具有大的 2-癸基十四烷基柔性侧链的受体-受体型过二亚胺基聚合物受体：合成和氟化的影响

IF 3.8 3区材料科学 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY

Optical Materials Pub Date : 2025-03-12 DOI:10.1016/j.optmat.2025.116932

Zheyu Li , Daoyou Li , Yifan Bao , Pengzhi Guo , Zezhou Liang , Chunyan Yang , Junfeng Tong

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引用次数: 0

摘要

受体-受体（A-A）型过二亚胺（PDI）基聚合物受体（PAs）具有很高的空气稳定性和出色的电荷迁移率。然而，专门研究基于 A-A 型 PDI 的聚合物受体的工作很少，而且结构与光伏性能之间的相互作用仍然模糊不清。本文开发了三种 A-A 型 PDI 基聚酰胺 PPDI-DT-DTBT、PPDI-DT-DTFBT 和 PPDI-DT-DTFFBT，它们具有大柔性 2-癸基十四烷基（DT）侧链，以探究苯并噻二唑（BT）分子不同氟化作用的影响。为了进行比较，还制备了不含 BT 单元的供体-受体（D-A）型聚合物受体 PPDI-DT-2T。它们都具有很高的热稳定性和溶液态光稳定性。氟取代基的逐渐增加会导致吸收蓝移、带隙增大、ELUMO 提高、分子构型更加平面化以及聚集性增强。因此，以广泛开发的供体聚合物 PTB7-Th 为电子供体，基于单氟 PPDI-DT-DTFBT 的体异质结器件获得了 0.70 V 的中等 VOC、6.22 mA cm-2 的最高 JSC 和 37.56 % 的 FF，从而获得了 1.63 % 的功率转换效率（PCE）。相比之下，基于无氟 PPDI-DT-DTBT 和二氟 PPDI-DT-DTFFBT 的器件的 PCE 较低，分别为 1.31 % 和 1.24 %。对照聚合物受体 PPDI-DT-2T 由于具有高 ELUMO，尽管 VOC 高达 0.80 V，但 PCE 仍为 1.27 %。单氟化后 PCE 的提高主要源于 JSC 和 FF 的增加，这是由于吸收的改善和电子迁移率的提高。在这些 DT 侧链修饰的 PDI 聚合物受体中观察到的低效率可能是由于溶解度有限导致的大量聚集和粗糙的表面形态造成的。有趣的是，无氟 PPDI-DT-DTBT 薄膜的 ELUMO 值为 -3.85 eV，具有最高的 OFET 电子迁移率（2.2 × 10-2 cm2 V-1 s-1）。这一发现表明，延长 A-A 型含 PDI 聚酰胺的柔性侧链是谨慎之举，然而，单氟化苯并噻二唑分子是一种有效的方案，它可以调整分子构型并提高电荷迁移率，从而提高全聚合物太阳能电池的光伏性能。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

Acceptor-acceptor type perylenediimide-based polymeric acceptors with large 2-decyltetradecyl flexible side chain: Synthesis and impact of fluorination

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Acceptor-acceptor type perylenediimide-based polymeric acceptors with large 2-decyltetradecyl flexible side chain: Synthesis and impact of fluorination

Acceptor-acceptor (A-A) type perylenediimide (PDI)-based polymeric acceptors (PAs) possessed a high air stability and an excellent charge mobility. However, few efforts devoted to A-A type PDI-based polymeric acceptors and the interplay between the structure and photovoltaic performance was still nebulous. Herein, three A-A type PDI-based PAs PPDI-DT-DTBT, PPDI-DT-DTFBT and PPDI-DT-DTFFBT with large flexible 2-decyltetradecyl (DT) side chains were developed to probe into the effect of different fluorination at the benzothiadiazole (BT) moiety. And the donor-acceptor (D-A) type polymer acceptor PPDI-DT-2T without BT unit was prepared to make the comparison. All of them exhibited the high thermo-stability and solution state photo-stability. Gradually increased fluorine substituents acquired the blue-shifted absorption, the increased bandgap, the raised E_LUMO, more planar molecular configuration and strengthened aggregation. Accordingly, with the widely developed donor polymer PTB7-Th as electron donor, bulk heterojunction device based on monfluorinated PPDI-DT-DTFBT obtained the middle V_OC of 0.70 V, the highest J_SC of 6.22 mA cm⁻² and FF of 37.56 %, contributing to the winning power conversion efficiency (PCE) of 1.63 %. By contrast, fluorine-free PPDI-DT-DTBT- and difluorinated PPDI-DT-DTFFBT-based devices acquired the inferior PCEs of 1.31 % and 1.24 %. The control polymer accepter PPDI-DT-2T got the PCE of 1.27 % regardless of the high V_OC of 0.80 V as the result of high E_LUMO. The raised PCE after monofluorination was mainly originated from the increased J_SC and FF, which was due to the improved absorption and the higher electron mobility. The observed low efficiency in these DT-side chain modified PDI polymeric acceptors was probably due to the large aggregation and the coarse surface morphology resulting from limited solubility. Interestingly, fluorine-free PPDI-DT-DTBT film exhibited the E_LUMO of −3.85 eV and afforded the highest OFET electron mobility of 2.2 × 10⁻² cm² V⁻¹ s⁻¹. This finding implied that it was cautious to prolong the flexible side chain during the A-A type PDI-containing PAs, however, monofluorinating the benzothiadiazole moiety was an effective scenario by the virtue of tuning the molecular configuration and lifting the charge mobility, with an aim at elevating the photovoltaic performance in all-polymer solar cells.

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来源期刊

Optical Materials 工程技术-材料科学：综合

CiteScore

6.60

自引率

12.80%

发文量

1265

审稿时长

38 days

期刊介绍： Optical Materials has an open access mirror journal Optical Materials: X, sharing the same aims and scope, editorial team, submission system and rigorous peer review. The purpose of Optical Materials is to provide a means of communication and technology transfer between researchers who are interested in materials for potential device applications. The journal publishes original papers and review articles on the design, synthesis, characterisation and applications of optical materials. OPTICAL MATERIALS focuses on: • Optical Properties of Material Systems; • The Materials Aspects of Optical Phenomena; • The Materials Aspects of Devices and Applications. Authors can submit separate research elements describing their data to Data in Brief and methods to Methods X.