Monodisperse Polymer Melts Crystallize via Structurally Polydisperse Nanoscale Clusters: Insights from Polyethylene

Hall, Kyle Wm.; Sirk, Timothy W.; Percec, Simona; Klein, Michael L.; Shinoda, Wataru

doi:10.3390/polym12020447

Cited by 9 publications

(22 citation statements)

References 60 publications

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“…In turn, we were able to represent an individual n -C 720 H 1442 chain using 240 SDK beads, substantially reducing the number of interaction sites required to simulate polyethylene crystallization in each of the 400-chain systems (96,000 coarse-grain sites vs over 850,000 atomic sites) and enabling us to undertake the current study. We have previously established that the SDK model is suitable for investigating polyethylene systems and processes in silico (see ref ) and have leveraged the SDK model to study various facets of crystal nucleation in entangled polyethylene melts. − , …”

Section: Methodsmentioning

confidence: 99%

“…While there has been, and continues to be, much experimental work − on polymer crystal nucleation as well as theoretical work − on nucleation processes, simulations are being increasingly leveraged to provide direct, unambiguous access to sub-nano spatiotemporal resolutions, namely, the time and length scales relevant to polymer crystal nucleation. For more than two decades, simulations have been used to study the molecular-level details of polymer crystal nucleation under nonflow conditions in both solutions − and melts. − In recent years, several groups have also started using molecular simulations to study polymer crystal nucleation in the presence of shear − and extension ,,,− conditions, emulating flow-induced nucleation. Other groups have leveraged molecular simulations to characterize how polymer crystal nucleation is affected at the molecular level by molecular weight distributions, − additives, , interfaces, − and changes in the polymer architecture ( i.e.…”

Section: Introductionmentioning

confidence: 99%

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Chain-End Modification: A Starting Point for Controlling Polymer Crystal Nucleation

et al. 2021

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This computational study illustrates how modifying the end groups of polymer chains offers a viable strategy to control polymer crystal nucleation in entangled melts. More specifically, altering chain ends to enhance chain-end aggregation enables crystal nucleation to occur at higher temperatures than with unmodified counterparts. Surprisingly, while chain-end aggregation does enhance crystal nucleation, chain-end clusters do not act as direct nucleating agents. As such, the crystal nucleation enhancement arising from chain-end modification differs from historical models, for example, via epitaxial matching. This study is based on coarse-grain molecular simulations of polyethylene crystallization in which chain-end modifications have been achieved by altering the Lennard–Jones parameters of the terminal coarse-grain beads of the polyethylene chains, thereby varying the size of chain ends and emulating chain termination with polycylic aliphatic moieties (e.g., adamantyl groups). The present approach thus leverages steric mismatch between chain-end and main-chain segments as a strategy to alter polyethylene crystal nucleation rather than relying on the utilization of directional (e.g., hydrogen bonding) or ionic interactions. The present computer simulations demonstrate an up to 20 K increase in the crystal nucleation temperature of entangled melts composed of n-C720H1442 polyethylene-like chains even though chain ends account for a small fraction (<1 mol %) of the sample. Seemingly, low chemical loadings are needed to control nucleation via end-group modification.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Chain-End Modification: A Starting Point for Controlling Polymer Crystal Nucleation

et al. 2021

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“…The material structural elements can vary significantly in scale, ranging from atomic-scale lattices to bridge-sized truss structures. SMs are typically studied at four different structural scales, namely, the sub-microstructure, the microstructure, the mesostructure and the macrostructure (Figure 1) (Zhao et al , 2019; Liu et al , 2018; Hall et al , 2020; Borgue et al , 2019; Barrios-Muriel et al , 2020; Yeh, 2020).…”

Section: Introductionmentioning

confidence: 99%

Manufacturing process-driven structured materials (MPDSMs): design and fabrication for extrusion-based additive manufacturing

Patterson

Chadha

Jasiuk³

2021

RPJ

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Purpose This paper aims to explore the design and fabrication of meso-scale Manufacturing Process-Driven Structured Materials (MPDSMs). These are designed, architected materials where the prime design requirement is manufacturability. The concepts are applied to those fabricated using fused deposition modeling or fused filament fabrication (FDM/FFF), a thermoplastic polymer additive manufacturing (AM) process. Three case studies were presented to demonstrate the approach. Design/methodology/approach The paper consists of four main sections; the first developed the MPDSMs concept, the second explored manufacturability requirements for FDM/FFF in terms of MPDSMs, the third presented a practical application framework and the final sections provided some case studies and closing remarks. Findings The main contributions of this study were the definition and development of the MDPSMs concept, the application framework and the original case studies. While it is most practical to use a well-defined AM process to first explore the concepts, the MPDSMs approach is neither limited to AM nor thermoplastic polymer materials nor meso-scale material structures. Future research should focus on applications in other areas. Originality/value The MPDSMs approach as presented in this concept paper is a novel method for the design of structured materials where manufacturability is the prime requirement. It is distinct from classic design-for-manufacturability concepts in that the design space is limited to manufacturable design candidates before the other requirements are satisfied. This removes a significant amount of schedule and costs risk from the design process, as all the designs produced are manufacturable within the problem tolerance.

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“…Previous in silico work has probed polymer crystal nucleation in the context of isolated chains, 41,65,69 solutions, 49,62,63,69 and melts. 33,[35][36][37][38][39][40]52,53,55,57,60,64 Simulations have also been used to elucidate the effects of molecular weight distribution, 28,[31][32][33]44 chain topology (e.g., linear vs. ring chains), 30 chain branching, 33,34,40 and cross-linking 70 on polymer crystal nucleation. There has been much interest in the evolution of chain conformations, 32,33,39,53,60,61,69 topological details related to chain folding, 28,29,32,33,[37][38][39]49,57,64,71 and connect...…”

Section: Introductionmentioning

confidence: 99%

“…33,[35][36][37][38][39][40]52,53,55,57,60,64 Simulations have also been used to elucidate the effects of molecular weight distribution, 28,[31][32][33]44 chain topology (e.g., linear vs. ring chains), 30 chain branching, 33,34,40 and cross-linking 70 on polymer crystal nucleation. There has been much interest in the evolution of chain conformations, 32,33,39,53,60,61,69 topological details related to chain folding, 28,29,32,33,[37][38][39]49,57,64,71 and connecting entanglements/disentanglement to observed crystallization phenomenology. 48,49,54,72 For example, Luo and Sommer 54 demonstrated that local entanglements play a key role in polymer crystallization memory effects, and revealed connections between local entanglement lengths, stem lengths and densities.…”

Section: Introductionmentioning

confidence: 99%

Property Decoupling across the Nucleus-Melt Interface during Polymer Crystal Nucleation

Hall,

Percec,

Shinoda

et al. 2020

Preprint

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Spatial distributions are presented that quantitatively capture how polymer properties (e.g., segment alignment, density, and potential energy) vary with distance from nascent polymer crystals (nuclei) in prototypical polyethylene melts. It is revealed that the spatial extent of nuclei and their interfaces is metric-dependent as is the extent to which nucleus interiors are solid-like. As distance from a nucleus increases, some properties, such as density, decay to melt-like behavior more rapidly than polymer segment alignment, indicating that a polymer nucleus resides in a nematic-like droplet. This nematic-like droplet region coincides with enhanced formation of ordered polymer segments that are not part of the nucleus. It is more favourable to find non-constituent ordered polymer segments near a nucleus than in the surrounding metastable melt, pointing to the possibility of one nucleus inducing the formation of other nuclei. These findings provide a conceptual bridge between polymer crystal nucleation under non-flow and flow conditions, and are used to rationalize previous results.

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Monodisperse Polymer Melts Crystallize via Structurally Polydisperse Nanoscale Clusters: Insights from Polyethylene

Cited by 9 publications

References 60 publications

Chain-End Modification: A Starting Point for Controlling Polymer Crystal Nucleation

Chain-End Modification: A Starting Point for Controlling Polymer Crystal Nucleation

Manufacturing process-driven structured materials (MPDSMs): design and fabrication for extrusion-based additive manufacturing

Property Decoupling across the Nucleus-Melt Interface during Polymer Crystal Nucleation

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