APS March Meeting 2017
Volume 62, Number 4
Monday–Friday, March 13–17, 2017;
New Orleans, Louisiana
Session R9: Focus Sesion: Architectural Design of Polymers II
8:00 AM–11:00 AM,
Thursday, March 16, 2017
Room: 268
Sponsoring
Unit:
DPOLY
Chair: Bryan Beckingham, Auburn University
Abstract ID: BAPS.2017.MAR.R9.4
Abstract: R9.00004 : Self-Consistent Field Theories for the Role of Large Length-Scale Architecture in Polymers*
8:36 AM–9:12 AM
Preview Abstract
Abstract
Author:
David Wu
(Depts. of Chemistry and Chemical Engineering, Colorado School of Mines, Golden, CO 80401)
At large length-scales, the architecture of polymers can be described by a
coarse-grained specification of the distribution of branch points and
monomer types within a molecule. This includes molecular topology (e.g.,
cyclic or branched) as well as distances between branch points or chain
ends. Design of large length-scale molecular architecture is appealing
because it offers a universal strategy, independent of monomer chemistry, to
tune properties. Non-linear analogs of linear chains differ in
molecular-scale properties, such as mobility, entanglements, and surface
segregation in blends that are well-known to impact rheological, dynamical,
thermodynamic and surface properties including adhesion and wetting. We have
used Self-Consistent Field (SCF) theories to describe a number of phenomena
associated with large length-scale polymer architecture.
We have predicted the surface composition profiles of non-linear chains in
blends with linear chains. These predictions are in good agreement with
experimental results, including from neutron scattering, on a range of
well-controlled branched (star, pom-pom and end-branched) and cyclic polymer
architectures. Moreover, the theory allows explanation of the segregation
and conformations of branched polymers in terms of effective surface
potentials acting on the end and branch groups. However, for cyclic chains,
which have no end or junction points, a qualitatively different topological
mechanism based on conformational entropy drives cyclic chains to a surface,
consistent with recent neutron reflectivity experiments. We have also used
SCF theory to calculate intramolecular and intermolecular correlations for
polymer chains in the bulk, dilute solution, and trapped at a liquid-liquid
interface. Predictions of chain swelling in dilute star polymer solutions
compare favorably with existing PRISM theory and swelling at an interface
helps explain recent measurements of chain mobility at an oil-water
interface.\\
\\In collaboration with: Renfeng Hu, Colorado School of Mines, and Mark Foster, University of Akron
*This work was supported by NSF Grants No. CBET- 0730692 and No. CBET-0731319.
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2017.MAR.R9.4