posted on 2025-01-11, 02:43authored byYuanyuan Liu, Shi-Qi Ye, Hong-Jian Deng, Long Chen, Zheng-Chun Yin, Zhiwei Xu, Yu-Xuan Lei, Qun Zhang, Shangfeng Yang, Guan-Wu Wang
Morphology optimization of blend films is an essential
strategy
to enhance the photovoltaic performance of organic solar cells (OSCs).
Additive engineering is effective for fine-tuning the active layer
morphology. Given the limited efforts and achievements in designing
and synthesizing liquid additives, new solid additives to manipulate
the morphology of active layers have gained widespread attention.
Herein, 1,4-dimethoxynaphthalene (DMNA), with the merits of simple
structure, low cost, and ecofriendliness, is successfully incorporated
as a novel solid additive to optimize the performance in OSCs based
on D18-Cl:N3. The relationship between different DMNA contents and
the device performance has been investigated. It is found that the
active layer morphology can be effectively regulated by DMNA, leading
to an enhanced molecular packing in the blend films, which favors
exciton dissociation, charge transfer, and suppression of charge recombination.
As a result, 18.61% power conversion efficiency (PCE) has been obtained
in the D18-Cl:N3 binary devices incorporated with the solid additive
DMNA, better than 17.21% PCE for the binary control device. This is
primarily due to the simultaneous increase of the short-circuit current
density and fill factor. Furthermore, the general applicability of
DMNA as an effective solid additive has been confirmed in other organic
photovoltaic systems. These results suggest that DMNA presents potential
prospects for regulating bulk heterojunction morphology toward high-performance
and high-stability OSCs.