Halogen-free solvent processed organic solar sub-modules (≈55 cm2) with 14.70% efficiency by controlling the morphology of alkyl chain engineered polymer donor

IF 10.7 Q1 CHEMISTRY, PHYSICAL
EcoMat Pub Date : 2024-10-27 DOI:10.1002/eom2.12496
Thavamani Gokulnath, Hyerin Kim, Donghyun Song, Ho-Yeol Park, Je-Sung Jee, Young Yong Kim, Jinhwan Yoon, Kakaraparthi Kranthiraja, Sung-Ho Jin
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Abstract

Goals of high efficiency, morphological analysis, and the ability to produce organic solar cell (OSC) sub-modules using halogen-free solvents are demanding. In this study, a robust conjugated polymer with thienothiophene π-spacer with pendant alkyl side chain (NapBDT-C12) was synthesized and used to fabricate sub-modules. Excellent efficiencies were demonstrated by a NapBDT-C12 integrated ternary blend, which was used to produce stable small-area-to-sub-module devices using O-xylene. The efficiency of the NapBDT-C12 added small-area ternary devices (PM6:NapBDT-C12:L8-BO) was 18.71%. Owing to the controlled homogeneity of the blend with favorable nanoscale film morphology, enhanced carrier mobilities, and exciton dissociation/splitting properties, contributed to the efficiencies of small-area-to-sub-module OSCs. Moreover, a 55 cm2 sub-module with an efficiency of 14.69% was accomplished by bar coating using O-xylene under ambient conditions. This study displays the potential of a ternary blend based OSC device to produce high efficiency scalable sub-modules at ambient conditions.

Abstract Image

通过控制烷基链工程聚合物供体的形态,无卤素溶剂加工的有机太阳能子模块(≈55 cm2)效率达到 14.70
高效率、形态分析以及使用无卤溶剂生产有机太阳能电池(OSC)子模块的能力等目标要求很高。在这项研究中,合成了一种带有噻吩噻吩π-间隔物和垂烷基侧链的强共轭聚合物(NapBDT-C12),并将其用于制造子模块。NapBDT-C12集成三元共混物具有极佳的效率,可用于使用邻二甲苯生产稳定的小面积子模块器件。添加了 NapBDT-C12 的小面积三元装置(PM6:NapBDT-C12:L8-BO)的效率为 18.71%。由于混合物的均匀性得到了控制,且具有良好的纳米薄膜形态,因此载流子迁移率和激子解离/分裂特性得到了增强,从而提高了小面积子模块 OSC 的效率。此外,通过在环境条件下使用邻二甲苯进行条状镀膜,55 平方厘米的子模块效率达到了 14.69%。这项研究显示了基于三元共混物的 OSC 器件在环境条件下生产高效可扩展子模块的潜力。
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CiteScore
17.30
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0.00%
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审稿时长
4 weeks
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