π-Conjugated Donor and Donor-Acceptor Metallo-Polymers

Two zinc(II)‐ and two ruthenium(II) containing π‐conjugated metallo‐polymers were synthesized and characterized in detail. We could prove by SEC, analytical ultracentrifugation (AUC) and viscosimetry the ruthenium(II) metallo‐polymers to be high molar mass materials (Mfs = 20 000 g · mol−1 Ru1‐2; Mf...

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Bibliographic Details
Published in:Macromolecular rapid communications. 2010-05, Vol.31 (9-10), p.868-874
Main Authors: Wild, Andreas, Schlütter, Florian, Pavlov, Georges M., Friebe, Christian, Festag, Grit, Winter, Andreas, Hager, Martin D., Cimrová, Vera, Schubert, Ulrich S.
Format: Article
Language:English
Subjects:
analytical ultracentrifugation
conducting polymers
metallo-polymers
solar cells
supramolecular structures
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Summary:Two zinc(II)‐ and two ruthenium(II) containing π‐conjugated metallo‐polymers were synthesized and characterized in detail. We could prove by SEC, analytical ultracentrifugation (AUC) and viscosimetry the ruthenium(II) metallo‐polymers to be high molar mass materials (Mfs = 20 000 g · mol−1 Ru1‐2; Mfs = 34 000 g · mol−1 Ru1) exhibiting intrinsic viscosities of up to [η] = 192 · cm3 · g−1. Applying spin‐coating we produced homogeneous films of the polymers and could, subsequently, investigate the photophysical properties in the solid state. Introducing the Ru(II) metallo‐polymers mixed with PCBM[60] as photoactive layer in bulk‐heterojunction solar cells resulted in very low efficiencies due to morphology problems. The reaction of donor and/or acceptor containing π‐conjugated bisterpyridines with zinc(II) and ruthenium(II) ions results in a series of metallo homo and copolymers. The characterization using SEC, analytical AUC, and viscosimetry prove the ruthenium(II) metallo‐polymers to be high molar mass materials (Mfs = 20 000 g · mol−1, $\overline{M_{\rm n,SEC}}$ = 38 000 g · mol−1 Ru1‐2; Mfs = 34 000 g · mol−1, $\overline{M _{\rm n,SEC}}$ = 88 000 g · mol−1 Ru1) exhibiting intrinsic viscosities of up to [η] = 192 cm3 · g−1.
ISSN:1022-1336
1521-3927
DOI:10.1002/marc.200900889