The melting point (T-m) of the alpha 1 form of isotactic polypropylene (iPP) as a function of its molar mass was studied with molecular dynamics (MD) simulations. The 11mer, 32mer, and 47mer systems were simulated, with the latter displaying a T-m representative of the long-chain polymer. Adopting a methodology developed in previous work, composite (sandwich) configurations consisting of both melt and crystal subdomains in contact with each other were generated, and T-m was determined as that temperature where none of the phases in the sandwich grew at the expense of the other. To deal with the sluggish dynamics of solidification and melting, a constraining potential that drives chains toward helical conformations was added to the Hamiltonian, solid liquid equilibration was achieved at high temperature in the presence of this, potential, and T-m was ultimately obtained through gradual removal of the constraining potential in single-phase solid and liquid simulations by Gibbs Duhem integration. The enthalpy difference Delta H-fus and entropy difference Delta S-fus between single-phase solid and liquid were obtained in the absence of the constraining potential. During the melting process the up down configuration of chains, the structure factor, the order parameter describing chain orientation relative to the c crystallographic axis, and motions characteristic of the rotator phase were studied along with the density and enthalpy.

• 出版日期2016-6-28