TY - JOUR
T1 - Analysis of multiple melting behavior of spherulites comprising ring-band shell/ringless core in polymorphic poly(butylene adipate)
AU - Woo, E. M.
AU - Yen, Kai Cheng
AU - Wu, Ming Chien
PY - 2008/5/1
Y1 - 2008/5/1
N2 - In-depth interpretation of ring-banded spherulitic morphology, crystals, polymorphism, and complex melting behavior in poly(1,4-butylene adipate) (PBA) were analyzed via a procedure of designing composite core-shell spherulites, in which two lamellar patterns (ring-band vs. ringless) were packed by subjecting to crystallization at two-step temperature schemes with specific temperatures and times. By heating to 52 °C and holding at that temperature for 30 min annealing, the core can be stripped off by melting, and analysis specifically on the ring-shell portion (with the ringless core stripped by controlled melting) proves that the highest melting peak (P4 at 55-57 °C) is likely associated with melting of the ring-band lamellae. Furthermore, the unusually complex multiple melting in PBA can be attributed to all three widely proposed mechanisms: (1) multiple types of lamellae preexisting in crystallized PBA, (2) scan/heating induced remelting/reorganization, and (3) polymorphism of dual crystal cells. In addition, this study evidently shows that the extinction rings within the ring-banded shell, regardless of alternate edge-on and flat-on mechanism or alternative origins, can be of all singly α-crystal form, either initially or upon post-heating temperature-induced transformation. Thus, the type of crystal forms (α or β) in polymorphic PBA is mainly associated with temperature of crystallization (Tc = 28 or 35 °C), and not likely with lamellar orientation (flat-on or edge-on).
AB - In-depth interpretation of ring-banded spherulitic morphology, crystals, polymorphism, and complex melting behavior in poly(1,4-butylene adipate) (PBA) were analyzed via a procedure of designing composite core-shell spherulites, in which two lamellar patterns (ring-band vs. ringless) were packed by subjecting to crystallization at two-step temperature schemes with specific temperatures and times. By heating to 52 °C and holding at that temperature for 30 min annealing, the core can be stripped off by melting, and analysis specifically on the ring-shell portion (with the ringless core stripped by controlled melting) proves that the highest melting peak (P4 at 55-57 °C) is likely associated with melting of the ring-band lamellae. Furthermore, the unusually complex multiple melting in PBA can be attributed to all three widely proposed mechanisms: (1) multiple types of lamellae preexisting in crystallized PBA, (2) scan/heating induced remelting/reorganization, and (3) polymorphism of dual crystal cells. In addition, this study evidently shows that the extinction rings within the ring-banded shell, regardless of alternate edge-on and flat-on mechanism or alternative origins, can be of all singly α-crystal form, either initially or upon post-heating temperature-induced transformation. Thus, the type of crystal forms (α or β) in polymorphic PBA is mainly associated with temperature of crystallization (Tc = 28 or 35 °C), and not likely with lamellar orientation (flat-on or edge-on).
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U2 - 10.1002/polb.21423
DO - 10.1002/polb.21423
M3 - Article
AN - SCOPUS:42549170143
SN - 0887-6266
VL - 46
SP - 892
EP - 899
JO - Journal of Polymer Science, Part B: Polymer Physics
JF - Journal of Polymer Science, Part B: Polymer Physics
IS - 9
ER -