Molecular Packing and Dielectric Property Optimization through Peripheral Halogen Swapping Enables Binary Organic Solar Cells with an Efficiency of 18.77%
作者:
Liang, HZ (Liang, Huazhe) [1] , [2] ; Chen, HB (Chen, Hongbin) [1] , [2] ; Wang, PR (Wang, Peiran) [1] , [2] ; Zhu, Y (Zhu, Yu) [1] , [2] ; Zhang, YX (Zhang, Yunxin) [3] ; Feng, WY (Feng, Wanying) [1] , [2] ; Ma, KQ (Ma, Kangqiao) [1] , [2] ; Lin, Y (Lin, Yi) [4] ; Ma, ZF (Ma, Zaifei) [4] ; Long, GK (Long, Guankui) [3] ; Li, CX (Li, Chenxi) [1] , [2] ; Kan, B (Kan, Bin) [3] ; Yao, ZY (Yao, Zhaoyang) [1] , [2] ; Zhang, HT (Zhang, Hongtao) [1] , [2] ; Wan, XJ (Wan, Xiangjian) [1] , [2] ; Chen, YS (Chen, Yongsheng) [1] , [2]
DOI
10.1002/adfm.202301573
在线发表
APR 2023
已索引
2023-04-30
文献类型
Article; Early Access
摘要
Peripheral halogen regulations can endow non-fullerene acceptors (NFAs) with enhanced features as organic semi-conductors and further boost efficient organic solar cells (OSCs). Herein, based on a remarkable molecular platform of CH14 with more than six halogenation positions, a preferred NFA of CH23 is constructed by synergetic halogen swapping on both central and end units, rendering the overall enlarged molecular dipole moment, packing density and thus relative dielectric constant. Consequently, the CH23-based binary OSC reaches an excellent efficiency of 18.77% due to its improved charge transfer/transport dynamics, much better than that of 17.81% for the control OSC of CH14. This work demonstrates the great potential for further achieving state-of-the-art OSCs by delicately regulating the halogen formula on these newly explored CH-series NFAs.