posted on 2012-08-15, 00:00authored byPeter
A. Korevaar, Charley Schaefer, Tom F. A. de Greef, E. W. Meijer
The influence of the ratio between poor and good solvent
on the
stability and dynamics of supramolecular polymers is studied via a
combination of experiments and simulations. Step-wise addition of
good solvent to supramolecular polymers assembled via a cooperative
(nucleated) growth mechanism results in complete disassembly at a
critical good/poor solvent ratio. In contrast, gradual disassembly
profiles upon addition of good solvent are observed for isodesmic
(non-nucleated) systems. Due to the weak association of good solvent
molecules to monomers, the solvent-dependent aggregate stability can
be described by a linear free-energy relationship. With respect to
dynamics, the depolymerization of π-conjugated oligo(p-phenylene vinylene) (OPV) assemblies in methylcyclohexane
(MCH) upon addition of chloroform as a good solvent is shown to proceed
with a minimum rate around a critical chloroform/MCH solvent ratio.
This minimum disassembly rate bears an intriguing resemblance to phenomena
observed in protein unfolding, where minimum rates are observed at
the thermodynamic midpoint of a protein denaturation experiment. A
kinetic nucleation–elongation model in which the rate constants
explicitly depend on the good solvent fraction is developed to rationalize
the kinetic traces and further extend the insights by simulation.
It is shown that cooperativity, i.e., the nucleation of new aggregates,
plays a key role in the minimum polymerization and depolymerization
rate at the critical solvent composition. Importantly, this shows
that the mixing protocol by which one-dimensional aggregates are prepared
via solution-based processing using good/poor solvent mixtures is
of major influence on self-assembly dynamics.