studied the synthesis of nanocomposites with cellulose use as crystallizing polymer on the basis of its ability to form crystalline particles with various parameters of an elementary cell – nanoparticles of a metal or oxide origin. The authors obtained high dispersed systems by dispersion of volume phases from solutions using condensation method. At using of this method, depending on the conditions of the formation process of the new phase can be obtained as systems with a size of several nanometers as well as more coarsely dispersed systems. The dispersiveness of a system, arising during formation of new phases, is determined by ratio speed of formation and nucleus growth of new phase a phase transition. The condensation process involves the formation of new phase according the heterogeneous or homogeneous mechanisms. The kinetics formation of new phase is determined by two stages: the formation of  condensation centers (nucleus) and nucleus growth. In formation process of nanocomposite materials the natural polymer with known molecular structure is used as matrix, in which we can put desired nanoparticles in the form of filler. In this work the authors used cellulose which has developed capillary-porous structure, including in-fibrillar porous with the size of 1.5-10 nm, and which is able to form crystallites with different parameters of lattice cell.

References

1. A.I. Gusev. Nanocrystalline materials. Cambridge International Science Publishing, 2001. - 347 p.

2. C. Berry, A. Curtis. Functionalisation of magnetic nanoparticles for applications in biomedicine. 2003, J. Phys. D: Appl. Phys. 36 R198.

3. R. Massart. Preparation of aqueous magnetic liquids in alkaline and acidic media. IEEE Trans. Magn. 17, 1981. - p. 1247-1248.

4. R.Sh. Askhadulin, P.N. Martynov // VI Russian Conference "Physical chemistry of ultrafine (nano) systems" 9-23 August 2002, Tomsk. Proceedings of the Conference. Moscow: Engineering Physics Institute, 2003. p.451-455.

5. V. Fortov. Thermophysical properties of substances in extreme conditions. Materials of the X Russian conference on thermophysical in book properties of substances. Kazan: Butlerov Communications. 2002. p. 1-7.

6. C.L.Chiang. Application of superparamagnetic nanoparticles in purification of plasmid DNA from bacterial cells / C.L. Chiang, C.S. Sung, T.F. Wu // J. of Chromatography B.- 2005,- V. 822.- p. 54-60.

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Published

2012-11-15

How to Cite

Maylieva, G. K., Mirzaeva, A. A., Satayeva, G. E., Jandosov, J., & Mansurov, Z. A. (2012). The Synthesis of Nanocomposites with Use of Cellulose. Eurasian Chemico-Technological Journal, 14(4), 327–330. https://doi.org/10.18321/ectj130

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