posted on 2018-02-05, 11:48authored byJiangping Xu, Hang Zhou, Qing Yu, Ian Manners, Mitchell A. Winnik
Nucleated self-assembly in selective
solvents of core-crystalline
block copolymers (BCPs) is a special case of living supramolecular
polymerization, leading to rodlike micelles of controlled and uniform
length. For the crystallization-driven self-assembly of PFS-containing
BCPs (PFS = polyferrocenyldimethylsilane), the formation of block
comicelles by sequential addition of different BCPs is well-established.
But there are only a few examples of living copolymerization, the
simultaneous addition of pairs of BCPs with different corona-forming
chains. At present, relatively little is known about the competitive
kinetics of different BCPs crystallizing on a common seed. Here we
report a systematic study of the competitive seeded growth kinetics
of pairs of linear PFS-containing BCPs and show that one can manipulate
the kinetics to control the morphology of the comicelles. We found
that the seeded-growth kinetics of the individual BCP unimer dominates
the coassembly behavior and thus the morphology of the corona. Patchy
comicelles with microphase-segregated corona chains are formed when
the epitaxial growth rates of the two different BCPs on the common
seed are similar. In contrast, factors that lead to dissimilar growth
rates (long corona-forming blocks or introduction of charges on corona-forming
chains) promote large-scale separation of the corona blocks, leading
to block comicelles. Because the termini of the comicelles remain
living, they can further direct the growth of unimers, resulting in
hierarchical block comicelles with patchy blocks and single-component
(homo) blocks. Furthermore, the patchy comicelles can be loaded with
either gold or platinum nanoparticles, generating organic–inorganic
hybrid materials with potential application in catalysis.