Molecular origins of the thermophysical properties of polymers and modeling of polymer permeation by large molecules

by Belmares, Michael Paul

Abstract (Summary)
NOTE: Text or symbols not renderable in plain ASCII are indicated by [...]. Abstract is included in .pdf document. The molecular origins of the phase transitions of polymers have not been completely understood. The molecular level understanding of polymer behavior is of great technological and scientific value. For example, the melt to glass transition of a polymer [...] is perhaps its most useful quantity describing it. A low [...] polymer will be a useful elastomer and a high Tg polymer will serve for structural purposes. Additionally, sub-glass relaxations are related to polymer aging. Based on a simple poly (ethylene) model, the intramolecular and intermolecular factors governing polymer melting, the glass transition and subglass transitions were investigated through a careful and systematic variation of the torsional potential as well as the cohesive energy of the polymer. The model polymers were studied using constant pressure canonical (Gibbs) dynamics of a system of four polymer chains with one hundred and fifty beads per chain. The advantage of varying systematically the torsional potential is that the morphology of the polymer is controlled, ranging from highly amorphous to highly crystalline, depending on the gauche-trans conformational energy differences. The effect of cohesive energy on the various transitions may also be studied by changing the Van der Waals well depth of each bead in the polymer chain. The first study presented in this chapter is a semi-crystalline case where the gauche energy was +1.14 kcal/mol more stable than the trans energy, and the trans-gauche barrier was 3.01 kcal/mol. A melting point, a glass transition and a tentatively assigned gamma relaxation were characterized. In a second study, the effect of the trans-gauche barrier on the phase transitions of a semi-crystalline polymer (gauche energy=+1.14 kcal/mol) was investigated. In a third study, the effect of the torsional barrier on the glass transition of amorphous polymers (gauche energy=trans energy) was investigated. In a fourth study, the effects of crystallinity on the phase transitions of polymers was investigated by varying the trans-gauche energy differences while maintaining the trans-gauche barrier constant at 4.03 kcal/mol. In the fifth and final study, the effect of the cohesive energy on the polymer phase transitions was investigated by changing the Lennard Jones well depth of each bead while maintaining the torsional potential fixed with a gauche energy of 1.14 kcal/mol relative to the trans energy, and a trans-gauche barrier of 4.03 kcal/mol. Based on these studies, new insights on the general thermo-physical properties of polymers were obtained. A summary of the molecular interpretations of the melting point, glass transition, and sub-glass transitions is provided at the conclusion of this study. Therefore, the strength of this study is its ability to produce numerous phase transitions within a single structural polymer model by a systematic variation of the intermolecular and intramolecular forcefield parameters. This allows an effective comparison of the thermodynamics, the kinetics and morphology of each of the polymer cases.
Bibliographical Information:

Advisor:William A. Goddard

School:California Institute of Technology

School Location:USA - California

Source Type:Master's Thesis



Date of Publication:05/28/1998

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