Revealing the spacing effect of neighboring side‐chains in modulating molecular aggregation and orientation of M‐series acceptors

Controlling the aggregation of small‐molecule acceptors (SMAs) is essential to obtain an optimal morphology and to improve the photovoltaic performance of polymer solar cells (PSCs). However, reducing intermolecular aggregation of SMAs is usually accompanied by the disruption of compact molecular pa...

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Bibliographic Details
Published in:Aggregate (Hoboken) 2023-08, Vol.4 (4), p.n/a
Main Authors: Ma, Yunlong, Luan, Shaoxin, Cai, Dongdong, Zhang, Shu‐Quan, Wang, Jin‐Yun, Tu, Qisheng, Zhu, Yuhang, Zheng, Qingdong
Format: Article
Language:English
Subjects:
aggregation
Carbon
molecular orientation
Morphology
neighboring side‐chains
Nitrogen
Phase transitions
polymer solar cells
Polymers
small‐molecule acceptors
Thin films
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Summary:Controlling the aggregation of small‐molecule acceptors (SMAs) is essential to obtain an optimal morphology and to improve the photovoltaic performance of polymer solar cells (PSCs). However, reducing intermolecular aggregation of SMAs is usually accompanied by the disruption of compact molecular packing thereby leading to their decreased electron mobilities. Here, two novel M‐series SMAs (MD1T and MD2T) based on ladder‐type heterononacenes with neighboring side‐chains separated by one or two thiophene rings are designed and synthesized. It is found that shortening the spacing of the neighboring side‐chains of the SMAs can greatly alleviate the intermolecular aggregation and alter the molecular orientation from bimodal edge‐on/face‐on to predominant face‐on while maintaining the compact molecular packing. As a result, a more favorable morphology with smaller domain sizes is formed for the MD1T‐based blend films, which greatly improves the charge generation and charge transport for the corresponding PSCs. The best‐performing MD1T‐based device affords an efficiency of 12.43%, over seven times higher than that of the MD2T‐based device. This work reveals the importance of the spacing between the neighboring side‐chains in modulating the molecular aggregation and active layer morphology, and the obtained structure‐performance relationships shall provide important guidance for designing highly efficient SMAs. The spacings of neighboring side‐chains play a vital role in modulating the molecular aggregation and orientation of M‐series acceptors. The acceptor (MD1T) with shorter side‐chain spacing can alleviate excessive molecular aggregation and induce the formation of ordered face‐on molecular orientation thereby leading to the corresponding active layer with optimal morphology and improved photovoltaic properties.
ISSN:2692-4560
2766-8541
2692-4560
DOI:10.1002/agt2.322