Persistence length is commonly used to quantitatively describe the chain rigidity of macromolecules, which represents an important structural parameter governing many physical properties of polymers. Although the mathematical models and experimental measurements on the chain rigidity of conventional single stranded polymers have been well explored and documented, those of the more rigid yet highly intriguing multiple stranded polymers, especially conjugated ladder polymers, are yet not well established. This article introduces the fundamental concepts on macromolecular chain rigidity, as well as the corresponding experimental methods, models, and simulations. Subsequently, representative examples of works done on the chain rigidity of nonladder conjugated polymers and conjugated ladder polymers are reviewed. Last but not least, it provides outlooks on the challenges with respect to the less-investigated chain rigidity of conjugated ladder polymers, including new models to describe and predict chain conformation, synthetic control on structural defects, and insights into the correlation of rigidity and applications.
An extensive polycyclic π-system
with 23 fused rings is synthesized
via a highly efficient borylation reaction, in which four B–N
covalent bonds and four B←N coordinate bonds are formed in
one pot. B←N coordinate bonds not only lock the backbone into
a near-coplanar conformation but also decrease the LUMO energy level
to around −3.82 eV, demonstrating the dual utility of this
strategy for the synthesis of extensive rigid polycyclic molecules
and the development of n-type conjugated materials
for organic electronics and organic photovoltaics.
Conjugated polymers have been widely investigated where the ladder-type conjugated polymers get more attention on account of their rigid backbones and extraordinary properties. However, the understanding of how the rigid...
Determining the doping mechanism of organic semiconductors (OSCs) by neutral dopants, whether through the formation of ion-pair (IP) or charge transfer complex (CTC), remains an open challenge. It is hypothesized...
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