Morphological, dielectric, tunable electromagnetic interference shielding and thermal characteristics of multiwalled carbon nanotube incorporated polymer nanocomposites: A facile, environmentally benign and cost effective approach realized via polymer latex/waterborne polymer as matrix

George, Gejo; Simon, Sanu Mathew; Prakashan, V.P.; Sajna, M.S.; Faisal, Muhammad; Chandran, Anoop; Wilson, Runcy; Biju, P.R.; Joseph, Cyriac; Unnikrishnan, N. V.

doi:10.1002/pc.24689

Cited by 14 publications

(5 citation statements)

References 70 publications

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“…This indicated that the nanocomposites exhibited almost similar EMI-SE in both the X-band and K u -band and there is a negligible variation with varying frequency. This is similar to the results reported by George et al [67] for the polypropylene (PP)/MWCNT nanocomposites prepared by the solution method followed by hot pressing. However, in contrast to the PES/MWCNT (which showed 29-30 dB) nanocomposites, the PP/MWCNT showed a total EMI-SE of about 25 dB for the 10 wt% MWCNT nanocomposite.…”

Section: Electromagnetic Interference-shielding Effectiveness (Emi-se)supporting

confidence: 91%

“…Abbas et al [27] reported an EMI-SE of 35 dB (in the X-band) for 20 wt% MWCNT filled Poly(ether-sulfone) (PES) nanocomposites (thickness = 0.5 mm) fabricated by the solution method. Similarly, George et al [28] reported an EMI-SE of ∼47 dB (in the X-band) for the 2 mm thick PP/MWCNT composite fabricated by the solution method followed by hot pressing. The functionalization of the CNTs can also increase the EMI-SE compared to CNTs without functionalization.…”

Section: Introductionmentioning

confidence: 78%

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High electromagnetic interference shielding of poly(ether-sulfone)/multi-walled carbon nanotube nanocomposites fabricated by an eco-friendly route

Verma¹,

Rathod²,

Goyal

2020

Nanotechnology

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High-performance polymer matrix nanocomposites based on poly(ether-sulfone) (PES) matrix reinforced with multi-walled carbon nanotubes (MWCNTs) were fabricated using planetary ball mill followed by hot pressing. Their electrical properties and the electromagnetic interference shielding effectiveness (EMI-SE) were investigated and discussed. A percolation threshold of about 0.65 vol% MWCNT was obtained. The electrical conductivity was increased by more than ten orders of magnitude at the percolation threshold and to approximately 0.01 S cm −1 at 6.67 vol% (or 10 wt%) MWCNT. This is a significant improvement. The highest EMI-SE of about 29-30 dB (both in the X-band and K u -band) was obtained for the 6.67 vol% MWCNT filled nanocomposites with a thickness of 0.9 mm. The specific EMI-SE of these nanocomposites were found to be higher than the literature values. The thermal stability and the char yield (measured at 900 • C) of the nanocomposites were found to be more than 470 • C and 40.6%, respectively.

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Section: Electromagnetic Interference-shielding Effectiveness (Emi-se)supporting

confidence: 91%

Section: Introductionmentioning

confidence: 78%

High electromagnetic interference shielding of poly(ether-sulfone)/multi-walled carbon nanotube nanocomposites fabricated by an eco-friendly route

Verma¹,

Rathod²,

Goyal

2020

Nanotechnology

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“…In order to further illustrate the utility and advancement of in‐situ synthesized rGO/mC‐A, the comparison of the dielectric constants and EMI SE performance of our results and previously reported values are shown in Figure 5. As a result, Figure 5E, F demonstrate the superiority of in‐situ synthesized rGO/mC‐A with in terms of relatively high dielectric constants and EMI SE values at low addition of rGO, compared to other systems, such as CNT/Epoxy, [ 40 ] MWCNTs/Epoxy, [ 41 ] MWCNT/PS, [ 42 ] MWCNT/PP, [ 43 ] TGO/SCI/Epoxy, [ 44 ] Graphene/Epoxy, [ 45 ] GNPs/Epoxy, [ 46 ] rGM/Epoxy, [ 47 ] GNPs/Epoxy, [ 48 ] Graphene/PU, [ 49 ] Graphene/TPU, [ 50 ] at 8.2–12.4 GHz.…”

Section: Resultsmentioning

confidence: 97%

Improved dispersion of reduced graphene oxide in benzoxazine composites via electrostatic interaction with M‐cresol

Wang

et al. 2023

Polymer Composites

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Reduced graphene oxide (rGO) exerts excellent performance in polymers, but suffers from poor dispersion. Here, the electrostatic interaction between the phenolic hydroxyl group of m‐cresol and rGO was discovered for the first time, and benzoxazine with m‐cresol containing rGO as the phenolic source were synthesized to achieve a more uniform dispersion of rGO in benzoxazine. The results show that the in situ synthesized rGO/benzoxazine system exhibited superior properties, including a lower curing reaction temperature (21°C relative reductions in curing temperature (225.7°C) for the system with 2 wt% rGO added in situ), higher dielectric constant ((8.69) relative improvement of 0.79), higher electromagnetic shielding value at 8.2–12.4 GHz ((7.45 dB) relative improvement of 0.75 dB), and higher thermal diffusivity at room temperature ((0.162 mm2/s) relative improvement of 26%). This study provides a method to homogeneously disperse rGO in benzoxazine without using of a solvent or any other treatment.

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“…An important problem in the synthesis scheme of PCCCM considered above is to ensure close interaction of the modifying additive nanoparticles with the initial polyvinyl chloride molecules (or aggregates of molecules). This problem is of interest, per se; it is considered in many studies where PVC modification by carbon NC is used to render antistatic or shielding properties to NC/PVC composite materials [ 32 , 33 , 34 , 35 , 36 , 37 , 38 , 39 ], to improve thermal or electrophysical properties [ 39 , 40 , 41 , 42 , 43 , 44 ], and to apply such materials in energy storage devices [ 41 , 42 ], chemical sensors [ 41 , 42 ] and microelectronics [ 39 , 44 ]. A uniform distribution of carbon nanoparticles in PVC melt or its solutions in organic solvents is obtained using ultrasonic treatment [ 33 , 40 , 41 , 42 , 44 , 45 ], preliminary surface functionalization of the modifying carbon nanoparticles [ 46 , 47 , 48 ], surfactant additives [ 49 , 50 ], and mechanical mixing in a dry form in special-purpose mills [ 35 , 39 , 42 , 43 ] or extruders [ 33 , 34 ].…”

Section: Methodsmentioning

confidence: 99%

Porous Carbon–Carbon Composite Materials Obtained by Alkaline Dehydrochlorination of Polyvinyl Chloride

et al. 2022

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Porous carbon–carbon composite materials (PCCCM) were synthesized by the alkaline dehydrochlorination of polyvinyl chloride solutions in dimethyl sulfoxide containing the modifying additives of a nanostructured component (NC): graphite oxide (GO), reduced graphite oxide (RGO) or nanoglobular carbon (NGC), with subsequent two-step thermal treatment of the obtained polyvinylene–NC composites (carbonization at 400 °C and carbon dioxide activation at 900 °C). The focus of the study was on the analysis and digital processing of transmission electron microscopy images to study local areas of carbon composite materials, as well as to determine the distances between graphene layers. TEM and low-temperature nitrogen adsorption studies revealed that the structure of the synthesized PCCCM can be considered as a porous carbon matrix in which either carbon nanoglobules (in the case of NGC) or carbon particles with the “crumpled sheet” morphology (in the case of GO or RGO used as the modifying additives) are distributed. Depending on the features of the introduced 5–7 wt.% nanostructured component, the fraction of mesopores was shown to vary from 11% to 46%, and SBET—from 791 to 1115 m2 g−1. The synthesis of PCCNC using graphite oxide and reduced graphite oxide as the modifying additives can be considered as a method for synthesizing a porous carbon material with the hierarchical structure containing both the micro- and meso/macropores. Such materials are widely applied and can serve as adsorbents, catalyst supports, elements of power storage systems, etc.

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Morphological, dielectric, tunable electromagnetic interference shielding and thermal characteristics of multiwalled carbon nanotube incorporated polymer nanocomposites: A facile, environmentally benign and cost effective approach realized via polymer latex/waterborne polymer as matrix

Cited by 14 publications

References 70 publications

High electromagnetic interference shielding of poly(ether-sulfone)/multi-walled carbon nanotube nanocomposites fabricated by an eco-friendly route

High electromagnetic interference shielding of poly(ether-sulfone)/multi-walled carbon nanotube nanocomposites fabricated by an eco-friendly route

Improved dispersion of reduced graphene oxide in benzoxazine composites via electrostatic interaction with M‐cresol

Porous Carbon–Carbon Composite Materials Obtained by Alkaline Dehydrochlorination of Polyvinyl Chloride

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