Conjugated Multiblock Copolymers and Microcracked Gold Electrodes Applied for the Intrinsically Stretchable Field-Effect Transistor

IF 8.2 2区材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY

ACS Applied Materials & Interfaces Pub Date : 2025-03-27 DOI:10.1021/acsami.5c00047

Yu-Chun Huang, Shuto Yamamoto, Jung-Yao Chen, Chun-Jen Su, U-Ser Jeng, Tomoya Higashihara, Yan-Cheng Lin

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Abstract

The rise of flexible electronic devices has led to extensive research into conjugated polymer structural engineering. Integrating polymer channels and contact electrodes, warranting high stretchability, is still critical, and the microcracked gold technique provides a potential strategy to integrate them. Conjugated block copolymers have gained significant attention due to their high flexibility, allowing for tailored polymer structures to meet the specific requirements of different device characteristics. In this study, novel N-type multiblock copolymers (multi-BCPs) composed of rigid poly(naphthalene diimide-alt-bithiophene) and flexible polyisobutylene segments were successfully synthesized as polymer semiconductors for the first time. The materials are named based on the weight fraction of soft segments: NDI (0 wt %), mAB73 (27 wt %), and mAB60 (40 wt %). The study explores the mechanical properties, crystallinity, and electrical performance of flexible multi-BCPs. The results show that introducing soft segments significantly enhances stretchability, with crack-onset strains beyond 100% because of their low elastic moduli of 40–50 MPa. Furthermore, the OFET device of mAB73 achieves unchanged mobility under 100% strain, outperforming mAB60 due to excessive polyisobutylene blocks. At the end of this study, an integrated stretchable device with high stretchability is fulfilled by utilizing the microcracked gold technique to combine the multi-BCP channels and contact electrodes. The integrated device can be applied to biomedical electronics without toxic or corrosive electrode materials. The influencing factors, including contact resistance, channel charge mobility, and electrode resistance, are systematically studied to investigate the integrated device’s mobility–stretchability relationship. The results indicate that the contact resistance between the multi-BCP channels and contact electrodes is essential to the device’s performance. Among these, mAB73, containing soft segments, exhibits more stability than NDI due to the microcracked gold electrodes with infiltrated gold nanoparticles in the rubbery channel surface. Appropriately incorporating soft segments significantly enhances mobility retention under tensile strains, highlighting the potential of multi-BCP designs in stretchable electronic applications.

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共轭多嵌段共聚物和微裂纹金电极在本质可拉伸场效应晶体管中的应用

柔性电子器件的兴起导致了共轭聚合物结构工程的广泛研究。整合聚合物通道和接触电极，保证高拉伸性，仍然是至关重要的，而微裂金技术提供了一种整合它们的潜在策略。共轭嵌段共聚物由于其高灵活性而获得了极大的关注，允许定制聚合物结构以满足不同器件特性的特定要求。本研究首次成功合成了刚性聚萘二亚胺-二噻吩和柔性聚异丁烯段组成的新型n型多嵌段共聚物（multi- bcp）作为聚合物半导体。这些材料是根据软段的重量分数命名的：NDI (0 wt %), mAB73 （27 wt %）和mAB60 （40 wt %）。该研究探讨了柔性多bcp的机械性能、结晶度和电性能。结果表明，引入软段可显著提高拉伸性能，由于软段弹性模量较低，在40 ~ 50 MPa之间，裂纹启动应变超过100%。此外，由于过量的聚异丁烯块，mAB73的OFET器件在100%应变下实现了不变的迁移率，优于mAB60。在本研究的最后，利用微裂金技术将多bcp通道与接触电极相结合，实现了具有高拉伸性的集成可拉伸器件。该集成装置可应用于生物医学电子领域，无需使用有毒或腐蚀性电极材料。系统研究了接触电阻、通道电荷迁移率和电极电阻等影响因素，探讨了集成器件的迁移率-拉伸性关系。结果表明，多bcp通道与接触电极之间的接触电阻对器件的性能至关重要。其中，含有软段的mAB73表现出比NDI更强的稳定性，这是由于在橡胶通道表面嵌入了金纳米粒子的微裂纹金电极。适当地结合软段可以显著提高拉伸应变下的迁移率保持，突出了多bcp设计在可拉伸电子应用中的潜力。

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来源期刊

ACS Applied Materials & Interfaces 工程技术-材料科学：综合

CiteScore

16.00

自引率

6.30%

发文量

4978

审稿时长

1.8 months

期刊介绍： ACS Applied Materials & Interfaces is a leading interdisciplinary journal that brings together chemists, engineers, physicists, and biologists to explore the development and utilization of newly-discovered materials and interfacial processes for specific applications. Our journal has experienced remarkable growth since its establishment in 2009, both in terms of the number of articles published and the impact of the research showcased. We are proud to foster a truly global community, with the majority of published articles originating from outside the United States, reflecting the rapid growth of applied research worldwide.