Cyclopentadithiophene-based Conjugated Polymers for Organic Thermoelectric Devices and Other Applications

SeungOk Pyo, Yehbeen Im, Hyeokjun Kim
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Abstract

The 4H-cyclopenta[2,1-b:3,4-b’]dithiophene (CPDT)-based conjugated polymers (CPs) have garnered significant attention in various fields of organic electronics due to their strong electron-donating properties, extended π-plane, and rigid, planar chemical structure. These unique features enable CPDT-based CPs to be highly advantageous for use in a range of organic semiconductor devices. While CPDT-based CPs have been extensively investigated and utilized as electron donors in various organic semiconductor devices, there is limited literature discussing the electrochemical properties of CPDT building blocks and the representative examples of CPDT-based CPs. In this mini-review, the authors outline the electrochemical properties of the CPDT building block, which stem from its rigid and planar chemical structure, facilitating the use of CPDT derivative materials in the field of organic semiconductors, such as organic photovoltaics (OPVs), organic thin film transistors (OTFTs), and organic photodetectors (OPDs). Furthermore, the authors highlight the advantages of CPDT-based CPs, particularly, for organic thermoelectric applications (OTEs) such as strong electron-donating properties and extended π-conjugation, which lead to facile p-type doping characteristics in CPDT-based CPs. The authors discuss the basic working principles of OTEs, including several key parameters of OTE devices such as the Seebeck coefficient (S) and power factor (PF). Additionally, the authors address the main challenge in OTEs: the trade-off relationship between electrical conductivity and the Seebeck coefficient. The review presents several strategies to overcome these trade-off limitations, focusing on CPDT and other CPs for OTE applications.
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用于有机热电器件和其他应用的环戊二烯基噻吩共轭聚合物
基于 4H-环戊二烯并[2,1-b:3,4-b']二噻吩(CPDT)的共轭聚合物(CPs)因其强大的电子捐赠特性、扩展的 π 平面和刚性平面化学结构而在有机电子学的各个领域引起了极大的关注。这些独特的特性使得基于 CPDT 的氯化石蜡在一系列有机半导体器件中的应用具有极大的优势。虽然基于 CPDT 的氯化石蜡已被广泛研究并用作各种有机半导体器件中的电子供体,但有关 CPDT 构建模块的电化学特性以及基于 CPDT 的氯化石蜡的代表性实例的文献却十分有限。在这篇微型综述中,作者概述了 CPDT 构建模块的电化学特性,这些特性源于其刚性和平面化学结构,有助于 CPDT 衍生物材料在有机半导体领域的应用,如有机光伏 (OPV)、有机薄膜晶体管 (OTFT) 和有机光电探测器 (OPD)。此外,作者还强调了基于 CPDT 的氯化石蜡的优势,尤其是在有机热电应用 (OTE) 中的优势,如强电子捐献特性和扩展的 π 共轭,这使得基于 CPDT 的氯化石蜡具有方便的 p 型掺杂特性。作者讨论了 OTE 的基本工作原理,包括 OTE 器件的几个关键参数,如塞贝克系数 (S) 和功率因数 (PF)。此外,作者还讨论了 OTE 面临的主要挑战:导电率与塞贝克系数之间的权衡关系。综述介绍了克服这些权衡限制的几种策略,重点关注 CPDT 和其他 CPs 在 OTE 中的应用。
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