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Decrypting of effective resistance for composites of polymer-carbon nanofiber: An applicable approach to regulate the electrical conductivity

Yasser Zare, Muhammad Tajammal Munir, Kyong Yop Rhee, Soo‐Jin Park

2025Journal of Materials Research and Technology14 citationsDOIOpen Access PDF

Abstract

It is postulated that the effective resistance ( R eff ) causes a critical impact on the nanocomposite electrical conductivity, and an increase in R eff inversely affects the composite conductivity. Nevertheless, R eff remains an elusive parameter, and its dependence on the characteristics of the filler, tunneling district and interphase were inadequately defined. In this work, we advance the Jang-Yin and Weber-Kamal models to accurately assess the conductivity for polymer/carbon nanofiber (CNF) system (PCNF), incorporating key factors as tunneling properties and interphase size. The precision of these models is rigorously evaluated against a broad spectrum of experimental data. By joining the models, we derive an explicit expression for R eff in PCNFs, elucidating its correlation with percolation onset, CNF concentration, CNF dimensions, interphase depth, CNF waviness, tunneling diameter ( d ), tunneling size, contact number ( m ), and polymer tunneling resistivity. A comprehensive analysis of these factors on the R eff validates the proposed theoretical framework. Our findings reveal that R eff reaches a peak value of 2.2 × 10 6 Ω at m = 50 and d = 10 nm, whereas it significantly decreases to approximately 0.04 × 10 6 Ω when d exceeds 34 nm. The results indicate that the minimal number and size of contacts maximize R eff , while increasing both contact number and diameter markedly reduces it. Furthermore, conditions such as reduced CNF waviness, thinner CNFs, a more substantial interphase, weak polymer tunneling resistivity, shorter tunneling distance, larger CNFs, and a lower percolation onset collectively act to minimize R eff , thereby optimizing the composite electrical conductivity.

Topics & Concepts

Materials scienceComposite materialElectrical resistivity and conductivityNanofiberConductivityPolymerCarbon nanofiberElectrical resistance and conductanceCarbon fibersCarbon nanotubeComposite numberElectrical engineeringEngineeringPhysical chemistryChemistryAdvanced Sensor and Energy Harvesting MaterialsCarbon Nanotubes in CompositesConducting polymers and applications