Effects of Molecular Weight and Crystallization Temperature on the Morphology Formation in Asymmetric Diblock Copolymers with a Highly Crystalline Block

Awaludin, Rohadi; Endo, Ryuji; Tanimoto, Satoshi; Sasaki, Shintaro; Nojima, Shuichi

doi:10.1295/polymj.32.602

Cited by 27 publications

(27 citation statements)

References 33 publications

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“…The ratio of total molecular weights, M M30 /M M11 , is 2.7 and that of PCL molecular weights, M M30,PCL /M M11,PCL , is 1.6. It was confirmed in our previous study by SAXS and TEM 27 that the crystallization of PCL blocks both in M11 and M30 brought about the morphological transition from the cylindrical or spherical microdomain to the lamellar morphology. The crystallization of M11 is extremely faster than that of M30 at the same crystallization temperature, for instance, M11 crystallizes completely within 45 min at 25 • C while M30 takes more than 3 days to crystallize at 25 • C.…”

Section: Samples and Blend Preparationsupporting

confidence: 76%

“…In our previous study by SAXS and TEM, 27 both M11 and M30 formed the lamellar morphology after the crystallization of PCL blocks, and therefore the lamellar morphology is naturally expected for the crystallized blends composed of M11 and M30. Details of this morphology can be evaluated quantitatively from the DSC and SAXS results.…”

Section: Lamellar Morphology After Crystallizationmentioning

confidence: 75%

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Crystallization Process in Binary Blends of Poly(ε-caprolactone)-block-Polybutadiene Copolymers

Tanimoto

Ito

Sasaki

et al. 2002

Polym J

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ABSTRACT:The crystallization process in binary blends of poly(ε-caprolactone)-block-polybutadiene (PCL-b-PB) copolymers has been investigated by time-resolved small-angle X-Ray scattering with synchrotron radiation (SR-SAXS), where the crystallization of PCL blocks induces a morphological transition both in neat copolymers but the crystallization rate is extremely different between them. The microdomain structure in the melt and the final morphology after crystallization were also measured by conventional SAXS, and the melting behavior of crystallized samples was observed by differential scanning calorimetry (DSC). The binary blend forms a single microdomain structure in the melt over the whole composition range investigated, and the crystallization proceeds with an intermediate rate between those of the constituent PCL-b-PB copolymers to result in a single lamellar morphology. The time dependence of SR-SAXS curves is qualitatively similar in features to that for the crystallization of pure PCL-b-PB copolymers, suggesting that the crystallization of the blend is substantially controlled by a single crystallization mechanism. The remarkable change in the crystallization rate with composition is ascribed to the difference in the stability of preexisting microdomain structures. The conformation of (longer and shorter) PB blocks in the final lamellar morphology is qualitatively discussed.KEY WORDS Crystalline-Amorphous Diblock Copolymer / Binary Blend / Crystallization Process / Final Morphology / It is well known that the crystallization of constituent polymers in polymer blends yields a lamellar morphology, an alternating structure consisting of lamellar crystals and amorphous layers, where the non-crystalline components are accommodated in the amorphous layers between lamellar crystals or rejected outside the lamellar morphology depending on the degree of segregation between the components. 1 When two homopolymers are both crystalline, a competitive crystallization may occur in a limited range of temperature to result in a complicated morphology. However, miscible crystalline/crystalline homopolymer blends above their melting temperatures are not common, so that the morphological study of such systems is very limited. 2,3 In particular, the miscible binary system, where both homopolymers crystallize in a same temperature range with extremely different rates, has not been reported so far.The morphology as well as the crystallization behavior of crystalline-amorphous diblock copolymers has been studied extensively, 4-20 and the lamellar morphology is inevitably formed by the crystallization unless the microdomain structure is sufficiently stable. Therefore, the binary blend of crystalline-amorphous diblocks will be a substitutive system for miscible crystalline/crystalline homopolymer blends with extremely different crystallization rates at a same temperature range. That is, it is possible to change widely the crystallization rate by changing the molecular weight and/or block ratio with keeping the miscibility betw...

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Section: Samples and Blend Preparationsupporting

confidence: 76%

Section: Lamellar Morphology After Crystallizationmentioning

confidence: 75%

Crystallization Process in Binary Blends of Poly(ε-caprolactone)-block-Polybutadiene Copolymers

Tanimoto

Ito

Sasaki

et al. 2002

Polym J

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“…2) Weakly segregated systems (Low values), TODT > Tc > Tg. In this case, there is little morphological restriction for the crystallization process, which allows a break out from the ordered melt structure, therefore the crystallization determines the final structure, usually crystalline lamellae are formed, erasing the previous structure of the melt [95,96,102,114,118,[143][144][145][146][153][154][155][156][157][158][159][160][161][162][163][164].…”

Section: Morphologymentioning

confidence: 99%

Fractionated crystallization in semicrystalline polymers

Sangroniz

Wang

et al. 2021

Progress in Polymer Science

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The crystallization of heterogeneously nucleated bulk polymers typically occurs in a single exothermic process, within a narrow temperature range, i.e., a single exothermic peak is detected by Differential Scanning Calorimetry when the material is cooled from the melt. However, when a bulk semicrystalline polymer is subdivided or dispersed into a multitude of totally (or partially) isolated microdomains (e.g., droplets or cylinders), in number comparable to that of commonly available nucleating heterogeneities, several separated crystallization events are typically observed, i.e., fractionated crystallization. This situation is often found for the minor crystallizable component in immiscible blends.When the bulk polymer is dispersed into a number of microdomains that is several orders of magnitude higher than the available number of heterogeneities within it, most microdomains will be heterogeneity-free. In these clean microdomains the nucleation can occur by contact with the interfaces (i.e., surface nucleation) or by homogeneous nucleation inside the microdomain volume. These cases can be easily encountered in cylinders or spheres within strongly segregated block copolymers, or in infiltrated polymers within nanopores of alumina templates.In this work, a comprehensive review of the known cases of fractionated crystallization is provided. The changes upon decreasing microdomain sizes from a dominant single heterogeneous nucleation, through fractionated crystallization, to surface or homogeneous nucleation are critically reviewed. Emphasis is placed on the common features of the phenomenon across the different systems, and thus on the general conclusions that can be drawn from the analysis of representative semicrystalline polymers. The origin of the fractionated crystallization effects and their dramatic consequences on the nucleation and crystallization kinetics of semicrystalline polymers are also discussed.

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“…Especially, the cases of either “templated” or “confined” crystallization are important, as now the Flory–Huggins parameter (χ N ), as well as the chain length of the polymer blocks are determining the crystallization process. A prominent example is poly(ε‐caprolactone‐ block ‐polybutadiene) BCPs (PCL‐ b ‐PB), where crystallization dominates over microphase separation at low molecular weights ( M n < 19,000 g/mol)8 (leading to “breakout‐crystallization”), whereas at significantly higher molecular weights ( M n > 44,000 g/mol −1 ) the microphase‐separated structure is retained and over‐rules crystallization 9. Similar cases have been described on a large variety of other BCPs (i.e., poly(ethylene)‐ b ‐poly(3 methyl‐1‐butene) (PE‐ b ‐PME),10, 11 poly(ethylene)‐ b ‐poly(styrene‐ethylene‐butene) (PE‐ b ‐PSEB),12 poly(ethylene oxide)‐ b ‐poly(butadiene) (PEO‐ b ‐PB13)) as well as BCP blends (i.e., poly(ethylene oxide)‐ b ‐poly(butylene oxide)/poly(butylene oxide) (PEO‐ b ‐PBO/PBO) 14.…”

Section: Introductionmentioning

confidence: 99%

Poly(ε‐caprolactone)–poly(isobutylene): A crystallizing, hydrogen‐bonded pseudo‐block copolymer

Ostas

Schröter

Beiner

et al. 2011

J. Polym. Sci. A Polym. Chem.

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The crystallization of block copolymers (BCPs) under homogeneous and heterogeneous nucleation is currently well understood revealing the strong interplay of crystallization in competition to microphase separation. This article reports investigations on synthesis and crystallization processes in weakly interacting supramolecular pseudo-BCPs, composed of poly(e-caprolactone) (PCL) and poly(isobutylene) (PIB) blocks, connected by a specifically interacting hydrogen bond (thymine/2,6-diaminotriazine). Starting from ring opening polymerization of e-caprolactone, the use of ''click''-chemistry enabled the introduction of thymine endgroups onto PCL polymer, thus generating the fully thymine-substituted pure PCLs (1a, 1b) as judged via NMR and MALDI analysis. Physical mixing of 1a, 1b with a bivalent, bis(2,6-diaminotriazine)-contain-ing molecule (2) generated the bivalent polymers BC1 and BC2, whereas mixing of 1a or 1b with the 2,6-diaminotriazinesubstituted PIB (3) generated the supramolecular pseudo-BCPs BC3 and BC4. Thermal investigations (DSC, Avrami analysis) revealed only minor changes in the crystallization behavior of BC1-BC4 with Avrami exponents close to three, indicative of a confluence of the growing crystals during the crystallization process. V C 2011 Wiley Periodicals, Inc. J Polym Sci Part A: Polym Chem 49: [3404][3405][3406][3407][3408][3409][3410][3411][3412][3413][3414][3415][3416] 2011

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Effects of Molecular Weight and Crystallization Temperature on the Morphology Formation in Asymmetric Diblock Copolymers with a Highly Crystalline Block

Cited by 27 publications

References 33 publications

Crystallization Process in Binary Blends of Poly(ε-caprolactone)-block-Polybutadiene Copolymers

Crystallization Process in Binary Blends of Poly(ε-caprolactone)-block-Polybutadiene Copolymers

Fractionated crystallization in semicrystalline polymers

Poly(ε‐caprolactone)–poly(isobutylene): A crystallizing, hydrogen‐bonded pseudo‐block copolymer

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