Modeling of the kinetics of polymorphic isothermal crystallization of poly (L-lactide) subjected to uniaxial molecular orientation

Kinetic model of polymorphic crystallization of uniaxially oriented amorphous poly(L-lactide) under isothermal conditions is formulated basing on the Hoffman-Lauritzen theory. Entire ranges of the crystallization temperatures and amorphous orientation factor are considered. The inverse transformation half-times of the amorphous phase to the individual polymorphs, between the unstable & alpha;' and stable & alpha; polymorphs, as well as of the overall crystallization are discussed. The kinetic effects are assigned to the decrease in the amorphous phase entropy caused by deformation and orientation of the flexible chain macromolecules.The model predicts that crystallization to the stable & alpha; form is controlled by the rate of transformation of the amorphous phase to & alpha;'. Concentration of heterogeneous nuclei typical for commercial polymer is assumed and in this case the role of homogeneous nucleation in the transformation kinetics is negligible. The role of homogeneous nucleation at different hypothetical concentrations of heterogeneous nuclei is estimated vs. the Hermans amorphous orientation factor and crystallization temperature. Ranges of domination of heterogeneous and homogeneous nucleation are predicted as dependent on the heterogeneous nuclei concentration.The increase of the overall oriented crystallization rate is predicted for the entire crystallization temperature range as resulting from the increase of the amorphous-to-& alpha;& PRIME; transformation rate at increasing amorphous orientation. The model provides a view on the mechanisms for possible control of the development of & alpha;'/& alpha; composition by adjusting the crystallization time vs. orientation and temperature.

Automated summary

This paper formulates a kinetic model for the polymorphic crystallization of uniaxially oriented amorphous poly(L-lactide) based on the Hoffman-Lauritzen theory. The model considers the entire ranges of crystallization temperatures and amorphous orientation factor. The model predicts that the crystallization to the stable α form is controlled by the rate of transformation from the amorphous phase to α'.