Operational stability is the main obstacle to the industrial applications of organic solar cells (OSCs). In this study, different degradation mechanisms under continuous simulated solar radiation are demonstrated for high-performance non-fullerene OSCs based on commonly used electron transport materials, i.e., ZnO and SnO2. The ZnO-induced decomposition pathways of A-DA'D-A type non-fullerene acceptors (NFAs) under UV illumination are unraveled for the first time and related to N-dealkylation of pyrrole from the core moiety. In the case of SnO2, poor photo-stability is primarily ascribed to a high density of trap states, which can be diminished by surface modification to achieve better device stability that is comparable with the stability under LED illumination without UV components. With a thorough understanding of the degradation pathways, this study provides valuable guidelines for designing high-performance and stable non-fullerene OSCs. @@@ Evidence of ZnO-induced decomposition of A-DA'D-A type NFA under UV illumination is demonstrated in this work. Using SnO2 as an alternative ETL, performance degradation of OSCs is mainly ascribed to a high concentration of surface defects, which can be overcome by amine modification of the SnO2 surface. image

• 单位
  广东工业大学