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Cyclic topology effects on the morphology of biocompatible and environment-friendly poly( -caprolactone) under nanoscale film confinement

A series of cyclic poly( -caprolactone)s ( c -PCLs) with extremely high purity have been prepared and quantitatively investigated in terms of the impact of molecular topology on the nanoscale film morphological structure. Quantitative synchrotron grazing incidence small angle X-ray scattering analys...

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Published in:Polymer chemistry 2020-07, Vol.11 (28), p.463-4638
Main Authors: Xiang, Li, Ryu, Wonyeong, Kim, Jehan, Ree, Moonhor
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creator Xiang, Li
Ryu, Wonyeong
Kim, Jehan
Ree, Moonhor
description A series of cyclic poly( -caprolactone)s ( c -PCLs) with extremely high purity have been prepared and quantitatively investigated in terms of the impact of molecular topology on the nanoscale film morphological structure. Quantitative synchrotron grazing incidence small angle X-ray scattering analysis found that c -PCLs, in comparison with their linear counterparts ( l -PCLs), exclusively form a horizontal lamellar structure with a shorter long period, characterized by a thicker crystalline layer, thicker and denser interfacial layers and a thinner amorphous layer. Grazing incidence wide angle scattering analysis additionally confirmed higher crystallinities for c -PCLs, which were further supported by synchrotron X-ray reflectivity analysis. Overall, the quantitative structural analyses of this study provide for the first time comprehensive insights into cyclic topology effects on the nanoscale film morphology of biocompatible and environment-friendly PCL. Quantitative grazing incidence X-ray scattering analysis combined with X-ray reflectivity using synchrotron radiation sources was explored for the first time cyclic topology effects on the nanoscale film morphology of poly( -caprolactone).
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subjects Biocompatibility
Crystal structure
Crystallinity
Data analysis
Grazing incidence
Lamellar structure
Morphology
Polymer chemistry
Small angle X ray scattering
Synchrotron radiation
Topology
title Cyclic topology effects on the morphology of biocompatible and environment-friendly poly( -caprolactone) under nanoscale film confinement
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