Simulation of electrical conductivity for polymer silver nanowires systems


HomeHome / Blog / Simulation of electrical conductivity for polymer silver nanowires systems

May 31, 2023

Simulation of electrical conductivity for polymer silver nanowires systems

Scientific Reports volume 13, Article number: 5 (2023) Cite this article 1715 Accesses 2 Citations 1 Altmetric Metrics details A simple model is developed for the conductivity of polymeric systems

Scientific Reports volume 13, Article number: 5 (2023) Cite this article

1715 Accesses

2 Citations

1 Altmetric

Metrics details

A simple model is developed for the conductivity of polymeric systems including silver nanowires (AgNWs). This model reveals the effects of interphase thickness, tunneling distance, waviness and aspect ratio of nanowires, as well as effective filler volume fraction on the percolation and electrical conductivity of AgNW-reinforced samples. The validity of this model is tested by using the measured data from several samples. Based on this model, the conductivity calculations are in proper accordance with the measured values. A large network and a low percolation onset are produced by nanowires with a high aspect ratio developing the nanocomposite conductivity. The results also show that a thicker interphase expands the network, thereby increasing the electrical conductivity. Furthermore, non-waved AgNWs exhibit more conductivity compared to wavy nanowires. It is concluded that the surface energies of polymer medium and nanowires have no effect on the conductivity of samples. On the other hand, the volume fraction and aspect ratio of nanowires, in addition to the interphase thickness and tunneling distance have the greatest influences on the conductivity of nanocomposites.

Conventional polymer composites contain micrometer-sized particles of organic and inorganic fillers1. These materials require high filler content, which can increase the weight of the composite and limit its processing. In consequence, polymers containing high conductive nanofillers such as carbon nanomaterials (such as, carbon nanotubes, graphene and its derivatives) and metallic nanomaterials provide sufficiently conductive polymer nanocomposites (PNCs) at considerably lower nanofiller contents2,3. Researchers are exploring PNCs for new applications including biosensors, actuators, energy storage devices such as supercapacitors and batteries, EMI shielding, electrostatic dissipation (EDS), etc4,5,6.

An important property of polymer nanocomposites is their electrical conductivity (EC), which is extremely important for practical applications in electronic devices and sensors7,8,9. Carbon nanotubes and nanowires with high aspect ratios have received special attention as rod-like nanofillers in the fabrication of high conductive PNCs10,11. Recent researches have led to the development of metallic nano-materials that have unique electronic, optical, catalytic, magnetic, and thermal properties12,13. Owing to the big aspect ratio and superior electrical conductivity, metallic nanowires including copper, gold, nickel, and silver (AgNWs), introduce a major role in the current applications14,15. In recent years, AgNWs have attracted much more attention due to their good conductivity and easy to synthesis16,17,18,19.

AgNWs are one of the most desirable materials since bulk Ag has a high conductivity (6.3 × 107 S/m), which makes them applicable in sensing, electronics, electromagnetic interference (EMI) shielding20,21. Furthermore, AgNWs are more human friendly than other non-metallic conductive nanomaterials like carbon nanotubes because they possess antimicrobial properties22. Therefore, AgNWs are a promising candidate for the fabrication of conductive polymer/ AgNWs nanocomposites (PAgNWs)23,24. An attractive use of AgNW-based PNCs is the manufacture of electrochemical biosensors for the detection of breast cancer25. Electrochemical biosensors are a group of sensors that exhibit high sensitivity, fast response, and low manufacturing costs for detecting different types of biological agents and diseases such as diabetes26,27, cancer28, etc. Since breast cancer is one of the three most dangerous and deadly cancers in women, an early detection can be of great assistance to patients. Consequently, it is necessary to develop the rapid diagnostic devices such as biosensors that possess high sensitivity and selectivity29. AgNWs with their high electrical conductivity, antibacterial properties, and high specific surface area are excellent candidates for the manufacture of electrochemical biosensors based on polymer nanocomposites for cancer detection.

At a certain concentration of the conductive nanofiller, commonly known as the electrical percolation threshold, PNC conductivity increases dramatically30. At percolation concentration, nanofillers produce conductive network in the polymer matrix31. Several parameters affect the percolation threshold and electrical conductivity in PNCs, including aspect ratio and dispersion state of the nanofiller within the polymer matrix, wetting between polymer and nanofiller, interphase thickness, tunneling distance, waviness and agglomeration of nanowires, volume fraction of nanowires, and processing technique31.

The key mechanism responsible for PAgNW electrical conductivity is electron tunneling32. In other words, the tunneling distance directly impacts the transfer of charges through tunneling regions. Thus, during the electron tunneling process between nanowires, the tunneling size will affect the conductivity of final PNC. Additionally, the interphase regions formed in PNCs due to the rigid interface between polymer medium and nanofiller influence the electrical conductivity. The thickness of these regions, called the interphase thickness, affects the percolation and conductivity of PNCs33. As the interphase thickness increases, electrical conductivity increases as well34. The calculation of tunneling distance and interphase thickness is challenging in practice and in experiments. So, providing a computational model to estimate these parameters and finally calculate the electrical conductivity of the nanocomposite would be extremely useful and beneficial.

Numerous models have been developed to analyze the conductivity of PNCs. A common method of expressing conductivity is the power-law assuming percolation concept and filler concentration. It is not able to reflect the key features of PNCs such as interphase thickness, waviness, tunneling distance, and nanofiller aspect ratio35. Consequently, it is crucial to develop new models for electrical conductivity of PNCs that are capable of taking into account the key factors such as interphase regions, tunneling distance, nanofiller waviness, and aspect ratio.

In our previous article34, Kovacs model was developed by considering logical parameters for approximating of electrical conductivity in the AgNW-filled samples. We have investigated the effects of various parameters including volume fraction and dimensions of nanofiller, as well as interphase thickness and tunneling resistivity in the previous model. However, one problem was the estimating of tunneling resistivity in that model. In the present work, Taherian model is developed to estimate the electrical conductivity of AgNW-filled composites. Using this simple and applicable model, it is possible to examine the impacts of curliness, interphase thickness, aspect ratio, the volume fraction of nanowires, and tunneling size on the conductivity of AgNW composites. Using the experimented results from the literature, the proposed model is examined and interphase/tunneling parameters are calculated. More, the stimuli of factors on the conductivity of samples are studied. Authors hope that this model will be able to aid in calculating the electrical conductivity of PNCs. Most previous studies have calculated the electrical conductivity of AgNW nanocomposites using numerical methods. However, the previous models commonly disregarded the interphase depth and tunneling properties. Also, previous model cannot present the conductivity by a simple way. Actually, we present a simple model by meaningful and effective parameters controlling the conductivity of AgNW-filled composites.

For predicting the electrical conductivity of PNCs reinforced with conductive nanofillers, Taherian36 developed a mathematical model based on three key factors, including conductivity of filler, aspect ratio of particles, and wettability between medium and nanoparticle as follows:

“σm” and “σf” are the conductivity of the polymer and nanofiller, respectively, “α” displays the. aspect ratio of nanofiller, roundness depends on “α”, cos (β) represents the wettability between polymer and nanofiller, and “P” and “Q” are also changeable parameters. The electrical conductivity of the majority of polymers is very low. Therefore, there is no need to include the negligible level of “σm” in model. Consequently, Eq. (1) is modified as:

In an article published in 2008, authors offered a model for the conductivity of PNCs containing carbon nanotubes with a random distribution37 as:

"\(\emptyset_{f }\)" refers to the nanofiller volume fraction, and "f" refers to the portion of particles in the network. Therefore, "\(\emptyset_{f }\)" and "f" directly affect the conductivity. Thus, "P" parameter can be regarded as a function of "\(\emptyset_{f }\)" and "f" by comparing Eqs. (2 and 3). Here, we consider "\(\emptyset_{f }\)" and "f" by nonlinear functions and Eq. (2) is rewritten as:

In view of the fact that electrical conductivity is a nonlinear function of filler concentration, considering nonlinear "\(\emptyset_{f }\)" and "f" will be closer to reality and experimental data.

Typically, rod-like nanofillers have an aspect ratio (ɑ) of:

"l" and "d" represent the length and diameter of the nanofiller.

In addition, there is a percolation threshold for nanofillers with random dispersion38 as:

Nanoparticle volume is represented by "V" and "Vex" is an excluded volume as the volume around a particle that is not available to nearby particles. "V" and "Vex" in PNCs containing tubular fillers with accidental dispersion are expressed38 as:

Using an interphase layer, PNCs can form large networks. There is the following alteration in the excluded volume as a result of the interphase part:

“t” represents interphase thickness. The interphase zone is created around the nanowires and has a lower conductivity than nanowires. So, it can transfer the electrons properly.

Further, big rod-like nanofillers cause the waviness that reduces their conductivity. Therefore, for the purpose of calculating the conductivity based on the waviness parameter (u), the equivalent length (leq) needs to be defined34 as follows:

Nanofiller will have no waviness if u = 1, but if u > 1, it will have more waviness. By considering "leq" as the effective length of nanofillers with high waviness (leq = l/u), "Vex" is changed to:

Percolation threshold of nanofillers can be expressed as follows by including waviness and interphase thickness in “Vex” formulation:

AgNWs and the surrounding interphase constitute the effective volume fraction of the filler as follows:

∅ i refers to the volume fraction of the interphase areas, which is given as follows:

The volume fraction of interphase is calculated as:

By placing the Eq. (14) into Eq. (13), “∅ eff” is expressed as:

The conductive networks are produced by only a portion of nanofillers once they reach the percolation threshold, while the remaining nanowires are dispersed throughout the medium. The part of percolated nanowires is considered as follows:

The formula for calculating the fraction of networked nanowires is written as follows by considering “∅ eff” instead of “∅ f” in the above equation:

Furthermore, the conductivity of wavy filler is also defined34 as:

Ryvkina et al39. offered a mathematical model for PNCs that emphasizes the electron tunneling mechanism as the dominant mechanism in the conduction of PNCs as:

In this expression, “A” refers to a characteristic tunnel distance, and “\({\uplambda }\)” refers to the tunneling distance between nanofillers. The tunneling distance determines the distance between neighboring AgNWs and when is less than 10 nm, it can transfer the electrons and cause the conductivity. Our previous work34 showed that the electrical conductivity of PNCs containing AgNWs is inversely proportional to the \({\uplambda }\). In this way, "Q" parameter in Eq. (4) may represent the tunneling distance between nearby nanofillers in PNCs. The "Q" parameter is equal to "\({ }\frac{{{\uplambda }^{2} }}{{z^{2} }}\) ". Therefore, Eq. (4) is rewritten as follows:

where z = 1 nm as a tunneling factor. In other words, "d" in this equation has nm unit.

In addition, the "roundness" factor was suggested by Taherian36. In other words, the roundness increases with a decrease in the aspect ratio of nanofiller. The roundness is measured between 0 and 1. For roundness, Zare et al35. have provided the following equation:

The role of wetting in electrical conductivity by cos (β) has been proposed by Taherian36 as follows:

“\(\gamma_{f}\), “\(\gamma_{p}\)”, and “\(\gamma_{fp}\)” represent the surface energies of nanofiller, polymer, and filler/polymer interphase, respectively, and "β" denotes the wetting angle. Additionally, “\(\gamma_{fp}\)” can be defined using the surface energies as follows:

Equation (20) can be rewritten as follows by substituting Eqs. (21) and (22):

In Fig. 1, the effects of “\(\gamma_{f}\) and “\(\gamma_{p}\)” on the electrical conductivity of PNCs are illustrated. Polymers have a surface energy of 20–50 mJ/m240 and AgNWs have a surface energy of 1000–1500 mJ/m241. Figure 1 shows that the electrical conductivity of the PNC insignificantly changes at these intervals. Accordingly, \({\text{exp}}\left( { - \frac{{\frac{1000 - \upalpha }{{1000}}}}{{\frac{{\gamma_{f} - \gamma_{fp} }}{{\gamma_{p} }}}}} \right)\) term in Eq. (24) can be ignored. Hence, Eq. (24) is rewritten as follows:

The effects of “\({\varvec{\gamma}}_{{\varvec{f}}}\) and “\({\varvec{\gamma}}_{{\varvec{p}}}\)” on the electrical conductivity of a PNC by (a) 3D and (b) contour plots.

Equation 25 offers a simple and beneficial model for estimating of conductivity in the PNCs containing AgNWs. In the present model, the effects of various factors such as aspect ratio, volume portion, and conductivity of nanowires, as well as tunneling length and interphase depth have been reflected.

Experimental data from the literature are utilized to prove the rationality of the proposed model. Experimented results and outputs of the offered model are shown in Fig. 2 for polyimide/AgNWs (PI/AgNWs) nanocomposite (d = 250 nm, l = 50 μm, u ≈ 1.45)42, poly (ether ketone ketone) (PEKK)/AgNWs sample (d = 260 nm, l = 55 μm, u ≈ 1.65)43, poly (lactic acid)/silver nanowire (PLA/AgNWs) nanocomposite (d = 250 nm, l = 50 μm, u ≈ 1.6)23, and poly(methyl methacrylate)/silver nanowire sample (PMMA/AgNWs) nanocomposite (d = 15 nm, l = 2.7 μm, u ≈ 1.9)44. We obtained the dimensions (d and l) of nanowires for these samples from references23,42,43,44. In Fig. 2, experimented conductivity displays good agreement with the proposed model. As a result, the proposed model is an ideal equation for estimating the conductivity in the real-world applications.

Experimental and theoretical conductivities for (a) PI/AgNWs42, (b) PEKK/AgNWs43, (c) PLA/AgNWs23 , and (d) PMMA/AgNWs44 samples at different nanofiller concentrations based on the proposed model.

Two key parameters in nanocomposites that affect the electrical conductivity are the interphase thickness and the tunneling distance for electron transfer. Comparing measured data to the forecasts of the proposed model can determine the average values of these parameters. According to the experimental results, \(\hbox{``}\emptyset_{p} {^{\prime\prime}}\) was reported as 0.0049 for the PI/AgNWs42, 0.0059 for PEKK/AgNWs43, 0.0059 for PLA/AgNWs23, and 0.008 for PMMA/AgNWs44. By applying the experimental values of percolation threshold to Eq. (12), we can calculate the value of “t” and “λ” (t, λ). By comparing the experimental conductivity values with those of the offered model, the values of (t, λ) are found as (5 nm, 1.1 nm), (7 nm, 7.5 nm), (6 nm, 7.5 nm), and (1.5 nm, 4 nm) for the PI/AgNWs42, PEKK/AgNWs43, PLA/AgNWs23, and PMMA/AgNWs44 nanocomposites, respectively. Actually, numerous levels for “t” and “λ” are calculated by fitting the measured percolation onset to Eq. (12), but we report the average ones. However, interphase depth should be shorter than the gyration radius of macromolecules and tunneling distance should be lower than 10 nm to encourage the electron transferring. All calculations for interphase depth and tunneling distance fall within the suitable ranges confirming the perditions. Consequently, this model can be used to calculate the interphase thickness and tunneling distance in PNCs. Furthermore, the values of “t” and λ"” obtained by this model are almost identical for two nanocomposites with the same percolation thresholds. Therefore, it is evident that the proposed model is highly accurate.

The offered model is used to investigate how different parameters handle the percolation onset and nanocomposite conductivity. This assessment determines the predictability of the offered model plus the effects of the factors on the electrical conductivity of PNCs. Calculating of electrical conductivity has been done by taking the average of the following parameters: u = 1.4, l = 50 µm, t = 5 nm, d = 200 nm, λ = 2 nm, ∅f = 0.01, and σf = 6 × 107 S/m.

Figure 3 illustrates the impresses of “f” and “λ” on the conductivity of PNCs. The conductivity reaches its maximum (1300 S/m) when λ = 1 nm and f = 0.7. We also observe that the conductivity is about 0 at λ > 3.5 nm or f < 0.37. As a result, increases in “f” value in a small tunneling distance between nanowires lead to an improved electrical conductivity of the final PNC. Alternatively, low conductivity is observed when a large number of nanowires cannot participate in the conductive networks and nanowires are far apart. Literature studies have shown that once percolation is achieved, the percentage of networked nanofillers and the tunneling distance between fillers influence the conductivity significantly45,46.

The impacts of “f” and “λ” on the electrical conductivity of PNCs by (a) 3D and (b) contour plots.

Electrical conductivity increases with increasing the network dimensions, whereas electrical conductivity decreases with smaller networks. Therefore, the value of “f” directly correlates with the electrical conductivity. In addition, our previous work34 identified a direct influence of network dimension on the conductivity of PNCs, which supports the accuracy of offered model for the calculation of electrical conductivity in PNCs. Additionally, the tunneling effect is a probabilistic phenomenon heavily influenced by the distance between any neighboring nanowire pair47. Percolation occurs when electrical links are formed between nanofillers that are physically separated, thereby forming conductive networks45. A mechanism of electron tunneling is believed to determine the conductivity. In fact, electrons transfer between nanofillers through electron tunneling45. The tunneling distance determines the distance between adjacent AgNWs and can transfer the electrons when it is less than 10 nm. Because of van der Waals interactions, nanofillers cannot physically contact each other. Thus, they remain separated by an energy barrier of a nanometer gap, where electron tunneling may occur when the distance between two nanofillers is less than the threshold cutoff distance47,48. There have been several studies indicating a tunneling cutoff distance of about 1.4 nm49,50. In addition, numerous reports confirm that electrical conductivity is inversely related to tunneling distance51,52,53. Also, as shown in Eq. (25), conductivity is inversely related to tunneling distance. Therefore, the offered model correctly guesses the effect of tunneling distance on the nanocomposite conductivity.

Figure 4 shows the impressions of “∅f” and “α” on the conductivity of PNCs. Electrical conductivity is maximized as 305 S/m at ∅f = 0.02 and α > 820. In contrast, at ∅f < 0.014, the minimum value of conductivity is observed and nanocomposite is insulated. Nanowires with a higher aspect ratio and higher volume fraction will cause an improved electrical conductivity, while a lower aspect ratio and smaller volume fraction of nanowires can result in a reduction in the conductivity.

The stimuli of “∅f” and “α” on the electrical conductivity of PNCs by (a) 3D and (b) contour plots.

The nanowires in the polymer matrix begin to form conductive networks after passing the percolation threshold. When nanowire concentrations are below the percolation levels, conductive networks cannot be formed. Therefore, electron tunneling is not possible. In filler concentrations above the percolation threshold, a fraction of nanowires creates the conductive networks with specific dimensions that assist to electron transfer and thus increase the conductivity. Furthermore, increasing the aspect ratio of nanowires improves the electrical conductivity. In other words, the smaller the diameter and the longer the length of the nanowires, the easier the formation of conductive networks in the polymer matrix, thus allowing percolation to take place at lower volume fractions of the nanowires, which improve the electrical conductivity. Moreover, literature studies indicate that higher aspect ratio of conductive particles provides higher electrical conductivity for nanocomposites54,55. The level of conductivity above the percolation threshold is equivalent for all kind of particle with same nature of material. A lower percolation threshold shifts the percolation curve to lower amount of fillers and the same level of conductivity is obtained with a lower content of nanowires.

Therefore, the proposed model accurately predicts the relationship between the aspect ratio and the electrical conductivity of nanocomposites.

Figure 5 displays the impacts of the radius and length of nanowires on the conductivity. Based on this plot, it is seen that the electrical conductivity is inversely proportional to the radius (or diameter) of the nanowires and directly proportional to their length. A maximum conductivity of 12 S/m is obtained for PNCs with l = 70 μm and R = 70 nm. However, the PNC is a complete insulator at l < 24 μm and all radii of nanowires.

The influences of “R” and “l” on the electrical conductivity of PNCs by (a) 3D and (b) contour plots.

Nanowires with a smaller radius and a bigger length have a greater aspect ratio. At higher aspect ratios of nanowires, conductive networks are easier to form56. Consequently, electrical percolation takes place at a lower volume fraction of nanowires. Furthermore, the dimensions of the conductive networks become larger at higher aspect ratios, and electrons can easily tunnel through the nanowires, thus growing the conductivity. On the other hand, nanowires with a larger radius and shorter length cause a lower conductivity for the PNC, because the aspect ratio decreases and conductive networks are difficult to form.

The effects of nanowire conductivity and the thickness of interphase on the electrical conductivity of PNCs are also illustrated in Fig. 6. It is illustrated that the electrical conductivity of nanocomposite reaches 110 S/m at t = 50 nm and σf = 9 × 107 S/m, while at t < 21 nm, the nanocomposite is insulated. It can be observed that the electrical conductivity of PNCs is directly related to the conductivity of nanowires and the thickness of produced interphase. As a result, the higher the conductivity of the nanowires and the thicker the interphase lead to an improvement in the conductivity of nanocomposite. In contrast, the low electrical conductivity of nanowires and thin interphases can insulate the final nanocomposite.

The influences of “t” and “σf” on the electrical conductivity of PNCs by (a) 3D and (b) contour plots.

The formation of conductive networks in nanocomposites is facilitated by increasing the interphase thickness around nanowires. The interphase zone around the nanowires is conductive causing the electron transferring. Therefore, electrons can transfer more easily between nanowires, and the electrical conductivity is improved. In addition, according to Eq. (15), a thicker interphase produces a higher effective volume fraction of nanowires, which directly affects the electrical conductivity of nanocomposite. Additionally, since polymer matrices have low electrical conductivity and are generally insulating, it is primarily for the conductivity of nanowires that controls the conductivity of PNCs. The conductivity of PNCs is improved by increasing nanowire conductivity, and the maximum conductivity is attained by adding more conductive nanowires. A major reason for this can be seen in the tremendous differences in the electrical conductivity of polymers and nanofillers36,57, which demonstrate the importance of nanowire conductivity to the electrical conductivity of nanocomposite. Therefore, the suggested model indicates that nanowire conductivity largely affects the conductivity of nanocomposites.

Conductivity calculations are shown in Fig. 7 based on “∅ p” and “u”. The nanocomposite has a maximum conductivity of 20 S/m at ∅ p = 0.001 and u = 1. Additionally, at ∅ p > 0.003, the conductivity is 0. Hence, a low percolation threshold and small waviness of nanowires make the nanocomposites more conductive and these parameters differently affect the conductivity.

Electrical conductivity of a PNC by “∅ p” and “u”: (a) 3D and (b) contour plots.

Percolation volume fraction causes the formation of conductive networks in the systems. The electrical conductivity of the nanocomposite is negatively related to the percolation threshold, since it is well known that a low percolation threshold increases the network percentage (Eq. 17), which increases the electrical conductivity. Literature researches also indicated that a lower percolation threshold causes more conductivity at lower amount of nanoparticles58. Therefore, it is reasonable to mention that there is a reverse relationship among conductivity and percolation onset, as offered by the current model. Furthermore, nanowires that are not wavy increase the electrical conductivity of nanocomposites, because a lower range of "u" shows more straight nanowires in PNC increasing the effective length of nanowires. Straight nanowires reach the smallest percolation threshold, which increases the dimensions of networks and conductivity of PNCs59. Hence, “u” adversely handles the conductivity of PNCs, as stated by the advanced model.

An applicable model for the conductivity of AgNW-filled nanocomposites was derived using several key factors including nanowire volume fraction, aspect ratio, percolation threshold, interphase size, tunneling distance, filler waviness and nanowire conductivity. Experimental results confirmed the predictions of the offered model. Furthermore, the effects of dissimilar factors on the electrical conductivity of the nanocomposite were investigated. The mathematical studies indicated that the superficial energies of medium and silver nanowires did not affect the electrical conductivity of PNCs. Therefore, these terms were not taken into account in the proposed model. A minimum conductivity is observed at λ > 3.5 nm or f < 0.37, demonstrating that a lower network percentage and a bigger tunneling distance result in a reduction in the conductivity of nanocomposite. In addition, a maximum electrical conductivity of 305 S/m was shown at ∅f = 0.02 and α > 820, indicating that the aspect ratio and volume fraction of the nanowires directly affect the conductivity. Besides, a low percolation threshold and small curvature of nanowires produce a higher conductivity, but a higher percolation threshold than 0.003 causes an insulated sample. Conclusively, a higher volume fraction of nanowires, longer and more-straight nanowires, thicker interphase, and a smaller tunneling distance will lead to higher improvement in the conductivity of PNCs.

The data that support the findings of this study are available on request from the corresponding author.

Ilyas, R. A. et al. Polymer composites filled with metal derivatives: A review of flame retardants. Polymers 13, 1701 (2021).

Article Google Scholar

Gooneh-Farahani, S., Naghib, S. M., Naimi-Jamal, M. R. & Seyfoori, A. A pH-sensitive nanocarrier based on BSA-stabilized graphene-chitosan nanocomposite for sustained and prolonged release of anticancer agents. Sci. Rep. 11, 1–14 (2021).

Article Google Scholar

Gupta, S. et al. Nanohybrid-based immunosensor prepared for helicobacter pylori BabA antigen detection through immobilized antibody assembly with@ Pdnano/rGO/PEDOT sensing platform. Sci. Rep. 10, 1–14 (2020).

Article ADS Google Scholar

German, N., Ramanaviciene, A. & Ramanavicius, A. Dispersed conducting polymer nanocomposites with glucose oxidase and gold nanoparticles for the design of enzymatic glucose biosensors. Polymers 13, 2173 (2021).

Article Google Scholar

Anderson, L., Govindaraj, P., Ang, A., Mirabedini, A. & Hameed, N. Modelling, fabrication and characterization of graphene/polymer nanocomposites for electromagnetic interference shielding applications. Carbon Trends 4, 100047 (2021).

Article Google Scholar

Nie, N. et al. The Application of Polymer Nanocomposites in Energy Storage Devices. Polymer Nanocomposite Materials: Applications in Integrated Electronic Devices. 157–187 (2021).

Sharma, S., Sudhakara, P., Omran, A. A. B., Singh, J. & Ilyas, R. A. Recent trends and developments in conducting polymer nanocomposites for multifunctional applications. Polymers 13, 2898 (2021).

Article Google Scholar

Bera, M. & Maji, P. K. Graphene-based polymer nanocomposites: Materials for future revolution. MOJ Poly. Sci. 1, 13 (2017).

Google Scholar

Idumah, C. I. & Obele, C. M. Understanding interfacial influence on properties of polymer nanocomposites. Surf. Interfaces 22, 100879 (2021).

Article Google Scholar

Tang, J., Sun, H., Li, X., Liang, F. & Jiang, T. Chemical-etched silver nanowires with tunable rough shape for surface enhanced Raman scattering. Colloids Surf. A 630, 127521 (2021).

Article Google Scholar

Lin, S., Zou, C., Liang, H., Peng, H. & Liao, Y. The effective removal of nickel ions from aqueous solution onto magnetic multi-walled carbon nanotubes modified by $β$-cyclodextrin. Colloids Surf. A 619, 126544 (2021).

Article Google Scholar

Dikshit, P. K. et al. Green synthesis of metallic nanoparticles: Applications and limitations. Catalysts 11, 902 (2021).

Article Google Scholar

Saravanan, A. et al. A review on biosynthesis of metal nanoparticles and its environmental applications. Chemosphere 264, 128580 (2021).

Article ADS Google Scholar

Song, J. Y., Oh, J. H., Choi, D. & Park, S. M. Highly efficient patterning technique for silver nanowire electrodes by electrospray deposition and its application to self-powered triboelectric tactile sensor. Sci. Rep. 11, 1–12 (2021).

Article ADS Google Scholar

Hwang, J. S. et al. Recycling silver nanoparticle debris from laser ablation of silver nanowire in liquid media toward minimum material waste. Sci. Rep. 11, 1–11 (2021).

Google Scholar

Kim, A., Won, Y., Woo, K., Jeong, S. & Moon, J. All-solution-processed indium-free transparent composite electrodes based on Ag nanowire and metal oxide for thin-film solar cells. Adv. Func. Mater. 24, 2462–2471 (2014).

Article Google Scholar

Shi, Y. et al. Synthesis and applications of silver nanowires for transparent conductive films. Micromachines 10, 330 (2019).

Article Google Scholar

Jones, R. S., Draheim, R. R. & Roldo, M. Silver nanowires: Synthesis, antibacterial activity and biomedical applications. Appl. Sci. 8, 673 (2018).

Article Google Scholar

Zhang, P. et al. Silver nanowires: Synthesis technologies, growth mechanism and multifunctional applications. Mater. Sci. Eng. B 223, 1–23 (2017).

Article Google Scholar

Zhang, Z., Wang, H., Li, S., Li, L. & Li, D. Transparent and flexible cellulose nanofibers/silver nanowires/acrylic resin composite electrode. Compos. A Appl. Sci. Manuf. 76, 309–315 (2015).

Article Google Scholar

Yoon, Y., Hall, A. S. & Surendranath, Y. Tuning of silver catalyst mesostructure promotes selective carbon dioxide conversion into fuels. Angew. Chem. Int. Ed. 55, 15282–15286 (2016).

Article Google Scholar

Yerli-Soylu, N. et al. TiO2 nanocomposite ceramics doped with silver nanoparticles for the photocatalytic degradation of methylene blue and antibacterial activity against Escherichia coli. Eng. Sci. Technol. Int. J. 35, 101175 (2022).

Google Scholar

Fallahi, H., Azizi, H., Ghasemi, I. & Karrabi, M. Preparation and properties of electrically conductive, flexible and transparent silver nanowire/poly (lactic acid) nanocomposites. Org. Electron. 44, 74–84 (2017).

Article Google Scholar

Xu, F. & Zhu, Y. Highly conductive and stretchable silver nanowire conductors. Adv. Mater. 24, 5117–5122 (2012).

Article Google Scholar

Hasanzadeh, M. et al. Ultrasensitive immunoassay of breast cancer type 1 susceptibility protein (BRCA1) using poly (dopamine-beta cyclodextrine-Cetyl trimethylammonium bromide) doped with silver nanoparticles: A new platform in early stage diagnosis of breast cancer and effici. Microchem. J. 145, 778–783 (2019).

Article Google Scholar

Mohammadpour-Haratbar, A., Mazinani, S., Sharif, F. & Bazargan, A. M. Improving nonenzymatic biosensing performance of electrospun carbon nanofibers decorated with Ni/Co particles via oxidation. Appl. Biochem. Biotechnol. 194, 1–23 (2022).

Article Google Scholar

Mohammadpour-Haratbar, A., Mosallanejad, B., Zare, Y., Rhee, K. Y. & Park, S.-J. Co3O4 nanoparticles embedded in electrospun carbon nanofibers as free-standing nanocomposite electrodes as highly sensitive enzyme-free glucose biosensors. Rev. Adv. Mater. Sci. 61, 744–755 (2022).

Article Google Scholar

Mohammadpour-Haratbar, A., Zare, Y. & Rhee, K. Y. Electrochemical biosensors based on polymer nanocomposites for detecting breast cancer: Recent progress and future prospects. Adv. Colloid Interface Sci. 309, 102795 (2022).

Article Google Scholar

Wang, W., Han, R., Chen, M. & Luo, X. Antifouling peptide hydrogel based electrochemical biosensors for highly sensitive detection of cancer biomarker HER2 in human serum. Anal. Chem. 93, 7355–7361 (2021).

Article Google Scholar

Krukiewicz, K. et al. Electrical percolation in extrinsically conducting, poly ($\varepsilon$-decalactone) composite neural interface materials. Sci. Rep. 11, 1–10 (2021).

Article Google Scholar

Zare, Y. & Rhee, K. Y. Formulation of tunneling resistance between neighboring carbon nanotubes in polymer nanocomposites. Eng. Sci. Technol. Int. J. 24, 605–610 (2021).

Google Scholar

Carvalho Fernandes, D. C., Lynch, D. & Berry, V. 3D-printed graphene/polymer structures for electron-tunneling based devices. Sci. Rep. 10, 1–8 (2020).

Article Google Scholar

Zare, Y., Rhee, K. Y. & Park, S.-J. An applicable model for the modulus of polymer halloysite nanotubes samples by the characteristics of halloysite nanotubes, interphase zone and filler/interphase network. Colloids Surf. A 628, 127330 (2021).

Article Google Scholar

Mohammadpour-Haratbar, A., Zare, Y. & Rhee, K. Y. Development of a theoretical model for estimating the electrical conductivity of a polymeric system reinforced with silver nanowires applicable for the biosensing of breast cancer cells. J. Market. Res. 18, 4894–4902 (2022).

Google Scholar

Zare, Y., Mišković-Stanković, V. & Rhee, K. Y. Effects of interphase regions and tunneling distance on the electrical conductivity of polymer carbon nanotubes nanocomposites. Carbon Lett. 29, 567–577 (2019).

Article Google Scholar

Taherian, R. Experimental and analytical model for the electrical conductivity of polymer-based nanocomposites. Compos. Sci. Technol. 123, 17–31 (2016).

Article Google Scholar

Deng, F. & Zheng, Q.-S. An analytical model of effective electrical conductivity of carbon nanotube composites. Appl. Phys. Lett. 92, 71902 (2008).

Article Google Scholar

Mutiso, R. M. & Winey, K. I. Electrical properties of polymer nanocomposites containing rod-like nanofillers. Prog. Polym. Sci. 40, 63–84 (2015).

Article Google Scholar

theoretical modeling and experimental results. Ryvkina, N., Tchmutin, I., Vilčáková, J., Pel\’\išková, M. & Sáha, P. The deformation behavior of conductivity in composites where charge carrier transport is by tunneling. Synth. Met. 148, 141–146 (2005).

Article Google Scholar

Tsibouklis, J. & Nevell, T. G. Ultra-low surface energy polymers: The molecular design requirements. Adv. Mater. 15, 647–650 (2003).

Article Google Scholar

Medasani, B., Park, Y. H. & Vasiliev, I. Theoretical study of the surface energy, stress, and lattice contraction of silver nanoparticles. Phys. Rev. B 75, 235436 (2007).

Article ADS Google Scholar

Nguyen, T. H. L., Cortes, L. Q., Lonjon, A., Dantras, E. & Lacabanne, C. High conductive Ag nanowire–polyimide composites: Charge transport mechanism in thermoplastic thermostable materials. J. Non-Cryst. Solids 385, 34–39 (2014).

Article ADS Google Scholar

Cortes, L. Q., Lonjon, A., Dantras, E. & Lacabanne, C. High-performance thermoplastic composites poly (ether ketone ketone)/silver nanowires: Morphological, mechanical and electrical properties. J. Non-Cryst. Solids 391, 106–111 (2014).

Article ADS Google Scholar

Zeraati, A. S., Arjmand, M. & Sundararaj, U. Silver nanowire/MnO2 nanowire hybrid polymer nanocomposites: Materials with high dielectric permittivity and low dielectric loss. ACS Appl. Mater. Interfaces 9, 14328–14336 (2017).

Article Google Scholar

Chanda, A., Sinha, S. K. & Datla, N. V. Electrical conductivity of random and aligned nanocomposites: Theoretical models and experimental validation. Compos. A Appl. Sci. Manuf. 149, 106543 (2021).

Article Google Scholar

Pal, G. & Kumar, S. Multiscale modeling of effective electrical conductivity of short carbon fiber-carbon nanotube-polymer matrix hybrid composites. Mater. Des. 89, 129–136 (2016).

Article Google Scholar

Doh, J., Park, S.-I., Yang, Q. & Raghavan, N. The effect of carbon nanotube chirality on the electrical conductivity of polymer nanocomposites considering tunneling resistance. Nanotechnology 30, 465701 (2019).

Article Google Scholar

Hu, N., Karube, Y., Yan, C., Masuda, Z. & Fukunaga, H. Tunneling effect in a polymer/carbon nanotube nanocomposite strain sensor. Acta Mater. 56, 2929–2936 (2008).

Article ADS Google Scholar

Bao, W. S., Meguid, S. A., Zhu, Z. H. & Weng, G. J. Tunneling resistance and its effect on the electrical conductivity of carbon nanotube nanocomposites. J. Appl. Phys. 111, 93726 (2012).

Article Google Scholar

Fang, C., Zhang, J., Chen, X. & Weng, G. J. A Monte Carlo model with equipotential approximation and tunneling resistance for the electrical conductivity of carbon nanotube polymer composites. Carbon 146, 125–138 (2019).

Article Google Scholar

Payandehpeyman, J., Mazaheri, M. & Khamehchi, M. Prediction of electrical conductivity of polymer-graphene nanocomposites by developing an analytical model considering interphase, tunneling and geometry effects. Compos. Commun. 21, 100364 (2020).

Article Google Scholar

Ambrosetti, G. et al. Solution of the tunneling-percolation problem in the nanocomposite regime. Phys. Rev. B 81, 155434 (2010).

Article ADS Google Scholar

Maiti, S., Suin, S., Shrivastava, N. K. & Khatua, B. B. Low percolation threshold in polycarbonate/multiwalled carbon nanotubes nanocomposites through melt blending with poly (butylene terephthalate). J. Appl. Polym. Sci. 130, 543–553 (2013).

Article Google Scholar

Chen, J. & Yan, L. Effect of carbon nanotube aspect ratio on the thermal and electrical properties of epoxy nanocomposites. Fuller. Nanotub. Carbon Nanostruct. 26, 697–704 (2018).

Article ADS Google Scholar

Qian, J. et al. Effect of aspect ratio of multi-wall carbon nanotubes on the dispersion in ethylene-$α$-octene block copolymer and the properties of the nanocomposites. J. Polym. Res. 26, 1–11 (2019).

Article Google Scholar

Li, J. et al. Correlations between percolation threshold, dispersion state, and aspect ratio of carbon nanotubes. Adv. Func. Mater. 17, 3207–3215 (2007).

Article Google Scholar

Thabet, A., Mubarak, Y. A. & Bakry, M. A review of nano-fillers effects on industrial polymers and their characteristics. J. Eng. Sci 39, 377–403 (2011).

Google Scholar

Gao, C. et al. Graphene networks with low percolation threshold in ABS nanocomposites: Selective localization and electrical and rheological properties. ACS Appl. Mater. Interfaces 6, 12252–12260 (2014).

Article Google Scholar

Li, C., Thostenson, E. T. & Chou, T.-W. Effect of nanotube waviness on the electrical conductivity of carbon nanotube-based composites. Compos. Sci. Technol. 68, 1445–1452 (2008).

Article Google Scholar

Download references

This work was supported by the Basic Science Research Program through the National Research Foundation of Korea (NRF) funded by the Ministry of Education, Science and Technology (2022R1A2C1004437). It was also supported by the Korea government (MSIT) (2022M3J7A1062940).

Biomaterials and Tissue Engineering Research Group, Department of Interdisciplinary Technologies, Breast Cancer Research Center, Motamed Cancer Institute, ACECR, Tehran, Iran

Ali Mohammadpour-Haratbar & Yasser Zare

Department of Mechanical Engineering (BK21 Four), College of Engineering, Kyung Hee University, Yongin, Republic of Korea

Kyong Yop Rhee

You can also search for this author in PubMed Google Scholar

You can also search for this author in PubMed Google Scholar

You can also search for this author in PubMed Google Scholar

A.M. and Y.Z. wrote the main manuscript text. K.Y.R. revised the text. All authors reviewed the manuscript.

Correspondence to Yasser Zare or Kyong Yop Rhee.

The authors declare no competing interests.

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit

Reprints and Permissions

Mohammadpour-Haratbar, A., Zare, Y. & Rhee, K.Y. Simulation of electrical conductivity for polymer silver nanowires systems. Sci Rep 13, 5 (2023).

Download citation

Received: 27 July 2022

Accepted: 30 November 2022

Published: 02 January 2023


Anyone you share the following link with will be able to read this content:

Sorry, a shareable link is not currently available for this article.

Provided by the Springer Nature SharedIt content-sharing initiative

Scientific Reports (2023)

By submitting a comment you agree to abide by our Terms and Community Guidelines. If you find something abusive or that does not comply with our terms or guidelines please flag it as inappropriate.