材料科学
生物电子学
掺杂剂
聚苯乙烯磺酸盐
导电体
导电聚合物
佩多:嘘
电极
电导率
纳米技术
烷基
丙烯酸酯
兴奋剂
聚苯乙烯
共形矩阵
复合数
聚合物
光电子学
共轭体系
信号(编程语言)
电阻率和电导率
共聚物
电子皮肤
石墨烯
高分子化学
纳米棒
作者
Yaru Yue,Tianbiao Liang,Canglang Yao,Jihe Tang,F. Y. Li,Yao Huo,Ducai Wang,Peiji Liu,Sangjin Yang,Xin Fan,Xiaoxue Lin,Dong Wang,Kuan Sun,Changduk Yang,Huajun Cao,Shanshan Chen
标识
DOI:10.1002/adma.202520074
摘要
The development of conductive polymers that simultaneously achieve high electrical conductivity and tissue-like stretchability represents a persistent challenge in bioelectronics. Here, we demonstrate an "anchoring-buffering" molecular design strategy that overcomes this limitation through rationally designed in situ polymerizable hydroxyalkyl acrylate (HAX) dopants in poly(3,4-ethylenedioxythiophene): polystyrene sulfonate (PEDOT: PSS). Our dopant architecture features rigid acrylate groups that are inferred to maintain conjugation pathways by preferentially interacting with less conjugated PEDOT regions, and hydroxyl-terminated alkyl spacers that form a dynamic hydrogen-bond network for strain dissipation. By systematically varying alkyl chain lengths (HA0 to HA4), we optimize electrostatic screening to improve doping efficiency and π-stacking order, achieving a composite film with exceptional performance (850 S/cm conductivity and 88% elongation) that surpasses existing stretchable conductive polymers. When integrated into conformal biointerfaces, the electrode maintains stable electrophysiological signal acquisition (EMG/ECG/EEG) with 99.5% gesture recognition accuracy after 24 h of continuous wear, establishing a general molecular design framework to decouple conductivity and stretchability for next-generation wearable and implantable electronics.
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