溶液顺序沉积有机光伏:从形态控制到大面积模块

IF 42.9 Q1 ELECTROCHEMISTRY eScience Pub Date : 2023-08-01 DOI:10.1016/j.esci.2023.100142
Jianhua Jing, Yuejia Dou, Shihao Chen, Kai Zhang, Fei Huang
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引用次数: 2

摘要

有机光电材料可实现尖端、低成本的有机光电二极管,包括用于能量转换的有机太阳能电池(OSCs)和用于图像传感器的有机光电探测器(opd)。体异质结(BHJ)结构是通过在单一溶液中混合供体和受体材料而得到的,在活性层的构建中占主导地位,但其在薄膜形成过程中的形态演变对获得理想的纳米级形态以最大化激子解离和最小化非激子重组提出了很大的挑战。溶液顺序沉积(SSD)可以提供良好的p-i-n垂直分量分布,具有丰富的施主/受主界面和相对整齐的电极附近施主和受主相,使其具有优异的器件性能和长期稳定性。本文以p-i-n结构为重点,通过总结溶剂选择和添加剂策略,系统地回顾了在固态硬盘中调节这种形态的方法。这些方法已经成功地在三元osc、全聚合物太阳能电池和opd中实现了明确的形态。为了提供一个实用的视角,我们还讨论了BHJ和SSD薄膜器件稳定性的比较研究,并回顾了叶片涂层技术和大面积模块的影响进展,以指导工业生产。最后,提出了进一步研究最终商业化的挑战。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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Solution sequential deposited organic photovoltaics: From morphology control to large-area modules

Organic optoelectronic materials enable cutting-edge, low-cost organic photodiodes, including organic solar cells (OSCs) for energy conversion and organic photodetectors (OPDs) for image sensors. The bulk heterojunction (BHJ) structure, derived by blending donor and acceptor materials in a single solution, has dominated in the construction of active layer, but its morphological evolution during film formation poses a great challenge for obtaining an ideal nanoscale morphology to maximize exciton dissociation and minimize nongeminate recombination. Solution sequential deposition (SSD) can deliver favorable p–i–n vertical component distribution with abundant donor/acceptor interfaces and relatively neat donor and acceptor phases near electrodes, making it highly promising for excellent device performance and long-term stability. Focusing on the p–i–n structure, this review provides a systematic retrospect on regulating this morphology in SSD by summarizing solvent selection and additive strategies. These methods have been successfully implemented to achieve well-defined morphology in ternary OSCs, all-polymer solar cells, and OPDs. To provide a practical perspective, comparative studies of device stability with BHJ and SSD film are also discussed, and we review influential progress in blade-coating techniques and large-area modules to shed light on industrial production. Finally, challenging issues are outlined for further research toward eventual commercialization.

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