On the chain length dependence of local correlations in polymer melts and a perturbation theory of symmetric polymer blends

Abstract

The self-consistent field (SCF) theory of dense polymer liquids assumes that short-range correlations are almost independent of how monomers are connected into polymers. Some limits of this idea are explored in the context of a perturbation theory for mixtures of structurally identical polymer species, A and B, in which the AB pair interaction differs slightly from the AA and BB interaction, and the difference is controlled by a parameter alpha Expanding the free energy to O(α) yields an excess free energy of the form alpha z(N)φAφB, in both lattice and continuum models, where z(N) is a measure of the number of inter-molecular near neighbors of each monomer in a one-component liquid. This quantity decreases slightly with increasing N because the self-concentration of monomers from the same chain is slightly higher for longer chains, creating a deeper correlation hole for longer chains. We analyze the resulting N-dependence, and predict that z(N) = z∞[1 + β N-1/2], where N is an invariant degree of polymerization, and β=(6/π)3/2. This and other predictions are confirmed by comparison to simulations. We also propose a way to estimate the effective interaction parameter appropriate for comparisons of simulation data to SCF theory and to coarse-grained theories of corrections to SCF theory, which is based on an extrapolation of coefficients in this perturbation theory to the limit N ∞. We show that a renormalized one-loop theory contains a quantitatively correct description of the N-dependence of local structure studied here.