Understanding, Quantifying, and Controlling the Molecular Ordering of Semi-conducting Polymers: From Novices to Experts and Amorphous to Perfect Crystals

Molecular packing, crystallinity, and texture of semiconducting polymers are often critical to performance. Although frame-works exist to quantify the ordering, interpretations are often just qualitative, resulting in imprecise and liberal use of terminology. Here, we reemphasize the continuity of the degree of molecular ordering and advocate that a more nuanced and consistent terminology is used with regards to crystallinity, semicyrstallinity, paracrystallinity, crystallite/aggregate, and related characteristics. We are motivated in part by our own imprecise and inconsistent use of terminology and the need to have a primer or tutorial reference to teach new group members. We show that a deeper understanding can be achieved by combining grazing-incidence wide-angle X-ray scattering and differential scanning calorimetry. We classify a broad range of representative polymers into four proposed categories based on the quantitative analysis of molecular order based on the paracrystalline disorder parameter (g). A small database is presented for over 10 representative conjugated and insulating polymers ranging from amorphous to semicrystalline. Finally, we outline the challenges to rationally design perfect polymer crystals and propose a new molecular design approach that envisions conceptual molecular grafting that is akin to strained and unstrained hetero-epitaxy in classic (compound) semiconductors thin film growth.
Comment: Review article, 37 pages, 9 figures