Starting with a nanocarbon film, which has some special characteristics, the present study uses this film as a cluster of connected particles that induces the percolation of electrical carrier in composites. The composite is formed through the free infiltration of the polymer through the filler’s aggregates. This method forms nanocarbon/polymer composites which have an electrical conductivity more than three orders of magnitude greater than those prepared by mixing.
Norman, R.H. ( 1970). Conductive Rubbers and Plastics: Their Production, Application and Test Methods, Chapter 2, Elsevier Publishing Company Ltd., Essex.
2.
Klason, C., McQueen, D.H. and Kubat, J. ( 1996). Electrical Properties of Filled Polymers and Some Examples of Their Applications, Macromol. Symp., 108: 247-260.
3.
Kale, V. and Moukwa, M. ( 1999). Electrostatic Dissipation Control with an Organic Flooring System, J. Electrostat., 38(3): 239-248.
4.
Yu, G., Zhang, M.Q. and Zeng, H.M. ( 1998). Carbon Black-filled Polyolefin as a Positive Temperature Coefficient Material: Effect of Composition, Processing and Filler Treatment , J. Appl. Polymer. Sci., 70(3): 559-566.
5.
Wan, Y. and Wen, Y. ( 2004). Thermo-sensitive Properties of Carbon Black-loaded Styrene Butadiene Rubber Composite Membranes, Smart Mater. Struct. , 13(5): 983-989.
6.
Stauffer, D. and Aharony, A. ( 1992). Introduction to Percolation Theory, 1st edn, Taylor and Francis, London .
7.
Adler, J., Meir, Y., Aharony, A., Harris, A.B. and Klein, L. ( 1990). Low-concentration Series in General Dimension , J. Stat., 58: 511-538.
8.
Douglas, H., Jäger, M.K. and Pelíškova, M. ( 2004). Multiple Threshold Percolation in Polymer/Filler Composites , J. Phys. D: Appl. Phys., 37: 2160-2169.
9.
Bloor, D., Donnelly, K., Hands, P.J., Laughlin, P. and Lussey, D. ( 2005). A Metal-Polymer Composite with Unusual Properties , J. Phys. D: Appl. Phys., 38: 2851-2860.
10.
Sandu, I., Morjan, I., Voicu, I., Alexandrescu, R., Dumitrache, F., Soare, I., et al. (2003). Thin Films Induced by Nanometric Powders Flotation 2003; International Conference on Physics and Control (PHYSCON 2003) , Saint Petersburg, Russia, 3: 917-919.
11.
Sandu, I., Morjan, I., Voicu, I., Alexandrescu, R., Dumitrache, F., Soare, I., et al. (2005). From Nanopowders to Micro-crystals, International Conference on Physics and Control (PHYSCON 2005), Saint Petersburg, Russia, 773-775.
12.
Morjan, I., Voicu, I., Dumitrache, F., Sandu, I., Soare, I., Alexandrescu, R., et al. (2003). Carbon Nanopowders from the Continuous-wave CO2 Laser-induced Pyrolysis of Ethylene, Carbon, 41(15): 2913- 2921.
13.
Morjan, I., Voicu, I., Alexandrescu, R., Pasuk, I., Sandu, I., Dumitrache, F., et al. (2004). Gas Composition in Laser Pyrolysis of Hydrocarbon-based Mixtures: Influence on Soot Morphology, Carbon, 42(7): 1263-1267.
14.
Probst, N. and Grivei, E. ( 2002). Structure and Electrical Properties of Carbon Black, Carbon, 40: 201-205.
15.
Wessling, B. , Volk, H., Mathew , W.R. and Kulkarni, V.G. (1998). Models for Understanding Processing Properties of Intrinsically Conductive Polymers, Mol. Cryst. Liq. Cryst., 160(205): 205-220.
