材料科学
堆积
有机太阳能电池
激子
有机半导体
三元运算
光电子学
光伏系统
有机电子学
化学物理
纳米技术
能量转换效率
扩散
光伏
结晶
混合太阳能电池
半导体
光电流
聚合物太阳能电池
栅栏
开路电压
工作(物理)
电压
相(物质)
太阳能电池
微电子
工程物理
分子扩散
作者
Chengdu Cao,Houdong Mao,Lifu Zhang,Qin Zhao,B. P. Zhang,Liming Yang,Y. B. Zhao,Lin Wen,Yaxin Zhai,Licheng Tan,Yiwang Chen
标识
DOI:10.1002/adma.202514047
摘要
Thick-film (>300 nm) organic solar cells (OSCs) have attracted increasing attention in recent years due to their compatibility with large-scale industrial production. However, the inherently short exciton diffusion length (LD) of organic semiconductors severely restricts exciton diffusion to the interface in the larger donor/acceptor (D/A) domains, thereby impeding the photovoltaic performance, especially open circuit voltage and fill factor for the commercialized thick-film OSCs. Herein, a pressure-modulated molecular stacking (PMMS) strategy is employed to enhance crystallization and regulate fluid confinement depth (the grating depth of imprinted PM6) by controlling the imprinting pressure, thereby optimizing D/A inter-penetration with favorable vertical phase separation morphology. This strategy can significantly extend LD (from ≈ 26.5 to ≈ 40.3 nm) to facilitate efficient exciton diffusion and carrier transport by enhancing ordered molecular stacking. Consequently, the best devices achieve one of the highest power conversion efficiencies (PCE)s of 20.20% (100 nm) and 19.27% (300 nm, certified as 18.88%), respectively, while the large-area module (16.94 cm2) exhibits an impressive PCE of 17.01% for D18/BTP-eC9:L8-BO ternary system via blade-coating technology. This work provides a valuable approach to extending LD by constructing favorable vertical phase separation morphology for achieving large-scale high-efficiency thick-film OSCs.
科研通智能强力驱动
Strongly Powered by AbleSci AI