材料科学
复合材料
介电弹性体
弹性体
热稳定性
硅橡胶
电介质
韧性
纳米复合材料
可伸缩电子设备
数码产品
光电子学
化学工程
工程类
化学
物理化学
作者
Robert Herbert,Piotr Mocny,Yuqi Zhao,Ting‐Chih Lin,Junbo Zhang,Michael Vinciguerra,Sunny Surprenant,Wui Yarn Chan,Swarun Kumar,Michael R. Bockstaller,Krzysztof Matyjaszewski,Carmel Majidi
标识
DOI:10.1002/adfm.202309725
摘要
Abstract Liquid‐metal embedded elastomers (LMEEs) have been demonstrated to show a variety of excellent properties, including high toughness, dielectric constant, and thermal conductivity, with applications across soft electronics and robotics. However, within this scope of use cases, operation in extreme environments – such as high‐temperature conditions – may lead to material degradation. While prior works highlight the functionality of LMEEs, there is limited insight on the thermal stability of these soft materials and how the effects of liquid metal (LM) inclusions depend on temperature. Here, the effects on thermal stability, including mechanical and electrical properties, of LMEEs are introduced. Effects are characterized for both fluoroelastomer and other elastomer‐based composites at temperature exposures up to 325 °C, where it is shown that embedding LM can offer improvements in thermo‐mechanical stability. Compared to elastomer like silicone rubber that has been previously used for LMEEs, a fluoroelastomer matrix offers a higher dielectric constant and significant improvement in thermo‐mechanical stability without sacrificing room temperature properties, such as thermal conductivity and modulus. Fluoroelastomer‐LM composites offer a promising soft, multi‐functional material for high‐temperature applications, which is demonstrated here with a printed, soft heat sink and an endoscopic sensor capable of wireless sensing of high temperatures.
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