Strongly Non‐linear Carbon Nanofibre Influence on Electrical Properties of Polymer Composites

Biryulin, Yu. F.; Kurdybaylo, Dmitry; Шаманин, В. В.; Aleksjuk, G.; Волкова, Т. С.; Melenevskaya, E. Yu.; Saydashev, I.; Eidelman, E. D.; Makarova, T. L.; Теруков, Е. И.; Zaitseva, N. M.; Negrov, Vladimir L.; Tkatchyov, A.

doi:10.1080/15363830802313121

Cited by 2 publications

(1 citation statement)

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“…), geometry and size, surface functionalization, and so forth [5]. The main problem during the construction of the conductive network when carbonaceous particles are used, such as carbon black [6], graphite [7,13,14], fibers [15,16], or carbon nanotubes (NTC) [17,18], is the van der Waals interactions among carbon particles in the macroscopic agglomerates, which has a crucial effect for obtaining an optimal dispersion of them into the polymer matrix and in turn in the percolation threshold. Then, the compatibility is related to composition and surface chemistry [19]; geometry: a high aspect ratio of the conductive particles allows reaching lower percolation concentrations [14,20]; structure [10,[21][22][23]: a higher structure of the primary aggregates of elementary carbon particles reduces percolation threshold due to a better electric path interconnection at microscopic level [10]; surface area [22,23]: surface functionalization of the NTC [24][25][26][27][28], graphite [14,29], and CB particles [22] has been used to enhance the dispersion and compatibility with polymer matrixes.…”

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confidence: 99%

Relationship between Polymer Dielectric Constant and Percolation Threshold in Conductive Poly(styrene)‐Type Polymer and Carbon Black Composites

Martínez

López

Vigueras-Santiago

2015

Journal of Nanomaterials

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We study the effect of dielectric constant of some poly(styrene)-type polymer matrix on the percolation threshold in conductive polymer composites with carbon black (CB). We demonstrate that percolation threshold diminishes with an increment of the dielectric constant of polymer matrix. We chose polystyrene and other three polymers similar in structure and molecular weight but with different chemical nature. The corresponding dielectric constant and critical concentration,Xc, in volume fraction of carbon black, v/v CB, were the following: 4MePS(ε=2.43; Xc=0.058), PS(ε=2.60; Xc=0.054), 4BrPS(ε=2.82; Xc=0.051), and 4ClPS(ε=2.77; Xc=0.047). The correlation between both parameters confirms that the percolation threshold decreases while the dielectric constant increases. At microscopic level, this effect is attributed to an enhanced physical interaction of the CB particles with the asymmetric electric density produced by electronegative or inductive atoms/groups. Therefore, by controlling the chemical structure of the polymer matrix, the attraction forces between the polar groups on the carbon black surface particles with those of the polymer matrix can be improved, which in turn induces a better disaggregation and dispersion of those particles into the polymer matrix, allowing the percolation threshold reached at a lower filling fraction.

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