Studies of the crystallization, melting, and morphology of random ethylene/1-octene
copolymers by a combination of differential scanning calorimetry and atomic force microscopy are
presented. Two different crystallization mechanisms prevalent in separate temperature ranges are inferred
from the effect of cooling rate on the temperature dependence of crystallinity, from the reversibility of
crystallization/melting phenomena at the lowest temperatures, and from the temperature dependence of
kinetic parameters describing isothermal crystallization and melting. Morphological studies of these
copolymers demonstrate the coexistence of two distinct crystalline superstructures (i.e., lamellae and
fringed-micellar or chain cluster structures) which we tentatively associate with the two crystallization
mechanisms. The multiple melting behavior of these copolymers is associated with the existence of separate
morphological entities and is not explained by a mechanism of melting−recrystallization−remelting.
Finally, the upward shift of the melting endotherm of secondary crystals (i.e., these formed by the low-temperature mechanism) with longer crystallization times is explained by a decrease in the molar
conformational entropy of the remaining amorphous fraction as a result of secondary crystallization.
The phase behavior and miscibility of poly(c-caprolactone) (PCL)/polycarbonate (PC) blends have been investigated with DSC, cloud-point measurement, TGA, FTIR, NMR, and small-angle neutron scattering (SANS). Thermal analysis results indicated that the PCL-rich blends are semicrystallinel semicrystalline at room temperature. At about 30% PC incorporation, the PCL crystallinity showed amarked reduction, whereas the PC crystallinity approached amaximum. The composition dependence of Tgexhibited a discontinuity (cusp) and was critically analyzed using the classical equations of Gordon-Taylor and Fox and the free volume theory of Braun-Kovace. Combination of the Fox and Braun-Kovace equations accurately reproduced the T,-composition dependence. Thermal stability of the blends, as measured by the onset degradation temperature in air, increased with increasing PC. FTIR results coupled with lSC NMR findings supported the hypothesis that the blends primarily degraded via thermally-induced chain scission of PCL as evidenced by the evolution of COS. SANS studies on the deuterated PC-rich blends revealed that the scattering intensity first remained fairly constant with increasing temperature and then increased sharply at temperatures above the blend Tp The sudden rise in the scattering intensity was attributed to crystallization of PC resulting from prolonged annealing. Results derived from the RPA analysis of the SANS profiles measured at 30 "C for the deuterated PC-rich blends and those obtained from the melting point depression analysis of the PCL-rich blends suggested favorable blend interactions as reflected by the negative sign of the x parameter.
Crystalline morphologies of poly(e-caprolactone) (PCL) and deuterated polycarbonate (d-PC) blends were studied by small-angle neutron and X-ray scattering (SANS and SAXS). Measurements were conducted at both room temperature and temperatures above the melting point (60 °C) of PCL. Due to the different contrast between the phases for neutrons and X-rays, SANS exhibited a monotonic drop in intensity with increasing scattering angle while SAXS showed lamellar (peak) scattering. A two-correlation length model provided an excellent fit for the SANS data over the entire composition range. This model reproduced not only the shape but also the absolute magnitude of the scattering curves. The long range correlation length (~10s A) and the short range correlation length (-10 A) derived from this model are inferred to be associated with the crystalline PC domain and the local cluster in the amorphous phase (possibly resulting from crystallization-induced phase separation), respectively. Both the long range correlation length obtained from SANS and the long period measured from SAXS showed identical composition dependence. This further supports the applicability of the two-correlation length model and our interpretation.
Evolution of the poly(ecapro1actone) (PCL) lamellae in blends of PCL/PC (polycarbonate) was monitored by synchrotron small-angle X-ray scattering (SAXS). Theeffecta of crystallization temperature, PC concentration, and PC crystallinity on the PCL lamellar growth in the PCL-rich blends were investigated. The half-crystallization time derived from the temporal change of the peak intensity increased with crystallization temperature and generally increased with the addition of PC. For a given blend composition, the lamellar growth rate increased with increasing PC crystallinity. The interlamellar spacing initially varied with time and then approached a plateau value at the later stage of crystallization. An insertion mechanism is proposed in which the PCL is crystallized in the amorphous intralamellar phase. This model is also consistent with the quantitative SAXS results? which suggested that random mixing of PCL and PC lamellae occurred in the semicrystalline (PCL)/semicrystalline (PC) state.
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