posted on 2008-03-25, 00:00authored byMark Burnworth, James D. Mendez, Michael Schroeter, Stuart J. Rowan, Christoph Weder
The self-assembly polymerization of ditopic macromolecules through metal−ligand binding is an
attractive framework for the preparation of high-molecular-weight metallo-supramolecular polymers. This approach
was utilized here for the polymerization of a conjugated macromonomer (1) that was derived by functionalizing
a low-molecular-weight poly(2,5-dialkoxy-p-phenylene ethynylene) (PPE) core with 2,6-bis(1‘-methylbenzimidazolyl)pyridine (Mebip) ligands on the two terminal positions. To minimize electronic interactions between the
PPE moieties and the metal−ligand complexes, nonconjugated hexamethylene spacers were introduced between
the PPE and Mebip building blocks. The supramolecular polymerization of macromonomer 1 with equimolar
amounts of Zn2+ or Fe2+ resulted in polymers, which exhibit appreciable mechanical properties (loss moduli of
[1·Zn(ClO4)2]n and [1·Fe(ClO4)2]n at 25 °C are ca. 450 and 610 MPa, respectively), but on account of their
dynamic, reversible nature offer the ease of processing of low-molecular-weight compounds. The optoelectronic
properties of these metallopolymers are similar to those of the parent PPE and demonstrate that the functionalities
of semiconducting building blocks and coordination chain extenders can be effectively decoupled by a short,
nonconjugated spacer.