Exploring the Elastomer Influence on the Electromechanical Performance of Stretchable Conductors

材料科学 弹性体 可伸缩电子设备 导电体 复合材料 数码产品 模数 复合数 表征(材料科学) 纳米线 纳米技术 电气工程 工程类
作者
Samuel Lienemann,Ulrika Boda,Mohsen Mohammadi,Tunhe Zhou,Ioannis Petsagkourakis,Nara Kim,Klas Tybrandt
出处
期刊:ACS Applied Materials & Interfaces [American Chemical Society]
卷期号:16 (29): 38365-38376 被引量:6
标识
DOI:10.1021/acsami.4c03080
摘要

Stretchable electronics has received major attention in recent years due to the prospects of integrating electronics onto and into the human body. While many studies investigate how different conductive fillers perform in stretchable composites, the effect of different elastomers on composite performance, and the related fundamental understanding of what is causing the performance differences, is poorly understood. Here, we perform a systematic investigation of the elastomer influence on the electromechanical performance of gold nanowire-based stretchable conductors based on five chemically different elastomers of similar Young's modulus. The choice of elastomer has a huge impact on the electromechanical performance of the conductors under cyclic strain, as some composites perform well, while others fail rapidly at 100% strain cycling. The lack of macroscopic crack formation in the failing composites indicates that the key aspect for good electromechanical performance is not homogeneous films on the macroscale but rather beneficial interactions on the nanoscale. Based on the comprehensive characterization, we propose a failure mechanism related to the mechanical properties of the elastomers. By improving our understanding of elastomer influence on the mechanisms of electrical failure, we can move toward rational material design, which could greatly benefit the field of stretchable electronics.

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