Compared with all-small-molecule (ASM) and other types of organic solar cells (OSCs), the small molecule donor:polymer acceptor (SMD:PA) OSCs develop much slower due to the lack of material matching rules. Herein, by changing the end-cap substituent of the small molecule donor from ethyl (MPhS-C2) to benzyl (MPhS-Ph), the different selection rules of donor properties and thermal annealing (TA) treatment between the ASM and the SMD:PA system under tetrahydrofuran processing are thoroughly investigated. Therefore, MPhS-Ph exhibits more ordered molecular packing, leading to better adaptability in the SMD:PA system without TA; while the inferior molecular packing of MPhS-C2 after spin-coating performs better in the ASM system with TA. Whether spin-coating or TA process dominates morphological optimization also dominates their energy loss. Therefore, the MPhS-Ph:PYF-T-o and MPhS-C2:BTP-eC9 based devices achieve the highest power conversion efficiency (PCE) of 12.1% and 15.7%, respectively, both of which are cutting-edge PCEs in their own type of OSCs fabricated by non-halogen solvent. This result suggests that intrinsic strong crystallization independent of the thermal drive is hoped in SMD:PA-OSCs, while high miscibility after spin-coating and proper assembly under thermal drive is expected in ASM-OSCs, providing deep understanding and guidance in highly efficient materials design rules in both ASM-OSCs and SMD:PA-OSCs.
Keywords: all‐small‐molecule; morphology; non‐halogen solvent; polymer acceptor; small molecule donor.
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