Abstract

This study reports the successful design and synthesis of two novel polymerized nonfused ring electron acceptors, <b>P-2BTh</b> and <b>P-2BTh-F</b>, derived from the high-performance nonfused ring electron acceptor, 2BTh-2F. Prepared via Stille polymerization, these polymers feature thiophene and fluorinated thiophene as π-bridge units. Notably, <b>P-2BTh-F</b>, with difluorothiophene as the π-bridge, exhibits a more planar backbone and red-shifted absorption spectrum compared with <b>P-2BTh</b>. When employed in organic solar cells (OSCs) with PBDB-T as the donor material, <b>P-2BTh-F</b>-based devices demonstrate an outstanding power conversion efficiency (PCE) of over 11%, exceeding the 8.7% achieved by <b>P-2BTh</b>-based devices. Furthermore, all-polymer solar cells utilizing PBDB-T:<b>P-2BTh-F</b> exhibit superior storage stability. Additionally, <b>P-2BTh-F</b> was explored as a functional additive in a high-performance binary system, enhancing stability while maintaining comparable PCE (19.45%). This strategy offers a cost-effective approach for fabricating highly efficient and stable binary and ternary organic solar cells, opening new horizons for cost-effective and durable solar cell development.