Shuichiro Seno scite author profile

The morphology of ADMET-synthesized polyethylene with n-butyl branches precisely spaced on every 39th carbon (EH39) was studied in comparison with an ethylene/1-hexene addition copolymer possessing the same branching probability, the goal being to elucidate the effect of the intramolecular sequence length heterogeneity on the lamella crystal thickness and its distribution. EH39 was found to have an orthorhombic crystalline polymorphism, which is normal for commercialized polyethylenes and different from that of the other ADMET polyethylenes with shorter CH 2 spacing (C15, C21). EH39 exhibits a narrow lamella thickness distribution; the average thickness (l c,av. ) corresponds exactly to the space length between two consecutive branches, suggesting the complete exclusion of n-butyl branches from the crystal stem. The average thickness, l c,av. mentioned above is also coincident with that obtained from WAXS and SAXS. On the other hand, the 1-hexene copolymer forms much thicker lamellae and a broader thickness distribution than ADMET polyethylene. Here, the average thickness l c,av. determined by TEM observation of the copolymer is 1.5 times larger than that calculated from the most probable ethylene sequence length obtained from 13 C NMR, or for a theoretical ethylene sequence length distribution, indicating that the lamellae are composed predominantly of the sparsely branched longer ethylene sequences that are statistically included. The intramolecular sequence distribution is considered significant to determine the lamella thickness and thickness distribution for short chain-branched polyethylenes with a narrow intermolecular chemical composition distribution.

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Influence of Branch Incorporation into the Lamella Crystal on the Crystallization Behavior of Polyethylene with Precisely Spaced Branches

Matsui

Seno

Nozue

et al. 2013

Macromolecules

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Depending on the degree of short chain branch (SCB) incorporation, the crystallization behavior and resultant crystalline structure drastically change in polyethylene with precisely spaced branches. In polyethylene with hexyl branches precisely spaced on every 21st carbon (HB21), only crystallization mediated by a transient hexagonal phase without incorporation of the SCB was observed. On the other hand, in polyethylene with ethyl branches precisely spaced on every 21st carbon (EB21), crystallization behavior was strongly dependent on the crystallization temperature. A thin lamella was formed through crystallization mediated by a hexagonal phase and no thickening occurred at 5–8 °C, while thickening of the transient hexagonal lamellae occurred at 10–15 °C, and one SCB seemed to be incorporated into a crystal stem. At 17 °C, no thickening of the hexagonal phase occurred and a hexagonal phase with sufficient lamella thickness was directly formed from the melt. At 21–28 °C, crystallization mediated by hexago..

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Right-Handed Helical Structure of Expanded Oligo(l-leucine) Containing [Ru(terpyridine)₂]²⁺ Moieties

et al. 2004

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Expanded oligo(l-leucine)s, containing an alternate arrangement of a bis(terpyridine)ruthenium(II) moiety and a l-leucine residue, were synthesized and characterized by 1H NMR, UV, CD, and electrochemical properties. The intensity of CD spectra per ruthenium unit increased with the elongation of the peptide chain. 1H NMR analysis of a tetramer indicated the right-handed helical structure in acetonitrile.

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Unusual Crystallization Behavior of Polyethylene Having Precisely Spaced Branches

et al. 2011

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Cross Nucleation in Polyethylene with Precisely Spaced Ethyl Branches

et al. 2012

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In cross nucleation, an early nucleating crystalline polymorph (A) nucleates another crystalline polymorph (B) of higher or lower thermodynamic stability without undergoing a polymorphic transformation. Although this phenomenon was recently observed in the crystallization process of several small molecules, there has been insufficient evidence for cross nucleation in a crystalline polymer. In this paper, we report cross nucleation behavior during an isothermal crystallization of a crystalline polymer with precisely spaced branches. Polyethylene with ethyl branches on every 21st carbon exhibited growth of new spherulites at the growth front of an initially formed spherulite. The radial growth rate of the initially formed spherulite and the newly grown spherulite calculated from polarized optical microscope data were 0.76 μm/min and 1.01 μm/min, respectively. The growth rate of the newly grown spherulite is faster than that of the initially formed spherulite, which meets a required condition for cross nucleation. Scanning microbeam wide-angle X-ray scattering (WAXS) confirmed that the crystalline polymorphs of the two kinds of spherulites are not the same.

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Shuichiro Seno

Effect of the Sequence Length Distribution on the Lamellar Crystal Thickness and Thickness Distribution of Polyethylene: Perfectly Equisequential ADMET Polyethylene vs Ethylene/α-Olefin Copolymer.

Influence of Branch Incorporation into the Lamella Crystal on the Crystallization Behavior of Polyethylene with Precisely Spaced Branches

Right-Handed Helical Structure of Expanded Oligo(l-leucine) Containing [Ru(terpyridine)₂]²⁺ Moieties

Unusual Crystallization Behavior of Polyethylene Having Precisely Spaced Branches

Cross Nucleation in Polyethylene with Precisely Spaced Ethyl Branches

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Shuichiro Seno

Effect of the Sequence Length Distribution on the Lamellar Crystal Thickness and Thickness Distribution of Polyethylene: Perfectly Equisequential ADMET Polyethylene vs Ethylene/α-Olefin Copolymer.

Influence of Branch Incorporation into the Lamella Crystal on the Crystallization Behavior of Polyethylene with Precisely Spaced Branches

Right-Handed Helical Structure of Expanded Oligo(l-leucine) Containing [Ru(terpyridine)2]2+ Moieties

Unusual Crystallization Behavior of Polyethylene Having Precisely Spaced Branches

Cross Nucleation in Polyethylene with Precisely Spaced Ethyl Branches

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Product

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Right-Handed Helical Structure of Expanded Oligo(l-leucine) Containing [Ru(terpyridine)₂]²⁺ Moieties