Multi-Scale Prediction of Effective Conductivity for Carbon Nanofiber Polymer Composites

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Multi-Scale Prediction of Effective Conductivity for Carbon Nanofiber Polymer Composites Publisher

Zare Y¹ ; Munir MT² ; Rhee KY³ ; Park SJ⁴

Show Affiliations

1. Biomaterials and Tissue Engineering Research Group, Department of Interdisciplinary Technologies, Breast Cancer Research Center, Motamed Cancer Institute, ACECR, Tehran, Iran
2. College of Engineering and Technology, American University of the Middle East, Egaila, 54200, Kuwait
3. Department of Mechanical Engineering (BK21 four), College of Engineering, Kyung Hee University, Yongin, South Korea
4. Department of Chemistry, Inha University, Incheon, 22212, South Korea

Source: Journal of Materials Research and Technology Published:2024

Abstract

In this study, a multi-scale method is developed using simple equations and meaningful factors to estimate the effective conductivity of carbon nanofiber (CNF) polymer composites, referred to PCNFs. The interphase around the networked nanofibers is considered in Step I, while the tunneling zone near the CNF/interphase is addressed in Step II. Finally, the effective conductivity of PCNFs, comprising CNFs, interphase, and tunnels, is estimated in Step III. The calculations of the multi-step method are validated by plotting the impacts of all factors and comparing them with experimental data from numerous CNF-filled samples. The minimum ranges of percolating onset (ϕp) and polymer resistivity in the tunnel (ρ) maximize the effective conductivity of system, but an insulative sample is observed at ρ > 60 Ω m and ϕp > 0.015. Additionally, a tunneling distance (λ) of 1 nm and a contact diameter (d) of 60 nm yield the uppermost effective conductivity of 0.45 S/m, though d < 20 nm results in an insulative PCNF. Consequently, lower percolation onset, smaller polymer tunneling resistivity, narrower tunnels, and larger contact diameters enhance the effective conductivity in PCNFs. Furthermore, the sample with the lowest tunneling resistance demonstrates the highest effective conductivity. This evidence reveals the key role of electron tunneling in PCNFs, validating the multi-scale methodology. © 2024 The Authors

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Style	Citing Format
MLA	Zare Y, et al.. "Multi-Scale Prediction of Effective Conductivity for Carbon Nanofiber Polymer Composites." Journal of Materials Research and Technology, vol. 33, no. , 2024, pp. 8895-8902.
APA	Zare Y, Munir MT, Rhee KY, Park SJ (2024). Multi-Scale Prediction of Effective Conductivity for Carbon Nanofiber Polymer Composites. Journal of Materials Research and Technology, 33(), 8895-8902.
Chicago	Zare Y, Munir MT, Rhee KY, Park SJ. "Multi-Scale Prediction of Effective Conductivity for Carbon Nanofiber Polymer Composites." Journal of Materials Research and Technology 33, no. (2024): 8895-8902.
Harvard	Zare Y et al. (2024) 'Multi-Scale Prediction of Effective Conductivity for Carbon Nanofiber Polymer Composites', Journal of Materials Research and Technology, 33(), pp. 8895-8902.
Vancouver	Zare Y, Munir MT, Rhee KY, Park SJ. Multi-Scale Prediction of Effective Conductivity for Carbon Nanofiber Polymer Composites. Journal of Materials Research and Technology. 2024;33():8895-8902.
BibTex	@article{ author = {Zare Y and Munir MT and Rhee KY and Park SJ}, title = {Multi-Scale Prediction of Effective Conductivity for Carbon Nanofiber Polymer Composites}, journal = {Journal of Materials Research and Technology}, volume = {33}, number = {}, pages = {8895-8902}, year = {2024} }
RIS	TY - JOUR AU - Zare Y AU - Munir MT AU - Rhee KY AU - Park SJ TI - Multi-Scale Prediction of Effective Conductivity for Carbon Nanofiber Polymer Composites JO - Journal of Materials Research and Technology VL - 33 IS - SP - 8895 EP - 8902 PY - 2024 ER -

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