Highly photostable N-annulated perylene-diimide-based dimeric acceptors: Synthesis and role of linking core

Two N-annulated perylene diimide (PDI) dimers, termed as, TVT-(PPDI-B)(2) and TYT-(PPDI-B)(2), selecting (E)-1,2-di(thien-2-yl)ethylene (TVT) and 1,2-di(thien-2-yl)acetylene (TYT) as the middle linkers, N-butyl-[1,12-b,c, d]pyrrole-N,NMODIFIER LETTER PRIME-bis(2-hexyldecyl)perylene diimide (PPDI-B) fused aromatic moiety as two wings, were developed to investigate the influence of linking core. It was exhibited that the improved absorption, 0.05 eV up-shifted E-LUMO, drastically reduced twisting angle from 68.0 degrees to 27.9 degrees between two N-annulated PDI moieties and enhanced molecular aggregation were found after substituting TVT linking core with TYT. Accordingly, under the best processing condition, TVT-(PPDI-B)(2)-based device gained the V-OC of 0.92, J(SC) of 3.61 mA center dot cm(-2), FF of 30.3% and consequently PCE of 1.02% when blending with PTB7-Th. In contrast, TYT-(PPDI-B)(2)-based device afforded 4.35% increased V-OC of 0.96 V, 86.98% enhanced J(SC) of 6.75 mA center dot cm(-2) and 55.45% raised FF of 47.1%, collectively contributed to a 211% raised PCE as high as 3.17%. This efficiency enhancement was mainly attributed to improved absorption, raised E-LUMO, more efficient exciton dissociation and electron mobility, weakened charge recombination, and more suitable morphology. Interestingly, 0.12 similar to 0.16 V up-shifted V-OC was achieved after applying N-annulation strategy at the bay-position of PDI building block. This indicates that precisely tuning the linking core in the N-annulated PDI-based dimers can effectively affect optoelectronic property, molecular geometry and morphology, and thus further boost the corresponding device efficiency.