Your search keyword '"Samara, C. T."' showing total 2 results

1. Effect of Tacticity on the Molecular Dynamics of Polypropylene Melts

Author

Antoniadis, S. J., Samara, C. T., and Theodorou, D. N.

Abstract

In this work we present the results of molecular dynamics simulations of polypropylene melts of different tacticities, based on a recently published molecular model. Volumetric properties of isotactic, syndiotactic, and atactic polypropylene exhibit no significant differences and are in good agreement with experimental data. The simulated X-ray diffraction patterns agree well with experimental scattering results, suggesting that the simulated structure is realistic. Methyl−methyl intramolecular distribution functions exhibit several peaks characteristic of the conformations adopted by each tacticity. Conformational distributions of dyads reveal a preference for tg conformers in isotactic polypropylene (iPP) and for tt in syndiotactic polypropylene (sPP), which is closely related to the type of helices observed in the crystalline form. Time autocorrelation functions have been computed for pendant (C−CH3) bonds and skeletal torsion angles. Predicted correlation times are found to be shortest for the iPP melt and longest for the sPP melt; a simple estimation of barriers to t → g conformational transitions explains this difference in the dynamics.

Published

1999

2. Molecular Dynamics of Atactic Polypropylene Melts

Author

Antoniadis, S. J., Samara, C. T., and Theodorou, D. N.

Abstract

A molecular model suitable for predicting thermodynamic and dynamical properties of polypropylene is developed. A systematic effort is undertaken to improve the representation of the potential. Molecular dynamics (MD) simulations of atactic polypropylene, based on the new potential, indicate good agreement of volumetric properties and of the solubility parameter with experimental data for a wide range of temperatures and pressures. To characterize the system dynamics at the segmental level, time autocorrelation functions have been computed for pendant (C−CH3) bonds and skeletal torsion angles. Predicted correlation times are in good agreement with NMR measurements. An analysis of conformational transitions reveals the development of spatial heterogeneity in the segmental mobility at constant observation time; this heterogeneity increases strongly with decreasing temperature. The rate of conformational isomerizations in the polymer has been analyzed by constructing a hazard plot of first passage times, which indicates a sharp decrease in the number of bonds capable of conformational transition at low temperature.

Published

1998