posted on 2016-07-14, 00:00authored byKris T. Delaney, Glenn H. Fredrickson
We review the latest developments
in computational methods for
direct simulation of fully fluctuating field theories of polymeric
assemblies. In this context, we describe a newly developed theoretical
and computational framework for accurately computing fluctuation-corrected
phase diagrams of mesostructured polymer systems and report the first
such complete phase diagram for a diblock copolymer melt. The method
is based on complex Langevin sampling of a UV regularized field-theoretic
model, with Helmholtz free energies computed using thermodynamic integration.
UV regularization ensures that the free energies do not have an arbitrary
reference; they can be compared between incommensurate phases, permitting
for the first time the computation of order–order transitions
with fluctuation corrections. We further demonstrate that computed
free energies are accurate in the disordered phase by comparison to
perturbation theory on the one-loop level. Importantly, we note that
our method uses no uncontrolled approximations beyond the initial
definition of a coarse-grained molecular model for the polymer melt
or solution. The method can be applied straightforwardly to melts
and solutions containing multiple species with diverse polymer architectures.