Unfused Acceptors Matching π-Bridge Blocks with Proper Frameworks Enable Over 12% As-Cast Organic Solar Cells

Emerging unfused-ring acceptors (UFAs) have been explored in pursuit of low-cost high-efficient organic solar cells (OSCs). Assembling unfused building blocks into proper frameworks are challenging for the molecular design of UFAs. The authors report herein four UFAs adopting either dithiophene cyclopentadiene (DTC) or dithieno[3,2-6:2',3'-d]pyrrole (DTP) as pi-bridge units with different molecular frameworks for high-efficient as-cast OSCs. All these acceptors exhibit strong near-infrared absorption and narrow optical band gap (E-g(opt) < 1.50 eV). DTC-bridged symmetric and DTP-bridged asymmetric UFAs exhibit higher planar conformation as well as suitable miscibility and homogeneous phase separation when blending with polymer donor PBDB-T to promote efficient charge transport in the blends. Their blends with PBDB-T contribute optimal PCE of 12.17% and 11.92% in ascast OSCs, among the highest values for UFAs based as-cast devices in the literature. Experimental and theoretical simulations systematically reveal the impact of manipulating the molecular framework of UFAs on their conformation, optoelectronic, and photovoltaic performance. The results indicate the matching pi-bridge units with molecular frameworks as an attractive approach to design UFAs for high-performance as-cast OSCs.

Automated summary

This study reports four unfused-ring acceptors (UFAs) with different molecular frameworks, which are used to fabricate high-efficiency organic solar cells (OSCs) with wet films. These UFAs exhibit strong near-infrared absorption and narrow optical band gap, and when blended with polymer donors, they promote efficient charge transport. Experimental and theoretical simulations demonstrate the impact of the molecular framework of UFAs on their performance.