Hao Wang, Busheng Zhang, Liming Wang, Xia Guo, Le Mei, Bo Cheng, Wei Sun, Lixuan Kan, Xinxin Xia, Xiaotao Hao, Thomas Geue, Feng Liu, Maojie Zhang, Xian-Kai Chen
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引用次数: 0
Abstract
Layer-by-layer (LBL) deposition has become a facile and promising method to fabricate highly efficient organic solar cells (OSCs). However, characterization and optimization of 3D morphology remain a grand challenge for LBL-processed active layers, and their correlation with photovoltaic properties of OSC devices is not clear to date. Here, to address this issue, the morphology and its formation mechanisms of LBL-processed active layer based on the classical D18/L8-BO blend were investigated systematically. Intriguingly, a unique 3D nanomorphology is achieved and uncovered within the LBL processed active layer, which highlights a highly uniform and “zigzag”-shaped phase structure formed by the intersection of donor and acceptor aggregates along horizontal direction in the middle-depth layer, rarely found in bulk heterojunction (BHJ) films processed by blend casting. Our results revealed that solid additive DBM with a twisted conformation plays a crucial role in achieving the uniform phase structure of LBL-deposited active layer. Consequently, the characteristic 3D morphology of LBL-processed device significantly improves short-circuit current and fill factor, enabling an impressive PCE of 20.2% in such binary device. Therefore, this work unambiguously demonstrates a unique 3D nanomorphology within LBL active layer, unveils the morphology manipulation mechanism, and their correlation with optoelectronic properties of OSCs.
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