化学
有机太阳能电池
光致发光
接受者
化学物理
量子产额
猝灭(荧光)
光电子学
光化学
量子效率
聚合物太阳能电池
密度泛函理论
能量转换效率
分子物理学
振荡器强度
电流密度
光伏系统
带隙
太阳能
太阳能电池
量子
单一债券
噻吩
Crystal(编程语言)
计算化学
作者
Ruohan Wang,Xiaodong Si,Le Mei,Wenkai Zhao,Wendi Shi,Xian Kai Chen,Song Guangkun,Longyu Li,Zheng Xiao,Zhaoyang Yao,Guankui Long,Chenxi Li,Xiangjian Wan,Yongsheng Chen
摘要
Designing acceptors with low nonradiative energy losses without compromising short-circuit current density and fill factor remains a critical challenge for achieving high-efficiency organic solar cells. In this study, we design and synthesize two acceptors, named a-Th2Cl and a-Th2Br, featuring a halogenated thiophene unit grafted via a single bond onto the central core, an approach that extends beyond conventional central core conjugation extension acceptor design. The rotation around the single bond can result in twist conformation, and the aggregation-caused quenching effect during the transition from solution to film is effectively suppressed, favoring increasing photoluminescence quantum yields. X-ray crystal structure analysis reveals that a-Th2Br exhibits unusual molecular packing behavior with strong J-aggregation. Theoretical simulation demonstrates that a-Th2Br aggregates exhibit a reduced extent of excited-state charge transfer and enhanced fluorescent oscillator strength compared to the benchmark acceptor L8-BO, rationalizing the observed high photoluminescence quantum yields and low nonradiative energy losses for the two acceptors films and corresponding organic solar cells. Moreover, when blended with PM6, both acceptors yield favorable bulk heterojunction morphologies. As a result, binary organic solar cells based on PM6:a-Th2Cl and PM6:a-Th2Br deliver power conversion efficiencies of 19.87 and 20.60% (certified 20.05%), with impressively low nonradiative energy losses values of 0.202 and 0.194 eV, respectively. These results highlight the potential of central core engineering in simultaneously suppressing nonradiative losses and maintaining a high short-circuit current density and fill factor in high-performance organic solar cells.
科研通智能强力驱动
Strongly Powered by AbleSci AI