材料科学
导电体
联锁
胶粘剂
复合材料
分层(地质)
韧性
弹性体
电极
可伸缩电子设备
粘附
数码产品
柔性电子器件
聚合物
导电聚合物
纳米复合材料
导电的
纳米技术
制作
聚氨酯
铜
脚手架
印刷电路板
作者
Gang Li,Minkun Cai,Chunyan Cao,Zijun Ouyang,Hong Fu,Lingyu Zhao,Bingang Xu
摘要
ABSTRACT The pronounced mismatch between polymeric electrodes and metallic components hinders the formation of robust electrical contacts. While most approaches rely on chemical design to strengthen interfacial interactions, we present a double‐sided mechanical interlocking strategy that provides both stability and adaptability. A conductive fabric scaffold bridges polymers and metals, with adhesives sequentially applied to both sides. The adhesive infiltrates and encapsulates scaffold fibers, forming a thread–hole adhesion that can only be disrupted by bulk failure. This mechanism achieves a record high interfacial toughness of 730 J m − 2 between conductive elastomer and copper using commercial silver pastes. Peeling tests show delamination occurs between silver paste and copper, indicating even higher toughness could be obtained with better‐performing products of conductive adhesive. Notably, the interface stability surpasses that of the electrode itself, remaining intact even when the electrode fails. The design is broadly compatible with elastomeric or hydrogel matrices and with diverse commercial adhesives. It enables the construction of reliable epidermal electronics and hydrogel‐based devices. Overall, this interlocking strategy provides a versatile platform for integrating soft and rigid conductors in hybrid electronic systems.
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