How Composition Determines the Properties of Isodimorphic Poly(butylene succinate-ran-butylene azelate) Random Biobased Copolymers: From Single to Double Crystalline Random Copolymers

Abstract: The structure, morphology and thermal properties of biobased and biodegradable poly(butylene succinate-ran-butylene azelate) random copolyesters with a wide composition range were studied. These PBS-ran-PBAz copolymers can crystallize in the entire composition range despite being random, displaying a eutectic point when their melting point is plotted as a function of composition. Wide Angle Xray Scattering (WAXS) studies confirmed isodimorphic behavior where PBS-rich copolymers crystallize with PBS type unit c… Show more

“…In the PBASGT case this Domain is located entirely at the baseline beyond the melting endotherm (see Fig. 4) as it was found also for poly(e-caprolatone) [27] and poly(butylene succinateran-butylene azelate) [28]. Strong and distinct self-nucleation suggests that nucleating agents for crystallization of PBASGT can be found.…”

Nucleation and crystallization of random aliphatic-butylene terephtalate copolyester

“…In the PBASGT case this Domain is located entirely at the baseline beyond the melting endotherm (see Fig. 4) as it was found also for poly(e-caprolatone) [27] and poly(butylene succinateran-butylene azelate) [28]. Strong and distinct self-nucleation suggests that nucleating agents for crystallization of PBASGT can be found.…”

Nucleation and crystallization of random aliphatic-butylene terephtalate copolyester

“…In domain III, the temperature is low enough to partially melt the polymer, while the unmolten crystals anneal into thicker crystals. Figure 4 illustrates the SN behavior of poly(butylene succinate) (PBS) [8]. Two polarized optical micrographs show the typical morphology after cooling the sample from the melt in domain I (after the melt memory is erased) or from domain II (after SN).…”

“…3 can be used to illustrate a strong crystalline memory effect. It is clear that crystalline memory is the only explanation for the behavior of the material in the high T s region within domain II, because full melting had been attained, as judged by the return of the DSC trace to the base line after melting at temperatures above 120 C. Wide-angle X-ray scattering (WAXS) experiments also indicate complete melting at temperatures above 120 C [8].…”

“…This process erases the memory of previous processing and thermal treatments. The memory effect could originate from some embryos (molecular clusters) that survive the thermal treatment and then Reprinted with permission from Arandia et al [8]. Copyright (2015) American Chemical Society become active nuclei once the temperature is lowered [26,44].…”

“…Coincident and fractionated crystallization phenomena are frequently observed in blends and copolymers, and SN can be employed to investigate the origin of the crystallization process [3,8,[87][88][89][90][91][92][93][94][95][96][97][98][99][100]. The work performed by Morales et al [93] has been chosen as an example of the application of SN to a polymer blend.…”

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

Polymers from Monomers Derived from Biomass