柔性和可拉伸三维结构在软电子中的应用

Soft science Pub Date : 2023-01-01 DOI:10.20517/ss.2023.07
Jang Hwan Kim, Su Eon Lee, Bong Hoon Kim
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引用次数: 0

摘要

可以在几何布局中进行机械变形的器件的开发,例如柔性/可拉伸器件,对于各种应用都很重要。传统的柔性/可拉伸设备已经使用二维(2D)几何结构进行了演示,导致设备操作和功能限制的尺寸限制。因此,扩大此类设备可以操作的尺寸并获得难以在二维平面结构中实现的独特功能仍然具有挑战性。作为一种解决方案,通过精确控制二维结构或直接构建来嵌入三维(3D)结构的柔性/可拉伸装置的开发已经引起了人们的极大关注。由于大量的努力,已经证明了几种具有独特工程特性的3D材料系统,包括电学、光学、热学和机械性能,这些特性在自然界中很难发生或在通常的2D材料系统中难以获得。此外,具有灵活性和可拉伸性的3D先进材料系统可以为开发各种形状因素的设备提供额外的选择。本文通过多个应用案例,综述了柔性/可拉伸3D材料系统的新型制造方法和前所未有的物理性能。此外,我们还总结了通过引入先进的3D系统在各个领域的创新应用的最新进展和趋势,包括微机电系统、光电子、能源设备、生物医学设备、传感器、执行器、超材料和微流体系统。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Applications of flexible and stretchable three-dimensional structures for soft electronics
The development of devices that can be mechanically deformed in geometrical layouts, such as flexible/stretchable devices, is important for various applications. Conventional flexible/stretchable devices have been demonstrated using two-dimensional (2D) geometry, resulting in dimensional constraints on device operations and functionality limitations. Accordingly, expanding the dimensions in which such devices can operate and acquiring unique functionality that is difficult to implement in 2D planar structures remain challenging. As a solution, the development of a flexible/stretchable device embedding a three-dimensional (3D) structure fabricated through the precise control of a 2D structure or direct construction has been attracting significant attention. Because of a significant amount of effort, several 3D material systems with distinctive engineering properties, including electrical, optical, thermal, and mechanical properties, which are difficult to occur in nature or to obtain in usual 2D material systems, have been demonstrated. Furthermore, 3D advanced material systems with flexibility and stretchability can provide additional options for developing devices with various form factors. In this review, novel fabrication methods and unprecedented physical properties of flexible/stretchable 3D material systems are reviewed through multiple application cases. In addition, we summarized the latest advances and trends in innovative applications implemented through the introduction of advanced 3D systems in various fields, including microelectromechanical systems, optoelectronics, energy devices, biomedical devices, sensors, actuators, metamaterials, and microfluidic systems.
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CiteScore
3.10
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