Efficient Polymer Solar Cells Enabled by A-DA′D-A Type Acceptors with Alkoxypheny-Substituted Quinoxaline as the Fused-Ring Core
Haimei Wu, Baofeng Zhao, Sen Zhang, Zhaozhao Bi, Weiping Wang, Liuchang Wang, Zhiyuan Cong, Wei Ma, Chao Gao
Abstract
Polymer solar cells (PSCs) have made tremendous advances over the past three years due to the advantages offered by A-DA′D-A type small molecule electron-acceptors (SMEAs). To this day, the power conversion efficiencies (PCEs) have exceeded 19% in the PSCs incorporated by appropriate wide-bandgap polymer electron-donors and structure fine-tuned A-DA′D-A SMEAs. Despite high fill factor (FF) and short-circuit current ( J SC ) that were successfully achieved in wide-bandgap polymers and these type SMEA-based PSCs, the open-circuit voltage ( V OC ) was comparatively small, which hinders the performance further enhancement of PSCs. To boost the V OC of A-DA′D-A type SMEA-based PSCs, two small molecules ( BQ-4F and BQ-4Cl ) were designed and synthesized, with the alkoxyphenyl-substituted quinoxaline-containing fused core as the A′ unit and difluorinated and dichlorinated end groups as the A segments. Benefiting from the introduced alkoxyphenyl-substituted quinoxaline-containing fused core, the two SMEAs all have elevated lowest unoccupied molecular orbital energy levels. PSCs based on PM6: BQ-4F achieved a high V OC of 0.916 V and a promising PCE of 12.45%. Despite the device of PM6: BQ-4Cl realizing a slightly decreased V OC of 0.906 V, it accomplished high J SC (22.47 mA cm –2 ) and FF (66.2%), thus giving rise to a high efficiency of 13.48%. Besides, after adding 20% of these two small molecules in PM6:Y6-based devices, the fabricated BQ-4F - and BQ-4Cl -based ternary devices achieved high PCEs of 16.75% and 16.77%, respectively, which were superior to the 15.81% value of the PM6:Y6 binary PSC. The findings from this study should assist in the design and construction of new quinoxaline-based A-DA′D-A SMEAs that would be used for the manufacture of binary and ternary PSCs with high V OC and efficiencies.