Crystal Growth Rate in a Blend of Long and Short Polymer Chains

Carvalho, Jessica L.; Cormier, Sara L.; Lin, Nan; Dalnoki-Veress, Kari

doi:10.1021/ma202429q

Cited by 18 publications

(9 citation statements)

References 23 publications

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“…These results arise from the higher molecular mobility of shorter chains which, in comparison with longer chains having the same chemical nature, present lower and higher crystallisation capacity. 16,17 Overall, it is observed that P2HEB displays a very different crystalline behaviour in the nascent form and after melting, which has been already found for materials such as ultra high molecular weight polyethylene (UHMWPE), 18 polyoxymethylene, 19 and heterotactic polylactide. 20 Nascent P2HEB, directly obtained after ROP, is obtained in powder form and displays a high crystallinity because polymerization reaction facilitates its crystalline growth.…”

Section: Thermal Transitions Of P2hebmentioning

confidence: 63%

Thermal, structural and degradation properties of an aromatic–aliphatic polyester built through ring-opening polymerisation

et al. 2017

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Section: Thermal Transitions Of P2hebmentioning

confidence: 63%

Thermal, structural and degradation properties of an aromatic–aliphatic polyester built through ring-opening polymerisation

et al. 2017

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“…In contrast with PCDI, the incorporation of TNPP to PLA results in a significant increase of the PLA crystallization kinetics, even though the molecular weight is also increased [12]. Based on the explanation of Carvalho et al [39], decreasing the number of chain ends in the system as a consequence of short chains removal is responsible for the increased crystallization rate. Also, Richter and coworkers [40] explained that chain ends are much more mobile than mid‐chain segments.…”

Section: Resultsmentioning

confidence: 99%

Crystallization behavior and morphology of polylactide and PLA/clay nanocomposites in the presence of chain extenders

Najafi

Heuzey

Carreau

2012

Polymer Engineering & Sci

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The effect of clay and chain extender on the nonisothermal, isothermal crystallization kinetics, and morphology of polylactide (PLA) was investigated in this study. PLA and PLA‐based nanocomposites containing 2 wt% organoclay were prepared via melt compounding. Three commercially available chain extenders were used: polycarbodiimide (PCDI), tris(nonylphenyl) phosphite (TNPP), and Joncryl ADR4368F. The nanoclay particles were found to act as nucleating agents. Chain extender incorporation, however, had diverse effects on both crystallization rate and degree of crystallinity. Nonisothermal DSC results revealed that the addition of PCDI increased the cold‐crystallization temperature (Tc) from 106 to 114°C, reduced the degree of crystallinity from 6.3 to 5.3%, and resulted in the formation of bimodal melting peaks in PLA. On the other hand, the reduction of chain ends in the presence of TNPP resulted in a significant increase of the crystallization rate and degree of crystallinity from 6.3 to 15.2%. In the case of Joncryl, its incorporation led to the formation of a long‐chain branching structure, which disrupted the chain packing. Therefore, the degree of crystallinity (from 6.3 to 1.6%) and the rate of crystallization decreased, while Tc was increased from 106 to 122°C in the presence of Joncryl. POLYM. ENG. SCI., 2013. © Society of Plastics Engineers

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“…The bottleneck to crystallization in other materials is not nucleation, but the crystal growth rate. Recently, blends of high and low molecular weight poly(ethylene oxide) were noted to exhibit counterintuitive behavior: the greater the content of low molecular weight material, the slower the spherulitic growth rate . The resulting hypothesis was that increasing the number of chain ends results in more crystalline defects at the crystalline growth front.…”

Section: Introductionmentioning

confidence: 99%

Polymer crystallization rate challenges: The art of chemistry and processing

Andjelić

Scogna

2015

J of Applied Polymer Sci

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The intention of this study is to discuss scientific advances toward one very important challenge in the polymer processing industry: How does one increase the crystallization rate of slow-to-crystallize polymeric materials, thereby facilitating processing and enabling peak product performance? In the medical device field, where both government-controlled regulatory entities and medical professionals closely scrutinize the biocompatibility of added crystallization rate enhancers, achieving these twin goals has always been challenging. Herein, we present a review of various chemical and physical approaches used to tune the crystallization rate of semicrystalline polymers, with a strong emphasis on two novel approaches recently discovered and developed in our laboratories.

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Crystal Growth Rate in a Blend of Long and Short Polymer Chains

Cited by 18 publications

References 23 publications

Thermal, structural and degradation properties of an aromatic–aliphatic polyester built through ring-opening polymerisation

Thermal, structural and degradation properties of an aromatic–aliphatic polyester built through ring-opening polymerisation

Crystallization behavior and morphology of polylactide and PLA/clay nanocomposites in the presence of chain extenders

Polymer crystallization rate challenges: The art of chemistry and processing

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