<i>In situ</i> AFM study of near‐surface crystallization in PET and PEN

Shinotsuka, Kei; Assender, Hazel E.

doi:10.1002/app.44269

Cited by 15 publications

(31 citation statements)

References 64 publications

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“…As a result, the observed crystallization temperature at the polymer surface ( T cS ) is decreased, resulting in preferential crystallization at the surface under suitable process conditions. As we reported previously, the surface molecules of PET and PEN films crystallize at lower temperatures than the bulk, exhibiting characteristic lamellar crystalline morphologies with, for films this thick, typically an edge‐on morphology.…”

Section: Resultssupporting

confidence: 71%

“…Table shows that, for all compositions, the surface crystallization temperature T cS , determined by AFM observation of relatively thick (436–680 nm) copolymer films, is about 60–90 °C below of the bulk crystallization temperature T cB measured by DSC, meaning that the enhanced local molecular mobility at the surface is observed in PET/PEN copolymers, showing the same trend of crystallizability with composition. The heating rates to induce the cold crystallization in this study were different between the DSC and AFM measurements, however, previous studies on various polymers, including our previous articles on PET and PEN, have shown that the T gS is lower than the T gB , and that there are distinct morphological differences observed at the onset of surface crystallization, and the subsequent crystallization that occurs at T cB , hence it is reasonable to infer that the crystallization temperature differences between T cB by DSC and T cS by AFM in these copolymer materials are also as a result of the depressed T gS .…”

Section: Resultscontrasting

confidence: 61%

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Synthesis of statistical PET/PEN random block copolymers and their crystallizability in the bulk and at the surface

Shinotsuka

Assender

Claridge

2018

J of Applied Polymer Sci

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A series of PET/PEN copolyesters were synthesized by molten transesterification. The degree of randomness and the sequence length of the copolymers were determined by 1H NMR spectroscopy, and the changes in the bulk glass transition temperature (TgB), bulk crystallization temperature (TcB), and bulk melting temperature (TmB) were observed by DSC. A clear relationship was obtained between the observed enthalpy of melting (ΔHm) and degree of randomness (B), and TmB was suppressed for the midcompositions. As with their homopolymer counterparts, there was significant depression in crystallization temperature at the surface (TcS) of the random/block copolymers compared with the bulk, and so surface‐localized crystallization could be induced in spin‐coated thick films (thickness ranging from ca. 400 to 700 nm) by annealing at a temperature in which the surface region is mobile, but the bulk is not. The formation of these clear surface crystals allows the morphology to be directly imaged by AFM, and we observed that the crystallizability and the lamellar morphology of the surface crystals deviated from those of the original homopolymers, depending on the mixing ratio of PET/PEN and degree of randomness. © 2018 Wiley Periodicals, Inc. J. Appl. Polym. Sci. 2018, 135, 46515.

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Section: Resultssupporting

confidence: 71%

Section: Resultscontrasting

confidence: 61%

Synthesis of statistical PET/PEN random block copolymers and their crystallizability in the bulk and at the surface

Shinotsuka

Assender

Claridge

2018

J of Applied Polymer Sci

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“…This phenomenon occurs in a temperature range not exceeding 15°C before the bulk crystallization and it is exacerbated in the case of relatively thick films that exceed a few 100 nm. Indeed, thick films prevent the influence of the substrate, which restricts the molecular mobility in the bulk layer of the polymer at the bottom interface . This will contribute to the increase of the average surface roughness as can be seen in Figure .…”

Section: Resultsmentioning

confidence: 99%

Annealing for the improvement of the capabilities of parylene C as electret

Kachroudi

Lagomarsini

Mareau

et al. 2018

J of Applied Polymer Sci

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Parylene C is a polymer elaborated by chemical vapor deposition and is particularly useful for the coating of deformed structures. New‐generation soft energy harvesting electrostatic generators can be of complex shape. These generators need electret material in order for them to function. It could thus be interesting to incorporate parylene C in this device. However, this polymer suffers from bad retention of trapped charges after corona discharge and a poor thermal stability of these charges. In this work, parylene C polymers were subjected to specific annealing before corona charging. This induces strong changes in the crystallinity of the material. Atomic force microscopy and X‐ray diffraction quantified the crystalline nature of parylene C following the annealing temperature. Surface potential decay of corona‐charged parylene C demonstrated that annealing to about 150°C is beneficial for the trapping of charges for a long time (analysis over 12 days). At the same time, thermal stability of the electret parylene C is achieved up to 100°C. Spherulites with a specific area close to the surface of the polymer could explain such performances due to their influence on the distribution of traps. Dielectric analysis does not confirm that the decay of surface charges is correlated to the dynamics of polymer chains, although the moving of chains probably influences the flowing of these charges. In sum, annealed parylene C appears to be a new interesting candidate for electret‐based electrostatic generators. © 2018 Wiley Periodicals, Inc. J. Appl. Polym. Sci. 2019, 136, 46908.

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“…A full description of this method is given in Shinotsuka and Assender. [24] 2.5 | Force-distance curve analysis…”

Section: H Nmr Spectroscopymentioning

confidence: 99%

“…The force-distance behavior from AFM curves has been used by multiple groups for the determination of a change in properties, associated with T g . [18,[24][25][26][27][28] For measurements reported here, the T g at the near surface was determined from the observed change in the snap-off displacement vs temperature. [18,24,25] The snap-off displacement at each temperature was taken as the mean of 30 measurements from different locations on the sample.…”

Section: H Nmr Spectroscopymentioning

confidence: 99%

Crystalline morphologies at the surface of PET/PEN random copolymer films

Shinotsuka

Assender

2019

Polymer Crystallization

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Crystalline Morphologies of the Surface of Random Copolymer Films In their work reported in article e10087, Shinotsuka and Assender demonstrate that polymers can crystallize preferentially at the free surface when annealed at temperatures between the surface and bulk glass transition temperatures, forming dendritic structures observable by AFM. This is a near‐surface rather than a thin‐film phenomenon. A 436nm thick 50/50 PET/PEN random copolymer shows surface crystallization at a temperature 90°C lower than bulk crystallization. In 31nm films, the crystallization is affected by the confinement of the thin film and the first stages of crystallization, near the nucleus, form with one morphology (orientation) and then switch to clearer dendrites, likely of edge‐on orientation. (DOI: https://doi.org/10.1002/pcr2.10087)

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In situ AFM study of near‐surface crystallization in PET and PEN

Cited by 15 publications

References 64 publications

Synthesis of statistical PET/PEN random block copolymers and their crystallizability in the bulk and at the surface

Synthesis of statistical PET/PEN random block copolymers and their crystallizability in the bulk and at the surface

Annealing for the improvement of the capabilities of parylene C as electret

Crystalline morphologies at the surface of PET/PEN random copolymer films

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