References
- Achour, M. E.; Droussi, A.; Medine, D.; Oueriagli, A.; Outzourhit, A.; Belhadj Mohamed, A.; Zangar, H. Thermal and dielectric properties of polypyrrole-poly(methyl methacrylate) nanocomposites. International Journal of Physical Sciences 2011, 6, 5075–5079.
- Aribou, N.; Elmansouri, A.; Achour, M. E.; Costa, L. C.; Belhadj Mohamed, A.; Oueriagli, A.; Outzourhit, A. Thermal and spectral dielectric properties of polypyrrole/polymethylmethacrylate composites. Spectroscopy Letters 2012, 45, 477–481.
- Rahaman, M.; Chaki, T. K.; Khastgir, D. Modeling of DC conductivity for ethylene vinyl acetate (EVA)/polyaniline conductive composites prepared through in situ polymerization of aniline in EVA matrix. Composites Science and Technology 2012, 72, 1575–1580.
- Emrea, F. B.; Kesik, M.; Kanik, F. E.; Akpinard, H. Z.; Aslan-Gurele, E.; Rossie, R. M.; Toppare, L. A benzimidazole-based conducting polymer and a PMMA–clay nanocomposite containing biosensor platform for glucose sensing. Synthetic Metals 2015, 207, 102–109.
- Baran, D.; Balan, A.; Stubhan, T.; Ameri, T.; Toppare, L.; Brabec, C. J. Photovoltaic properties of benzotriazole containing alternating donor–acceptor copolymers: Effect of alkyl chain length. Synthetic Metals 2012, 162, 2047–2051.
- Ciobotaru, I. C.; Matei, E.; Ciobotaru, C. C.; Polosan, S. Embedding of IrQ(ppy)2 organometallic compounds in polypyrrole conducting polymer for OLED’s applications. Synthetic Metals 2014, 198, 323–328.
- Erginer, R.; Toppare, L.; Alkan, S.; Bakır, U. Immobilization of invertase in functionalized copolymer matrices. Reactive and Functional Polymers 2000, 45, 227–233.
- Lux, F. Models proposed to explain the electrical conductivity of mixtures made of conductive and insulating materials. Reactive and Functional Polymers 1993, 28, 285–301.
- Elhad Kassim, S. A.; Achour, M. E.; Costa, L. C., Lahjomri, F. Modelling the DC electrical conductivity of polymer/carbon black composites. Journal of Electrostatics 2014, 72, 187–191.
- Elhad Kassim, S. A.; Achour, M. E.; Costa, L. C.; Lahjomri, F. Prediction of the DC electrical conductivity of carbon black filled polymer composites. Polymer Bulletin 2015, 72, 2561–2571.
- Achour, M. E.; Droussi, A.; Zoulef, S.; Gmati, F.; Fattoum, A.; Belhadj Mohamed, A.; Zangar, H. Electricalconductivity of polypyrrole–polymethylmethacrylate composites determined by impedance spectroscopy. Spectroscopy Letters 2008, 41(6), 299–304.
- Kirkpatrick, S. Percolation and conduction. Reviews of Modern Physics 1973, 45, 574–588.
- De Gennes, P. G. On a relation between percolation theory and the elasticity of gels. Journal de Physique Archives 1976, 37, 1–2.
- Efros, L.; Shklovskii, B. I. critical behaviour of conductivity and dielectric constant near the metal-non-metal transition threshold. Physica Status Solidi B 1976, 76, 475–485.
- Straley, J. P. Critical phenomena in resistor networks. Journal of Physics C: Solid State Physics 1976, 9, 783–795.
- Bergman, D. J.; Imry, Y. Critical behavior of the complex dielectric constant near the percolation threshold of a heterogeneous material. Physical Review Letters 1977, 39, 1222–1225.
- McLachlan, D. S. Analytical functions for the DC and AC conductivity of conductor-insulator composites. Journal of Electroceramics 2000, 5, 93–110.
- McLachlan, D. S. A quantitative analysis of the volume fraction dependence of the resistivity of cermets using a general effective media equation. Journal of Applied Physics 1990, 68, 195–199.
- Mamunya, E. P.; Shumskii, V. F.; Lebedev, E. V. Rheological properties and electric conductivity of carbon black-filled polyethylene and polypropylene. Polymer Science 1994, 36, 835–838.
- Mamunya, E. P.; Davidenko, V. V.; Lebedev, E. V. Effect of polymer-filler interface interactions on percolation conductivity of thermoplastics filled with carbon black. Compos. Interfaces 1997, 4, 169–176.
- Mamunya, E. P.; Davydenko, V. V.; Pissis, P.; Lebedev, E. V. Electrical and thermal conductivity of polymers filled with metal powders. European Polymer Journal 2002, 38, 1887–1897.
- Cullity, B. D. Elements of X-ray Diffraction, 2nd Ed.; Addison Wesley: Reading, MA 1978, 102.
- El Sawi, I.; Olivier, P. A.; Demont, P.; Bougherara, H. Processing and electrical characterization of a unidirectional CFRP composite filled with double-walled carbon nanotubes. Composites Science and Technology 2012, 73, 19–26.
- McQueen, D. H.; Jäger, K. M.; Peliskova, M. Multiple threshold percolation in polymer/filler composites. Journal of Physics D: Applied Physics 2004, 37, 2160–2169.
- Boukheir, S.; Len, A.; Füzi, J.; Kenderesi, V.; Achour, M. E.; Éber, N.; Costa, L. C.; Oueriagli, A.; Outzourhit. A. Structural characterization and electrical properties of carbon nanotubes/epoxy polymer composites. Journal of Applied Polymer Science 2016, 133, 44514.
- McLachlan, D. S.; M. B.; Newman R. E. Journal of the American Ceramic Society 1990, 73(8), 2187.
- Barton, R. L.; Keith, J. M.; King, J. A. Development and modeling of electrically conductive carbon filled liquid crystal polymer composites for fuel cell bipolar plate applications. Journal of New Materials for Electrochemical Systems 2007, 10, 225–229.
- Vargas-Bernal, R.; Herrera-Pérez, G.; Tecpoyotl-Torres, M.; Calixto-Olalde, M. E. Analysis of DC electrical conductivity models of carbon nanotube-polymer composites with potential application to nanometric electronic devices. Journal of Electrical and Computer Engineering 2013, 2013, 14.