Single-Component Organic Solar Cells with Competitive Performance

Organic Materials Pub Date : 2021-04-01 DOI:10.1055/s-0041-1727234

Yakun He, Ning Li, C. Brabec

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引用次数: 27

Abstract

Abstract Organic semiconductors with chemically linked donor and acceptor units can realize charge carrier generation, dissociation and transport within one molecular architecture. These covalently bonded chemical structures enable single-component organic solar cells (SCOSCs) most recently to start showing specific advantages over binary or multi-component bulk heterojunction concepts due to simplified device fabrication and a dramatically improved microstructure stability. The organic semiconductors used in SCOSCs can be divided into polymeric materials, that is, double-cable polymers, di-block copolymers as well as donor–acceptor small molecules. The nature of donor and acceptor segments, the length and flexibility of the connecting linker and the resultant nanophase separation morphology are the levers which allow optimizing the photovoltaic performance of SCOSCs. While remaining at 1–2% for over a decade, efficiencies of SCOSCs have recently witnessed significant improvement to over 6% for several materials systems and to a record efficiency of 8.4%. In this mini-review, we summarize the recent progress in developing SCOSCs towards high efficiency and stability, and analyze the potential directions for pushing SCOSCs to the next efficiency milestone.

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具有竞争性能的单组分有机太阳能电池

摘要具有化学连接供体和受体单元的有机半导体可以在一个分子结构内实现电荷载流子的产生、离解和传输。由于简化了器件制造和显著提高了微观结构稳定性，这些共价键合的化学结构使单组分有机太阳能电池（SCOSC）最近开始显示出优于二元或多组分体异质结概念的特定优势。SCOSC中使用的有机半导体可分为聚合物材料，即双电缆聚合物、二嵌段共聚物以及供体-受体小分子。供体和受体片段的性质、连接体的长度和柔性以及由此产生的纳米相分离形态是优化SCOSC光伏性能的杠杆。尽管十多年来SCOSC的效率一直保持在1-2%，但最近，几种材料系统的SCOSC效率显著提高到6%以上，并达到8.4%的创纪录效率。在这篇小型综述中，我们总结了在开发高效和稳定的SCOSC方面的最新进展，并分析了将SCOSC推向下一个效率里程碑的潜在方向。

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