Jiang Huanxiang, Liang Qi, Guo Haishuo, Zhang Andong, Wang Xuewen, Tang Zheng, Bo Zhishan
College of Textiles and Clothing State Key Laboratory of Bio-fibers and Eco-textiles, Qingdao University, Qingdao 266071, China.
State Key Laboratory for Modification of Chemical Fibers and Polymer Materials, Center for Advanced Low-dimension Materials, College of Materials Science and Engineering, Donghua University, Shanghai 201620, China.
J Am Chem Soc. 2024 Nov 6;146(44):30262-30271. doi: 10.1021/jacs.4c09567. Epub 2024 Oct 25.
Cathode interfacial layers (CILs) hold utmost importance for achieving ohmic contact at the organic semiconductor-cathode interface of organic photovoltaic devices. Delving deep into diverse design principles and working mechanisms is of great significance for designing novel CILs with high performance. Herein, two novel nonamine-based CILs are designed: one featuring a cyclopentadiene unit, designated as CIL-cp; while the other, lacking cyclopentadiene, is referred to as CIL-ph, which is an isomer of CIL-cp. The subtle changes in chemical structures result in distinct modification mechanisms toward ohmic contact. On one hand, the robust electron-withdrawing characteristic of cyclopentadiene endows CIL-cp with lower energy levels, resulting in an interfacial dipole at the active layer-CIL-cp interface due to electron transfer from D18 to CIL-cp. On the other hand, CIL-ph exhibits a strong interfacial dipole at the CIL-Ag interface, which significantly reduces the work function (W) of the silver electrode. Both CIL-cp and CIL-ph demonstrate excellent interfacial modification capability, whereas CIL-cp possesses a stronger electron extraction ability, thus leading to a high power conversion efficiency of 19.31% in the D18:L8-BO system. Our results reveal the distinctive operational mechanism of cyclopentadiene-based CILs, thus offering innovative design ideas for CIL materials.
阴极界面层(CILs)对于在有机光伏器件的有机半导体 - 阴极界面实现欧姆接触至关重要。深入研究各种设计原理和工作机制对于设计高性能的新型CILs具有重要意义。在此,设计了两种新型的非胺基CILs:一种具有环戊二烯单元,命名为CIL - cp;另一种没有环戊二烯,称为CIL - ph,它是CIL - cp的异构体。化学结构的细微变化导致对欧姆接触的不同修饰机制。一方面,环戊二烯强大的吸电子特性赋予CIL - cp较低的能级,由于电子从D18转移到CIL - cp,在活性层 - CIL - cp界面处产生界面偶极。另一方面,CIL - ph在CIL - Ag界面处表现出很强的界面偶极,这显著降低了银电极的功函数(W)。CIL - cp和CIL - ph都表现出优异的界面修饰能力,而CIL - cp具有更强的电子提取能力,因此在D18:L8 - BO体系中导致了19.31%的高功率转换效率。我们的结果揭示了基于环戊二烯的CILs独特的运行机制,从而为CIL材料提供了创新的设计思路。
