Multiscale Modeling of Vinyl-Addition Polynorbornenes: The Effect of Stereochemistry

Vinyl-addition polynorbornenes are candidates for designing high-performance polymers due to unique characteristics, which include a high glass transition temperature associated with a rigid backbone. Recent studies have established that the processability and properties of these polymers can be fin...

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Bibliographic Details
Published in:Polymers 2024-08, Vol.16 (16), p.2243
Main Authors: Shahidi, Nobahar, Laub, Jeffrey A, Vogiatzis, Konstantinos D, Doxastakis, Manolis
Format: Article
Language:English
Subjects:
Addition polymerization
Chemical synthesis
Density functional theory
Glass transition temperature
Molecular chains
Molecular conformation
Molecular dynamics
Molecular structure
Oligomers
Polymerization
Polymers
Polynorbornene
Simulation
Stereochemistry
Stereoisomerism
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Summary:Vinyl-addition polynorbornenes are candidates for designing high-performance polymers due to unique characteristics, which include a high glass transition temperature associated with a rigid backbone. Recent studies have established that the processability and properties of these polymers can be fine-tuned by using targeted substitutions. However, synthesis with different catalysts results in materials with distinct properties, potentially due to the presence of various stereoisomers that are difficult to quantify experimentally. Herein, we develop all-atom models of polynorbornene oligomers based on classical force fields and density functional theory. To establish the relationship between chemical architecture, chain conformations, and melt structure, we perform detailed molecular dynamics simulations with the fine-tuned atomistic force field and propose simpler coarse-grained descriptions to address the high molecular weight limit. All-atom simulations of oligomers suggest high glass transition temperatures in the range of 550-600 K. In the melt state (800 K), meso chains form highly rigid extended coils (C∞≈11) with amorphous structural characteristics similar to the X-ray diffraction data observed in the literature. In contrast, simulations with racemo chains predict highly helical tubular chain conformations that could promote assembly into crystalline structures.
ISSN:2073-4360
2073-4360
DOI:10.3390/polym16162243