| A regio-regular (RR) conjugated copolymer based on cyclopenta[2,1-b:3,4- b]dithiophene (CDT) and pyridal[2,1,3]thiadiazole (PT) structural units was prepared by using polymerization reactions involving reactants specifically designed to avoid random orientation of the asymmetric PT heterocycle. Compared to its regio-irregular (RI) counterpart, the RR polymer exhibits a two orders of magnitude increase in hole mobility from 0.005 to 0.6 cm2V -1s-1. To probe the reason for this difference in mobility, we examined the crystalline structure and its orientation in thin films of both copolymers as a function of depth via grazing incidence wide angle X-ray scattering (GIWAXS). In the RI film, the pi-pi stacking direction of the crystallites is mainly perpendicular to the substrate normal (edge-on orientation) while in the RR film the crystallites adopt a mixed pi-pi stacking orientation in the center of the film as well as near the interface between the polymer and the dielectric layer. These results demonstrate that control of backbone regularity is another important design criterion to consider in the synthesis and optimization of new conjugated copolymers with asymmetric structural units.;Solution processed organic photovoltaic devices (OPVs) have emerged as a promising sustainable energy technology due to their ease of fabrication, potential to enable low-cost manufacturing, and ability to be incorporated onto light-weight flexible substrates. To date, the most efficacious OPV device architecture, the bulk heterojunction (BHJ), consists of a blend of a light-harvesting conjugated organic electron donating molecule and a strong electron-accepting compound (usually a soluble fullerene derivative e.g. [6,6]-phenyl C71 butyric acid methyl ester (PC71BM).;BHJ layer morphology, which has been shown to be highly dependent on processing, has a significant effect on OPV performance. It is postulated that optimal BHJ morphologies consist of discrete bicontinuous nanoscale domains of each moiety, on the order of the exciton diffusion length, which extend vertically from each electrode, thereby increasing the surface area of the domains and forming continuous conducting pathways for efficient charge extraction and transfer. An optimal morphology, however, is seldom achieved during film formation; therefore, a number of processing techniques, such as thermal and sol vent annealing, and the addition of solvent additives to the casting solution have been explored to control the morphology in order to attain the multiple structural requirements. Solvent additive processing, a technique that is used in most record performing polymer:fullerene BHJ solar cell devices, involves the addition of small volumes of a high boiling point liquid to the BHJ casting solu- tion. Solvent additive processing, with 1,8-diiodooctane (DIO) as the additive, has recently been employed in solution processable small molecule (SPSM) BHJ systems, showing similar drastic effects on several device metrics and ultimately the power conversion efficiency (PCE). A recent SPSM study delineates how the volume of solvent additive used affects device performance: when 0.4 v/v% of DIO was used, the PCE increased from 1.8 to 7%, while a deterioration in the PCE to less than 1% occurred when only 1 v/v% of DIO was used.;Several structural characterization techniques, such as grazing incidence wide and small-angle X-ray scattering (GIWAXS and GISAXS), and energy filtered transmission electron microscopy (EF-TEM), were used to investigate structure-processing-property relationships in additive-treated SPSM BHJ films and were correlated to device performance. Scattering experiments showed that the use of additives had several effects on the structure of the BHJ at multiple length scales: e.g. the number and orientation of SPSM crystallites, different pi-pi stacking distances, and the nano-scale domain size. Additionally, EF-TEM further verified the effect of additives on the domain size and was complemented with tomographic reconstructions to provide a 3D representation of the BHJ morphology due to solvent additive processing. Finally, in situ GIWAXS was also performed to investigate the kinetics of crystallite formation during and shortly after spin-casting. The additive was shown to induce a complex structural evolution effect on the microstructure of SPSMs by inciting the formation of a metastable polymorph and enhanced crystalline quality of the SPSM during and shortly after casting, whereas the non-additive treated SPSM structure was static after initial crystallite formation. The results from this study have important implications for future optimization and design of solvent additive processed SPSM BHJ blends for OPV devices. |
