Chain dynamics in partially cross‐linked polyethylene by combined rheology and <scp>NMR</scp>‐based molecular rheology

Shahsavan, Farhad; Beiner, Mario; Saalwächter, Kay

doi:10.1002/pol.20210213

Cited by 4 publications

(5 citation statements)

References 46 publications

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“…While the number of network-like protons of PE0.5M samples began to level off due to the recovery of entanglements caused by the fast reptation of molecular chains. It agreed well with what was observed in partially cross-linked HDPE [50].…”

Section: Entanglement Networksupporting

confidence: 92%

“…From Figure S4 (see in Supplementary Materials), it could be seen that the number of network-like protons of PE1.1M samples continued to decrease, which was consistent with the trend at 140 • C. While the number of network-like protons of PE0.5M samples began to level off due to the recovery of entanglements caused by the fast reptation of molecular chains. It agreed well with what was observed in partially cross-linked HDPE [50].…”

Section: Entanglement Networksupporting

confidence: 92%

“…The residual dipolar coupling was contributed only by inter-segment proximity, including topological entanglements. The chain segments moved faster and could free themselves from physical topological constraints as the temperature rose [50]. This meant a decrease in network-like protons was expected, as shown in Figure S4 (see in Supplementary Materials).…”

Section: Entanglement Networkmentioning

confidence: 92%

“…1 H DQ NMR was robust to elucidate residual dipolar coupling, determining entanglement or crosslink densities in linear entangled polymer melts [50]. To further investigate the microscopic mechanism of the PE melting process, we tracked the entanglement network during PE melting with the help of 1 H DQ NMR.…”

Section: Entanglement Networkmentioning

confidence: 99%

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Chain Dynamics of Partially Disentangled UHMWPE around Melting Point Characterized by 1H Low-Field Solid-State NMR

et al. 2023

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Melts of ultrahigh molecular weight polyethylene (UHMWPE) entangled significantly, suffering processing difficulty. In this work, we prepared partially disentangled UHMWPE by freeze-extracting, exploring the corresponding enchantment of chain mobility. Fully refocused 1H free induction decay (FID) was used to capture the difference in chain segmental mobility during the melting of UHMWPE with different degrees of entanglement by low-field solid-state NMR. The longer the polyethylene (PE) chain is in a less-entangled state, the harder the process of merging into mobile parts after detaching from crystalline lamella during melting. 1H double quantum (DQ) NMR was further used to obtain information caused by residual dipolar interaction. Before melting, the DQ peak appeared earlier in intramolecular-nucleated PE than in intermolecular-nucleated PE because of the strong constraints of crystals in the former one. During melting, less-entangled UHMWPE could keep disentangled while less-entangled high density polyethylene (HDPE) could not. Unfortunately, no noticeable difference was found in DQ experiments between PE melts with different degrees of entanglement after melting. It was ascribed to the small contribution of entanglements compared with total residual dipolar interaction in melts. Overall, less-entangled UHMWPE could reserve its disentangled state around the melting point long enough to achieve a better way of processing.

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Section: Entanglement Networksupporting

confidence: 92%

Section: Entanglement Networksupporting

confidence: 92%

Section: Entanglement Networkmentioning

confidence: 92%

Section: Entanglement Networkmentioning

confidence: 99%

See 2 more Smart Citations

Chain Dynamics of Partially Disentangled UHMWPE around Melting Point Characterized by 1H Low-Field Solid-State NMR

et al. 2023

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“…Another improvement for the future would be the addition of more than one way to obtain D res , for instance, by fitting an Abragam-like function or through simultaneous fitting of two sets of data, as has been done in other works [34]. Further future developments of MEW2 could include different options for the analysis of various pulse sequences applied to elastomeric materials.…”

Section: Discussionmentioning

confidence: 99%

Introducing “MEW2” Software: A Tool to Analyze MQ-NMR Experiments for Elastomers

Salamanca,

Zepeda-Rodríguez,

Diñeiro

et al. 2023

Polymers

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Low-field time-domain proton Nuclear Magnetic Resonance (NMR) spectroscopy is an attractive and powerful tool for studying the structure and dynamics of elastomers. The existence of crosslinks and other topological constraints in rubber matrices (entanglements and filler–rubber interactions, among others) renders the fast segmental fluctuations of the polymeric chains non-isotropic, obtaining nonzero residual dipolar couplings, which is the main observable of MQ-NMR experiments. A new software, Multiple quantum nuclear magnetic resonance analyzer for Elastomeric Networks v2 (MEW2), provides a new tool to facilitate the study of the molecular structure of elastomeric materials. This program quantitatively analyzes two different sets of experimental data obtained in the same experiment, which are dominated by multiple-quantum coherence and polymer dynamics. The proper quantification of non-coupled network defects (dangling chain ends, loops, etc.) allows the analyzer to normalize the multiple quantum intensity, obtaining a build-up curve that contains the structural information without any influence from the rubber dynamics. Finally, it provides the spatial distribution of crosslinks using a fast Tikhonov regularization process based on a statistical criterion. As a general trend, this study provides an automatic solution to a tedious procedure of analysis, demonstrating a new tool that accelerates the calculations of network structure using 1H MQ-NMR low-field time-domain experiments for elastomeric compounds.

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Correlation Between Segmental Order Parameter and Entanglement Length in a Monodisperse Comb Polymer

Shahsavan,

Keller,

Wilhelm

et al. 2024

Macromolecules

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The motion of a polymer chain within a hypothetical confining tube leads to arise a segmental order parameter Sb. This parameter is assessed via multiple-quantum (MQ) NMR experiments, providing a valuable molecule-level rheological observable. In both polymer networks and entangled melts, the order parameter is proportional to the inverse of the number of segments between two covalent crosslinks or physical entanglements. In entangled polymer networks, the entanglements have usually been considered as additional but temporary crosslinks and the contribution of the physical and chemical constraints are assumed additive. Recent computer simulation results challenged this assumption for lowly crosslinked polymer networks; instead, Sb was shown to scale with (NeNc) 1/2 , 𝑁 and 𝑁 being the number of segments between crosslinks and entanglements, respectively [M. Lang and J.-U. Sommer, Phys. Rev. Lett. 2010, 104, 177801]. An experimental confirmation remains elusive due to challenges in distinguishing the contributions of entanglements and crosslinks, as well as the long averaging timescales involved. In this study, we assess this correlation by examining chain dynamics in a monodisperse polyisoprene comb, utilized as a model system.To model chain dynamics in this system, the dynamic dilution model, originally designed for predicting the rheological behavior of star and branched polymers, has been modified to facilitate its application in the analysis of MQ NMR signals. We also address some of its shortcomings.

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Chain dynamics in partially cross‐linked polyethylene by combined rheology and NMR‐based molecular rheology

Cited by 4 publications

References 46 publications

Chain Dynamics of Partially Disentangled UHMWPE around Melting Point Characterized by 1H Low-Field Solid-State NMR

Chain Dynamics of Partially Disentangled UHMWPE around Melting Point Characterized by 1H Low-Field Solid-State NMR

Introducing “MEW2” Software: A Tool to Analyze MQ-NMR Experiments for Elastomers

Correlation Between Segmental Order Parameter and Entanglement Length in a Monodisperse Comb Polymer

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