Synthesis of Superhydrophobic Carbon Surface during Combustion Propane

Authors

  • Z. A. Mansurov The Institute of Combustion Problems, 050012, Bogenbay batyr street, 172, Almaty, Kazakhstan
  • M. Nazhipkyzy The Institute of Combustion Problems, 050012, Bogenbay batyr street, 172, Almaty, Kazakhstan
  • B. T. Lesbayev The Institute of Combustion Problems, 050012, Bogenbay batyr street, 172, Almaty, Kazakhstan
  • N. G. Prikhodko The Institute of Combustion Problems, 050012, Bogenbay batyr street, 172, Almaty, Kazakhstan
  • M. Auyelkhankyzy The Institute of Combustion Problems, 050012, Bogenbay batyr street, 172, Almaty, Kazakhstan
  • I. K. Puri Department of Engineering Science and Mechanics, Virginia Tech, Blacksburg, Virginia 24061, USA

DOI:

https://doi.org/10.18321/ectj94

Abstract

We synthesize and deposit carbon nanostructures through flame synthesis on silicon and nickel wafers at different nonpremixed flame locations to produce hydrophobic surfaces. The hydrophobicity is characterized through the contact angle for water droplets placed on the surface. The surface morphology of the nanoparticles is obtained from SEM images. The morphology and hydrohobicity of the nanostructured surfaces depends upon the deposition, which differs at various flame locations. We determine the optimum flame location for the synthesis and deposition of surface carbon nanostructures that lead to maximum hydrophobicity.

References

1. Z.A. Mansurov. Some applications of nanocarbon materials for novel devices / R.Gross et. al (eds.), Nanoscale Devices -Fundamentals and Applications, 355-368. 2006 Springer.

2. S. Sen, I.K. Puri Flame synthesis of carbon nanofibers and nanofiber composites containing encapsulated metal particles. Nanotechnology 2004; 15 (3): 264 - 8.

3. S. Naha., S. Sen, I.K. Puri. Flame synthesis of superhydrophobic amorphous carbon surfaces, Carbon V. 45, Issue 8, (2007), P. 1702-1706.

4. S. Mazumder., S. Ghosh., I. Puri. Nonpremixed flame synthesis of hydrophobic carbon nanostructured surfaces, 33 th. Symp. (Intern.) on Combustion. Pittsburgh: The Combustion Inst., (2010).

5. J. Robertson Diamond-like amorphous carbon. Mater Sci Eng R 2002; 37 (4 - 6): 129 - 281.

6. A. Levesque, V.T. Binh, V. Semet, D. Guillot, R.Y. Fillit, M.D. Brookes, et al. Mono disperse carbon nanopearls in a foam-like arrangement: a new carbon nano-compound for cold cathodes. Thin Solid Films 2004; 464-465: 308 - 14.

7. Z.A. Mansurov, M. Nazhipkyzy, B.T. Lesbaev, I.K. Puri. Synthesis of superhydrophobic carbon surface during combustion propane. Oil and Gas, (2010); 5; p. 27-33 (In Russian).

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Published

2012-02-15

How to Cite

Mansurov, Z. A., Nazhipkyzy, M., Lesbayev, B. T., Prikhodko, N. G., Auyelkhankyzy, M., & Puri, I. K. (2012). Synthesis of Superhydrophobic Carbon Surface during Combustion Propane. Eurasian Chemico-Technological Journal, 14(1), 19–23. https://doi.org/10.18321/ectj94

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