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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 727-728Experimental Research on the Conductive Property...

Experimental Research on the Conductive Property of MWCNT Nanopaper

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Abstract:

This paper presents a systematic study of the nano-sized structure and temperature dependent electrical properties. A method of synthesizing the self-assembled multi-walled carbon nanotube (MWCNT) nanopaper on hydrophilic polycarbonate membrane was explored. The process is based on the very well-defined dispersion of nanotube and controlled pressure vacuum deposition procedure. The experiment results show that the ratio changes of MWCNT in the nanopaper could lead to the changes in the electrical conductivity efficiency of the nanopaper. Furthermore, the electrical resistivity of MWCNT nanopaper decreased as temperature increase.

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Frontiers of Mechanical Engineering and Materials Engineering III

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Periodical:

Applied Mechanics and Materials (Volumes 727-728)

Pages:

137-140

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.727-728.137

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Online since:

January 2015

Authors:

A Ying Zhang*

Keywords:

Carbon Nanotube (CN), Conductive Properties, Nanopaper

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© 2015 Trans Tech Publications Ltd. All Rights Reserved

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[1] X. Wang, Q.Q. Li, J. Xie and et al: Nano Lett. Vol. 9 (2009), p.3137.

[2] S. Gullapalli, M.S. Wong: Chem Eng Prog. Vol. 107 (2011), p.28.

[3] J.W. Mintmire, B.I. Dunlap and et al: Phys. Rev. Lett. Vol. 68 (1992), p.631.

[4] R.B. Pipes, S.J.V. Frank and et al: Compos Sci Technol. Vol. 63 (2003), p.1349.

[5] M.F. Yu, B.S. Files and et al: Phys Rev Lett. Vol. 84 (2000), p.5552.

[6] C. Dekker: Phys Today. Vol. 52 (1999), p.22.

[7] S. Berber, Y.K. Kwon and D. Tomanek: Phys Rev Lett. Vol. 84 (2000), p.4613.

[8] E.T. Thostenson, Z.F. Ren and T.W. Chou: Compos Sci Technol. Vol. 61 (2001), p.1899.

[9] Z. Yao, C.L. Kane and C. Dekker: Phys Rev Lett. Vol. 84 (2000), p.2941.

[10] C.Y. Li, E.T. Thostenson and T. W. Chou: Compos Sci Technol. Vol. 68 (2008), p.1445.

[11] J.S. Leng, H.B. Lu and et al: MRS Bull. Vol. 34 (2009), p.848.

[12] H.B. Lu, Y.J. Liu and et al: Appl Phys Lett. Vol. 96 (2010), p.084102.

[13] M.J. Biercuk, M.C. Llaguno and et al: Appl Phys Lett. Vol. 80 (2002), p.2767.

[14] L.S. Schadler, S.C. Giannaris and P.M. Ajayan: Appl Phys Lett. Vol. 73 (1998), p.3842.

[15] Z. Wang, Z.Y. Liang and et al: Compos Part A-Appl Sci Manuf. Vol. 35 (2004), p.1225.

[16] J. Gou, S.O. Braint and et al: J Nanomater. Vol. 1 (2006), p.1.

[17] J. Gou: Polym Int. Vol. 55 (2006), p.1283.

[18] X.J. He, J.H. Du and et al: Appl Phys Lett. Vol. 86 (2005), p.062112.