用于可穿戴和植入式电子设备的低阻抗导电纳米复合材料的最新进展

Yaozhu Chu , Zhao Sha , Sonya A. Brown , Shuai He , Shuying Wu , Chun H. Wang , Shuhua Peng
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摘要

柔性和可拉伸电子器件的最新进展凸显了在拉伸条件下保持基本电气性能的重要性,尤其是在可穿戴技术中。将可拉伸导体集成到软传感器和可拉伸电池等可穿戴设备中,凸显了提高耐用性和性能的努力。尽管对可拉伸导体的开发进行了广泛的研究,但在现有文献中,可拉伸电极的阻抗特性在很大程度上没有得到深入研究。本综述论文旨在通过全面概述材料和结构设计方面的最新进展,为可拉伸电极的阻抗特性量身定制,从而弥合这一差距。论文深入探讨了各种导电材料,包括金属、液态金属、导电聚合物、水凝胶和纺织品,每种材料都具有适合特定应用的独特性能。此外,它还讨论了所采用的各种制造方法,如直接混合、表面涂层/沉积、印刷以及创建导电网络的专门技术。除了材料和制造策略外,本综述还探讨了能够适应大变形的创新结构概念,如蛇形结构、盘绕结构、叽里格米结构和开网状结构。这些设计不仅增强了可拉伸电子器件的机械弹性,还有助于提高其电气性能,尤其是在低阻抗电子应用中。最后,本文深入探讨了低阻抗导电纳米复合材料在可穿戴电子设备中的新兴应用,解决了关键挑战,并讨论了未来的研究方向。
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Recent advances in low-impedance conductive nanocomposites for wearable and implantable electronics

Recent advancements in flexible and stretchable electronics have underscored the critical importance of maintaining essential electrical properties under stretching conditions, especially in wearable technology. The integration of stretchable conductors into wearable devices, such as soft sensors and stretchable batteries, highlights efforts to enhance durability and performance. Despite extensive studies into the development of stretchable conductors, the impedance characteristics of stretchable electrodes have largely evaded in-depth examination within existing literature. This review paper aims to bridge this gap by offering a comprehensive overview of recent advancements in both material and structural designs tailored for impedance property of stretchable electrodes. It delves into the exploration of various conductive materials, including metals, liquid metals, conducting polymers, hydrogels, and textiles, each offering unique properties suited for specific applications. Moreover, it discusses the diverse fabrication methods employed, such as direct mixing, surface coating/deposition, printing, and specialized techniques for creating electrically conductive networks. Beyond material and fabrication strategies, the review also explores innovative structural concepts capable of accommodating large deformations, such as serpentine, coiled, Kirigami, and open-mesh structures. These designs not only enhance the mechanical resilience of stretchable electronics but also contribute to their electrical performance, particularly in low impedance electronic applications. Finally, the paper provides insights into the emerging applications of conductive nanocomposites with low impedance for wearable electronics, addressing key challenges and discussing future research directions.

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