APS March Meeting 2010
Volume 55, Number 2
Monday–Friday, March 15–19, 2010;
Portland, Oregon
Session J4: Dynamics of Polymers on Multi-Length Scales: Melts
11:15 AM–2:15 PM,
Tuesday, March 16, 2010
Room: Oregon Ballroom 204
Sponsoring
Unit:
DPOLY
Chair: Anna Balazs, University of Pittsburgh
Abstract ID: BAPS.2010.MAR.J4.5
Abstract: J4.00005 : Rheology of Entangled Polymer Melts: Recent Results from Molecular Dynamics Simulations
1:39 PM–2:15 PM
Preview Abstract
Abstract
Author:
Ronald G. Larson
(University of Michigan)
Models for the rheology of entangled polymers, based on the
``tube" model are now open to investigation by molecular dynamics
simulations using the Kremer-Grest ``pearl necklace" model of
polymers. Here, we present extensive molecular dynamics
simulations of the dynamics and stress in entangled melts of
branched polymers and of ``binary blends" of diluted long probe
chains entangled with a matrix of shorter chains. Direct evidence
of ``hierarchical relaxation" is obtained in diffusion of
asymmetric star polymers, wherein the rate of slow diffusion of
the branch point is controlled by the much faster motion of the
attached arm. In studies of binary blends, the ratio of their
lengths is varied over a wide range to cover the crossover from
the chain reptation regime to tube Rouse motion regime of the
long probe chains. Reducing the matrix chain length results in a
faster decay of the dynamic structure factor of the probe chains,
in good agreement with recent Neutron Spin Echo experiments. The
diffusion of the long chains, measured by the mean square
displacements of the monomers and the centers of mass of the
chains, demonstrates a systematic speed-up relative to the pure
reptation behavior expected for monodisperse melts of
sufficiently long polymers. On the other hand, the diffusion of
the matrix chains is only weakly perturbed by the diluted long
probe chains. The simulation results are qualitatively consistent
with the theoretical predictions based on constraint release
Rouse model, but a detailed comparison reveals the existence of a
broad distribution of the disentanglement rates, which is partly
confirmed by an analysis of the packing and diffusion of the
matrix chains in the tube region of the probe chains. A
coarse-grained simulation model based on the tube Rouse motion
model with incorporation of the probability distribution of the
tube segment jump rates is developed and shows results
qualitatively consistent with the fine scale molecular dynamics
simulations.
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2010.MAR.J4.5