Percolation in Carbon Nanotube-Reinforced Polymers for Strain-Sensing Applications: Computational Investigation on Carbon Nanotube Distribution, Curvature, and Aggregation

The present article investigates the possibility of simulating the electrical conductivity of carbon nanotube-reinforced polymer composites by numerical methods. Periodic representative volume elements are generated by randomly distributing perfectly conductive reinforcements in an insulating matrix and are used to assemble an electrical network representative of the nanocomposite, where the nanotube–nanotube contacts are considered equivalent resistors modeled by means of Simmons’ equation. A comparison of the results with experimental data from the literature supports the conclusion that a random distribution of reinforcements is not suitable for simulating this class of materials since percolation thresholds and conductivity trends are different, with experimental percolation taking place before the expectations. Including nanotube curvature does not solve the issue, since it hinders percolation even further. In agreement with experimental observations, the investigation suggests that a suitable approach requires the inclusion of aggregation during the volume element generation to reduce the volume fraction required to reach percolation. Some solutions available in the literature to generate properly representative volume elements are thus listed. Concerning strain sensing, the results suggest that representative volume elements generated with random distributions overestimate the strain sensitivity of the actual composites.

[1]  Kamran Alam Khan,et al.  Rate dependent piezoresistive characterization of smart aerospace sandwich structures embedded with reduced graphene oxide (rGO) coated fabric sensors , 2022, Composites Communications.

[2]  A. García-Junceda,et al.  Microstructure and Electrical Conductivity of Cement Paste Reinforced with Different Types of Carbon Nanotubes , 2022, Materials.

[3]  Sung-Hoon Park,et al.  Comparative Study of Carbon Nanotube Composites as Capacitive and Piezoresistive Pressure Sensors under Varying Conditions , 2022, Materials.

[4]  Masahiro Inoue,et al.  Effect of Binder Chemistry on Dynamic Percolation in Electrically Conductive Carbon-Nanotube-Filled Pastes during Curing , 2022, MATERIALS TRANSACTIONS.

[5]  Kamran Alam Khan,et al.  Electromechanical behavior of self-sensing composite sandwich structures for next generation more electric aerostructures , 2022, Composite Structures.

[6]  G. Palardy,et al.  Damage Monitoring Methods for Fiber-Reinforced Polymer Joints: A Review , 2022, Composite Structures.

[7]  Ping Liu,et al.  Theoretical estimation on electrical conductivity, synergy effect and piezoresistive behavior for nanocomposites with hybrid carbon nanotube/graphene based on modified Bethe lattice method , 2022, Computational Materials Science.

[8]  A. Chattopadhyay,et al.  Computational analysis of CNT-reinforced polymer using nanoscale informed micromorphology , 2022, AIAA SCITECH 2022 Forum.

[9]  M. Haghgoo,et al.  Monte Carlo analytical-geometrical simulation of piezoresistivity and electrical conductivity of polymeric nanocomposites filled with hybrid carbon nanotubes/graphene nanoplatelets , 2022, Composites Part A: Applied Science and Manufacturing.

[10]  S. Kekez,et al.  Application of Artificial Neural Networks for Prediction of Mechanical Properties of CNT/CNF Reinforced Concrete , 2021, Materials.

[11]  Krishna Kiran Talamadupula,et al.  Statistical analysis of effective electro-mechanical properties and percolation behavior of aligned carbon nanotube/polymer nanocomposites via computational micromechanics , 2021 .

[12]  Ping Liu,et al.  The nonlinear synergistic enhancement electric conductive effect in polymer-matrix composites containing hybrid fillers of carbon nanotubes and graphene nanoplatelets , 2021 .

[13]  Steve Kench,et al.  Generating three-dimensional structures from a two-dimensional slice with generative adversarial network-based dimensionality expansion , 2021, Nature Machine Intelligence.

[14]  A. Ureña,et al.  Crack sensing mechanisms of Mode-II and skin-stringer joints between dissimilar materials by using carbon nanotubes , 2021 .

[15]  V. R. Kar,et al.  A Comprehensive Review on CNTs and CNT-Reinforced Composites: Syntheses, Characteristics and Applications , 2020 .

[16]  António Marques,et al.  Health and Safety Concerns Related to CNT and Graphene Products, and Related Composites , 2020, Journal of Composites Science.

[17]  M. Ayati,et al.  A computational approach to evaluate the nonlinear and noisy DC electrical response in carbon nanotube/polymer nanocomposites near the percolation threshold , 2020 .

[18]  M. A. Arshad,et al.  Kinetics of dynamic percolation in polymer/carbon composites , 2020, Polymer Engineering & Science.

[19]  S. Namilae,et al.  Stochastic percolation model for the effect of nanotube agglomeration on the conductivity and piezoresistivity of hybrid nanocomposites , 2019, Computational Materials Science.

[20]  B. Thang,et al.  A model for the thermal conductivity of mixed fluids containing carbon nanotubes , 2019, Computational Materials Science.

[21]  S. Pinho,et al.  Predictions of the electrical conductivity of composites of polymers and carbon nanotubes by an artificial neural network , 2019, Scripta Materialia.

[22]  S. Pinho,et al.  Application of machine learning to predict the multiaxial strain-sensing response of CNT-polymer composites , 2019, Carbon.

[23]  L. Gorbatikh,et al.  Debonding at the fiber/matrix interface in carbon nanotube reinforced composites: Modelling investigation , 2019, Computational Materials Science.

[24]  Chengyuan Wang,et al.  Electrical percolation of nanoparticle-polymer composites , 2018, Computational Materials Science.

[25]  T. Takeda,et al.  Fracture behavior and crack sensing capability of bonded carbon fiber composite joints with carbon nanotube-based polymer adhesive layer under Mode I loading , 2017 .

[26]  Michele Zappalorto,et al.  Analytical model for the prediction of the piezoresistive behavior of CNT modified polymers , 2017 .

[27]  L. Mishnaevsky,et al.  Nanomorphology of graphene and CNT reinforced polymer and its effect on damage: Micromechanical numerical study , 2016 .

[28]  M. Quaresimin,et al.  Effectiveness of the random sequential absorption algorithm in the analysis of volume elements with nanoplatelets , 2016 .

[29]  Flandin Lionel,et al.  CNT aggregation mechanisms probed by electrical and dielectric measurements , 2015 .

[30]  Ica Manas-Zloczower,et al.  Epoxy composites with carbon nanotubes and graphene nanoplatelets – Dispersion and synergy effects , 2014 .

[31]  Yasuhide Shindo,et al.  Electrical resistance-based strain sensing in carbon nanotube/polymer composites under tension: Analytical modeling and experiments , 2012 .

[32]  I. Manas‐Zloczower,et al.  Reinforcement Efficiency of Carbon Nanotubes—Myth and Reality , 2012 .

[33]  N. Hu,et al.  Investigation on sensitivity of a polymer/carbon nanotube composite strain sensor , 2010 .

[34]  I. Alig,et al.  Shear‐stimulated formation of multi‐wall carbon nanotube networks in polymer melts , 2009 .

[35]  N. Hu,et al.  Tunneling effect in a polymer/carbon nanotube nanocompositestrain sensor , 2008 .

[36]  Karl Schulte,et al.  Load and health monitoring in glass fibre reinforced composites with an electrically conductive nanocomposite epoxy matrix , 2008 .

[37]  I. Alig,et al.  Electrical conductivity recovery in carbon nanotube–polymer composites after transient shear , 2007 .

[38]  Alan H. Windle,et al.  Thermal and electrical conductivity of single- and multi-walled carbon nanotube-epoxy composites , 2006 .

[39]  Rémy Dendievel,et al.  Carbon nanotube-filled polymer composites. Numerical simulation of electrical conductivity in three-dimensional entangled fibrous networks , 2006 .

[40]  Bodo Fiedler,et al.  Evaluation and identification of electrical and thermal conduction mechanisms in carbon nanotube/epoxy composites , 2006 .

[41]  M. Sumita,et al.  Temperature and time dependence of conductive network formation: Dynamic percolation and percolation time , 2006 .

[42]  Ping Wang,et al.  Temperature dependence of electrical resistivity for carbon black filled ultra-high molecular weight polyethylene composites prepared by hot compaction , 2005 .

[43]  Christian A. Martin,et al.  Formation of percolating networks in multi-wall carbon-nanotube–epoxy composites , 2004 .

[44]  A. Sastry,et al.  Statistical geometry of random fibrous networks, revisited: Waviness, dimensionality, and percolation , 2004 .

[45]  Satish Nagarajaiah,et al.  Nanotube film based on single-wall carbon nanotubes for strain sensing , 2004 .

[46]  Jeremy G. Siek,et al.  The Boost Graph Library - User Guide and Reference Manual , 2001, C++ in-depth series.

[47]  D. Chung Temperature Dependence of Electrical Resistivity , 2001 .

[48]  J. Simmons Generalized Formula for the Electric Tunnel Effect between Similar Electrodes Separated by a Thin Insulating Film , 1963 .

[49]  Xin-She Yang,et al.  Introduction to Algorithms , 2021, Nature-Inspired Optimization Algorithms.

[50]  Michele Zappalorto,et al.  An efficient RVE formulation for the analysis of the elastic properties of spherical nanoparticle reinforced polymers , 2015 .

[51]  M. Sumita,et al.  Electrical conductivity of short carbon fiber filled HDPE/PMMA blends: effect of molding temperature and time , 1998 .

[52]  Epoxy Composites , 2022 .