posted on 2018-10-01, 00:00authored byPeter B. Rapp, Ahmad K. Omar, Bradley R. Silverman, Zhen-Gang Wang, David A. Tirrell
Networks
assembled by reversible association of telechelic polymers constitute
a common class of soft materials. Various mechanisms of chain migration
in associative networks have been proposed; yet there remains little
quantitative experimental data to discriminate among them. Proposed
mechanisms for chain migration include multichain aggregate diffusion
as well as single-chain mechanisms such as “walking”
and “hopping”, wherein diffusion is achieved by either
partial (“walking”) or complete (“hopping”)
disengagement of the associated chain segments. Here, we provide evidence
that hopping can dominate the effective diffusion of chains in associative
networks due to a strong entropic penalty for bridge formation imposed
by local network structure; chains become conformationally restricted
upon association with two or more spatially separated binding sites.
This restriction decreases the effective binding strength of chains
with multiple associative domains, thereby increasing the probability
that a chain will hop. For telechelic chains this manifests as binding
asymmetry, wherein the first association is effectively stronger than
the second. We derive a simple thermodynamic model that predicts the
fraction of chains that are free to hop as a function of tunable molecular
and network properties. A large set of self-diffusivity measurements
on a series of model associative polymers finds good agreement with
this model.