Pressure‐induced crystallization of low density polyethylene on carbon nanotubes and carbon nanofibers

Depan, Dilip; Hebert, Brittany; Conlin, Andrew; Chirdon, William M.; Khattab, Ahmed

doi:10.1002/pc.23919

Cited by 8 publications

(6 citation statements)

References 41 publications

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“…Fundamentally, crystallization involves two stages: nucleation and crystal growth. In our continuous efforts to realize the potential of CNTs to induce polymer crystallization, we found that carbon‐based nanoparticles are effective agents that facilitate nucleation; however, the second stage of growth is governed by space …”

Section: Resultsmentioning

confidence: 99%

“…In our continuous efforts to realize the potential of CNTs to induce polymer crystallization, we found that carbon-based nanoparticles are effective agents that facilitate nucleation; however, the second stage of growth is governed by space. [31][32][33][34] It has been previously reported that the dimensionality of carbon nanoparticles primarily governs the supramolecular architecture of the crystallized polymer. 24,35 As seen in SEM images of PLA-GNS, the polymer seems to be crystallized randomly on the surface of GNS in multiple orientations to generate a flower-like, petal-shaped structure.…”

Section: Characterization Methodsmentioning

confidence: 99%

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Influence of graphene nanoscrolls on the crystallization behavior and nano‐mechanical properties of polylactic acid

Ajala

Werther

Nikaeen

et al. 2019

Polymers for Advanced Techs

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Graphene nanoscrolls (GNS), one‐dimensional carbon‐based nanomaterials, have been predicted to possess extraordinary characteristics due to their unique open topology with scrolled graphene monolayers. In this study, the conversion of planar 2‐D graphene nanoplatelets (GNPs) to tubular and scrolled 1‐D GNSs is described. The effects of GNS as a nucleating agent to modulate the morphology, crystallization, and nano‐mechanical properties of polylactic acid (PLA) were studied. The nucleating effect of GNS and its unique topological characteristics proves to influence the crystallization of PLA. Fourier transform infrared (FTIR) spectroscopy indicated nonpreferential interactions of PLA chains around GNS due to the bulky and helical PLA macromolecular chains. Superior interfacial interactions and strain in GNS provide better load transfer between GNS and PLA matrices, resulting in higher modulus and hardness. This study is the first detailed analysis to elucidate the role of unique GNS to favorably modulate the properties of a polymer.

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Section: Resultsmentioning

confidence: 99%

Section: Characterization Methodsmentioning

confidence: 99%

Influence of graphene nanoscrolls on the crystallization behavior and nano‐mechanical properties of polylactic acid

Ajala

Werther

Nikaeen

et al. 2019

Polymers for Advanced Techs

Self Cite

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“…Some authors also report the decrease in the crystallinity of polyolefins after reinforcing with CNT 37 ; however, others report no changes in the crystallinity. 38 There are also publications that show evidence of the increase of crystallinity of a polymer after CNTs addition, for example, in composites of PE/CNT 39 and PP/CNT. 37 CNT addition to EVA forms the interphase with hindered chain mobility that may efficiently disrupt the crystals’ nucleation and growth in the composite as compared with the neat EVA.…”

Section: Resultsmentioning

confidence: 99%

Enhanced mechanical, conductivity, and dielectric characteristics of ethylene vinyl acetate copolymer composite filled with carbon nanotubes

Gaidukovs

Zukulis

Bochkov

et al. 2017

Journal of Thermoplastic Composite Materials

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We report high mechanical, dielectric, and thermal performance of carbon nanotubes (CNT) reinforced ethylene vinyl acetate (EVA) composites, fabricated using conventional melt extrusion processing. CNT have extremely high stiffness, electrical conductivity, and surface area, ensuring strong interactions with the polymer and effective reinforcement. The addition of CNT to EVA leads to an extremely high yield strength and Young’s modulus of the composites. The EVA composite produced, containing 5 wt% CNT, exhibited an almost 3-fold increase in Young’s modulus and a 2.2-fold improvement of yield strength compared to neat EVA. However, the composite maintained high deformation properties—a ductility of 1300%. Scanning electron microscopy analysis evidences the agglomeration of the CNT in the EVA/CNT composites. The EVA/CNT composites gained excellent electrostatic discharge properties—a surface resistivity in the range of 108 Ω/square. The observed thermal conductivity of the composites was increased by about 30% without losing the electrically insulating performance.

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“…[29] During this crystallization process, the periodic growth of lamellar disk-shaped polymer crystals is governed by soft epitaxy where the nanoparticle surface acts as a nucleating agent. [30][31][32] Notably, although the concentration of CNTs is nearly 15 times higher (~20 wt% of polymer) than those reported previously, [33,34] the NHSK architecture is still uniform. The high magnification SEM and TEM images in Figure 2 illustrated that the periodic crystallization of PE on the tube axis of CNTs prevented the agglomeration of CNTs in polymer matrices.…”

Section: Characterization Techniquesmentioning

confidence: 99%

Crystallization kinetics of high‐density and low‐density polyethylene on carbon nanotubes

Depan

Khattab

Simoneaux

et al. 2019

Polymer Crystallization

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This study presents a comparative analysis of the crystallization behavior of low‐density polyethylene (LDPE) and high‐density polyethylene (HDPE) nanocomposites. Carbon nanotubes (CNTs) were used as a nucleating agent to generate a nanohybrid shish‐kebab architecture. Materials characterizations were performed to evaluate the crystal morphology and crystallization kinetics using scanning electron microscopy (SEM) and differential scanning calorimetry (DSC), respectively. The lamellae of polyethylene were always found to grow laterally on the tube axis of CNTs. The parameters of the Avrami model for primary crystallization were determined. SEM indicated the crystal morphology changed from spherulitic to disk‐shaped with the addition of CNTs, while DSC‐based thermal examination indicated that the CNTs can provide nucleation sites to polyethylene to accelerate the crystal growth rate. HDPE was found to crystallize faster than LDPE on CNTs. The highly branched nature of LDPE's macromolecular chains are known to cause reduced chain mobility, which resulted in lower crystallinity values with smaller crystallite sizes for LDPE in this study. In comparison, the more linear HDPE chains have an increased polymer density and chain mobility, resulting in an improved nucleation ability of HDPE chain segments on CNTs.

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Pressure‐induced crystallization of low density polyethylene on carbon nanotubes and carbon nanofibers

Cited by 8 publications

References 41 publications

Influence of graphene nanoscrolls on the crystallization behavior and nano‐mechanical properties of polylactic acid

Influence of graphene nanoscrolls on the crystallization behavior and nano‐mechanical properties of polylactic acid

Enhanced mechanical, conductivity, and dielectric characteristics of ethylene vinyl acetate copolymer composite filled with carbon nanotubes

Crystallization kinetics of high‐density and low‐density polyethylene on carbon nanotubes

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