posted on 2024-01-08, 22:04authored byArielle Mann, Chengyuan Wang, Bianca L. Dumlao, Marcus Weck
Poly(p-phenylenevinylene)s (PPVs) featuring
complex
side-chains, to date, have only been synthesized by nonliving polymerization
methods which have no control over PPV molecular weights, dispersities,
or end groups. [2.2]Paracyclophane-1,9-diene (pCpd) has gained attention
as a monomer for its ability to be ring-opened to PPV in a living
fashion. pCpd, an organic cyclic scaffold with planar chirality, has
seen minimal structural diversity due to the harsh reaction conditions
required to afford the highly strained compound. Herein, we introduce
a general method to overcome this by targeting the synthesis of a
monohydroxy-pCpd via mono-demethylation of a dialkoxy-pCpd. The monohydroxy-pCpd
can then be functionalized easily, which we demonstrate using three
distinct side-chains with four moieties commonly incorporated in conjugated
polymers: an alkyl bromide, an oligo(ethylene glycol) chain, an enantiomerically
pure side-chain, and a Boc-protected amine. These monofunctionalized-pCpds
were investigated as monomers in the ring-opening metathesis polymerization
(ROMP) to afford functionalized PPVs in a living manner. The functional-group-containing
PPVs are synthesized with full control over their end groups, repeat
units, and dispersities. The feasibility of post-polymerization modifications
to incorporate any desired moiety to PPV fabricated by this method
was demonstrated using an azide–alkyne click reaction. All
synthesized PPVs were soluble in organic solvents and display the
same fluorescent emission, indicating their conjugated backbones are
unaltered.