Confinement Effects on the Crystallization Kinetics and Self‐Nucleation of Double Crystalline Poly(p‐dioxanone)‐<i>b</i>‐poly(ϵ‐caprolactone) Diblock Copolymers

Müller, Alejandro J.; Albuerne, Julio; Esteves, Luis M.; Márquez, Leni; Raquez, Jean-Marie; Degée, Philippe; Dubois, Philippe; Collins, Stephen F; Hamley, Ian W.

doi:10.1002/masy.200451128

Cited by 46 publications

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“…In block copolymers, factors such as the volumetric fraction and the degree of segregation affect the type of confinement and, as a consequence, influence the SN behavior. Several works dealing with the crystallization of semicrystalline block copolymers have reported the SN of crystallizable block(s) [3,[94][95][96][97][98][108][109][110][111][112][113][114][115][116][117][118][119]. In these studies, three kinds of behavior have been reported: 1.…”

Section: Influence Of Confinement On Self-nucleation Behaviormentioning

confidence: 99%

Self-Nucleation of Crystalline Phases Within Homopolymers, Polymer Blends, Copolymers, and Nanocomposites

Michell

Múgica

Zubitur

et al. 2015

Advances in Polymer Science

123

303

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Self-nucleation (SN) is a special nucleation process triggered by selfseeds or self-nuclei that are generated in a given polymeric material by specific thermal protocols or by inducing chain orientation in the molten or partially molten state. SN increases the nucleation density of polymers by several orders of magnitude, producing significant modifications to their morphology and overall crystallization kinetics. In fact, SN can be used as a tool for investigating the overall isothermal crystallization kinetics of slow-crystallizing materials by accelerating the primary nucleation stage in a previous SN step. Additionally, SN can facilitate the formation of one particular crystalline phase in polymorphic materials. The SN behavior of a given polymer is influenced by its molecular weight, molecular topology, and chemical structure, among other intrinsic and extrinsic characteristics. This review paper focuses on the applications of DSC-based SN techniques to study the nucleation, crystallization, and morphology of different types of polymers, blends, copolymers, and nanocomposites.

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Section: Influence Of Confinement On Self-nucleation Behaviormentioning

confidence: 99%

Self-Nucleation of Crystalline Phases Within Homopolymers, Polymer Blends, Copolymers, and Nanocomposites

Michell

Múgica

Zubitur

et al. 2015

Advances in Polymer Science

123

303

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“…This makes the crystallizable block copolymers representative systems having confined crystallization behavior, especially in the strong segregation regime [52]. Confined crystallization has been widely observed in the diblock copolymers having double crystalline blocks, such as PEO-b-PCL [112][113][114][115][116], PLLA-b-PEO [117][118][119][120][121][122], PLLA-b-PCL [123][124][125], poly(p-dioxanone) (PPDX)-b-PCL [126][127][128], polyolefin-based block copolymers [129][130][131][132][133][134][135], and so on. The confined crystallization kinetics and crystalline morphology of such block copolymers have been extensively studied.…”

Section: Crystalline Morphology Of Polymer Segments Confined In Blockmentioning

confidence: 99%

Crystalline and Spherulitic Morphology of Polymers Crystallized in Confined Systems

Xie

Bao

et al. 2017

Crystals

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Due to the effects of microphase separation and physical dimensions, confinement widely exists in the multi-component polymer systems (e.g., polymer blends, copolymers) and the polymers having nanoscale dimensions, such as thin films and nanofibers. Semicrystalline polymers usually show different crystallization kinetics, crystalline structure and morphology from the bulk when they are confined in the nanoscale environments; this may dramatically influence the physical performances of the resulting materials. Therefore, investigations on the crystalline and spherulitic morphology of semicrystalline polymers in confined systems are essential from both scientific and technological viewpoints; significant progresses have been achieved in this field in recent years. In this article, we will review the recent research progresses on the crystalline and spherulitic morphology of polymers crystallized in the nanoscale confined environments. According to the types of confined systems, crystalline, spherulitic morphology and morphological evolution of semicrystalline polymers in the ultrathin films, miscible polymer blends and block copolymers will be summarized and reviewed.

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“…[2][3][4] Although there have been a number of prior reports on double crystalline diblock copolymer systems, the understanding of their complicated properties is still at a nascent stage. [5][6][7][8][9][10][11][12][13][14][15][16] Poly(L-lactide) (PLLA) has been widely employed in the medical field because of its biodegradability. However the applications of PLLA to commercial products are limited principally by its brittleness.…”

Section: Introductionmentioning

confidence: 99%

Melt Structure and its Transformation by Sequential Crystallization of the Two Blocks within Poly(L‐lactide)‐block‐Poly(ε‐caprolactone) Double Crystalline Diblock Copolymers

Hamley

Parras

Castelletto

et al. 2006

Macro Chemistry & Physics

108

122

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Sequential crystallization of poly(L-lactide) (PLLA) followed by poly(e-caprolactone) (PCL) in double crystalline PLLA-b-PCL diblock copolymers is studied by differential scanning calorimetry (DSC), polarized optical microscopy (POM), wide-angle X-ray scattering (WAXS) and small-angle X-ray scattering (SAXS). Three samples with different compositions are studied. The sample with the shortest PLLA block (32 wt.-% PLLA) crystallizes from a homogeneous melt, the other two (with 44 and 60% PLLA) from microphase separated structures. The microphase structure of the melt is changed as PLLA crystallizes at 122 8C (a temperature at which the PCL block is molten) forming spherulites regardless of composition, even with 32% PLLA. SAXS indicates that a lamellar structure with a different periodicity than that obtained in the melt forms (for melt segregated samples). Where PCL is the majority block, PCL crystallization at 42 8C following PLLA crystallization leads to rearrangement of the lamellar structure, as observed by SAXS, possibly due to local melting at the interphases between domains. POM results showed that PCL crystallizes within previously formed PLLA spherulites. WAXS data indicate that the PLLA unit cell is modified by crystallization of PCL, at least for the two majority PCL samples. The PCL minority sample did not crystallize at 42 8C (well below the PCL homopolymer crystallization temperature), pointing to the influence of pre-crystallization of PLLA on PCL crystallization, although it did crystallize at lower temperature. Crystallization kinetics were examined by DSC and WAXS, with good agreement in general. The crystallization rate of PLLA decreased with increase in PCL content in the copolymers. The crystallization rate of PCL decreased with increasing PLLA content. The Avrami exponents were in general depressed for both components in the block copolymers compared to the parent homopolymers.Polarized optical micrographs during isothermal crystallization of (a) homo-PLLA, (b) homo-PCL, (c) and (d) block copolymer after 30 min at 122 8C and after 15 min at 42 8C.

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Confinement Effects on the Crystallization Kinetics and Self‐Nucleation of Double Crystalline Poly(p‐dioxanone)‐b‐poly(ϵ‐caprolactone) Diblock Copolymers

Cited by 46 publications

References 0 publications

Self-Nucleation of Crystalline Phases Within Homopolymers, Polymer Blends, Copolymers, and Nanocomposites

Self-Nucleation of Crystalline Phases Within Homopolymers, Polymer Blends, Copolymers, and Nanocomposites

Crystalline and Spherulitic Morphology of Polymers Crystallized in Confined Systems

Melt Structure and its Transformation by Sequential Crystallization of the Two Blocks within Poly(L‐lactide)‐block‐Poly(ε‐caprolactone) Double Crystalline Diblock Copolymers

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