Physical Origin of the Mass Dependence of Glass Transition Temperature and Fragility of Polymer Liquids
QL Yuan and XL Xu and JF Douglas and WS Xu, MACROMOLECULES, 58, 9528-9545 (2025).
DOI: 10.1021/acs.macromol.4c02991
Recently, there has been great interest in the prediction of the glass transition temperature T g and fragility of polymer materials in connection with the need for utilizing these material parameters to guide materials design and characterization. Most of these studies have involved empirical correlations of T g and fragility with various thermodynamic and structural properties in the absence of a validated predictive theoretical framework. In the present paper, we first focus on the variation of T g and fragility of polymer materials with molecular mass (M) calculated from the generalized entropy theory (GET), a synthesis of the lattice cluster theory of polymer thermodynamics with the Adam-Gibbs model relating the structural relaxation time to the fluid configurational entropy density S c , and determined from molecular dynamics simulations of a coarse-grained polymer melt having variable chain stiffness. In addition to providing predictions of the M variation of both T g and fragility for variable chain rigidity, molecular structure, and intermolecular interaction strength, the GET provides novel insights into the physical origin of changes in these parameters in terms of the magnitude of S c in its high temperature athermal state, S c *, where relaxation is nearly Arrhenius. The calculation of S c * based on an analytic theory is notably a unique capability of the GET. We show that the observed trends can be understood by analogy with crystallization and equilibrium polymerization transitions, where S c * influences the melting temperature and the self-assembly transition sharpness in a similar fashion, as found correspondingly in the GET for T g and fragility. Basic experimental trends in T g and fragility with varying M are reproduced by both the GET calculations and simulation results, offering a new theoretical framework for predicting T g and fragility for various applications. In contrast to the conventional free volume model, our theoretical framework provides a new interpretation of the M dependence of T g and fragility in terms of frustrated packing of polymers, arising from the constraint of chain connectivity.
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