Peroxide‐based crosslinking of solid silicone rubber, part <scp>II</scp>: The counter‐intuitive influence of dicumylperoxide concentration on crosslink effectiveness and related network structure

Freitas, Maurício Azevedo de; Monks, A. ‐M.; Kerschbaumer, Roman Christopher; Schlögl, Sandra; Saalwächter, Kay; Walluch, Matthias; Consolati, G.; Holzer, Clemens

doi:10.1002/app.54111

Cited by 3 publications

(1 citation statement)

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“…All of these assume that N can be related to N c (the number of Kuhn segments between two consecutive crosslinks) while the contribution of the entanglements remains constant. At this point, the assumption of the entanglement contribution only depending on the elastomeric matrix and its molecular weight is accepted, although it remains an open issue [28] that exceeds the objectives of this work.…”

Section: Introductionmentioning

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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Section: Introductionmentioning

confidence: 99%