X射线光电子能谱
钝化
材料科学
工作职能
图层(电子)
苯甲酸
接受者
接触角
有机太阳能电池
润湿
化学工程
电子受体
扫描电子显微镜
光化学
化学
纳米技术
有机化学
复合材料
聚合物
物理
凝聚态物理
工程类
作者
Hao Liu,Chao Wang,Wen Liang Tan,Lars Thomsen,Anthony S. R. Chesman,Yvonne Hora,Martyn Jevric,Jonas M. Bjuggren,Mats R. Andersson,Yahui Tang,Linjing Tang,Vũ Văn Đoán,Christopher R. McNeill
标识
DOI:10.1021/acsaelm.3c01517
摘要
ZnO is a common electron transport layer in organic solar cells that typically requires treatment with an additional layer to passivate surface traps to optimize the device performance. Here, we present a “one-step” approach to modifying ZnO electron transport layers (ETLs) used in organic solar cells. This approach involves adding benzoic acid (BZA) derivatives directly to the ZnO precursor solution, which are then present at the surface of the resulting ZnO film. We demonstrate this approach for three different BZA derivatives, namely, benzoic acid, 4-chlorobenzoic acid, and 4-hydrazinobenzoic acid. For all molecules, improved device performance and stability is demonstrated in solar cells using an active layer blend of PTQ10 (donor) and ITIC-Br (nonfullerene acceptor) compared to such cells prepared using untreated ZnO. Furthermore, similar or improved device performance and stability is demonstrated compared to conventional PEIE treatment of ZnO. The presence of the BZA derivatives at the surface after processing is established using X-ray photoelectron spectroscopy and near-edge X-ray absorption fine-structure spectroscopy. From atomic force microscopy analysis and X-ray diffraction studies, the addition of BZA derivatives appears to restrict ZnO grain growth; however, this does not negatively impact the device performance. ZnO layers treated with BZA derivatives also exhibit a higher water contact angle and lower work function compared to untreated ZnO. Improved device performance is attributed to reduced surface recombination at the ETL/active layer interface, while improved device stability is attributed to the increased hydrophobicity of the ETL. This approach enables simplification of device manufacture while still allowing for optimization of the surface properties of metal oxide ETLs.
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