基于石墨烯纳米片薄膜的高性能多响应电子皮肤的直接制备

Soft science Pub Date : 2022-01-01 DOI:10.20517/ss.2022.18
Xi Zhang, Xiaolin Li, Xusheng Wang, Lin Yuan, Jing Ye, Xin Wang, Hualin Deng, Bo Wen, Dong-feng Diao
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引用次数: 4

摘要

随着可穿戴设备的日益普及,轻量化电子皮肤(e-skin)引起了人们的极大关注。然而,目前的制造技术使得在低温下在柔性衬底上直接制造传感材料变得困难。因此,我们提出了一种柔性石墨烯纳米片嵌入碳(F-GNEC)薄膜,该薄膜使用电子回旋共振低温溅射系统直接生长在柔性衬底上。利用独特的电子回旋共振等离子体产生模式和等离子体与衬底表面之间的极化子能量传递模式,实现了电子皮肤的直接批量制造。F-GNEC薄膜包含大量垂直生长的石墨烯纳米片,石墨烯边缘可以作为电子捕获中心,从而实现多响应特性。当拉伸应变ε = 0.5%时,测量系数达到14699,当电子蒙皮弯曲至120°时,电阻变化率达到113.2%。在532 nm激光照射下,电子皮肤的光电流达到1.2 μA。F-GNEC薄膜表现出敏感的温度响应,在30-100°C的宽温度范围内达到-0.58%/°C的系数。直接制备的基于F-GNEC薄膜的电子皮肤稳定坚固,具有多响应检测能力,在虚拟现实技术和柔性机器人中具有潜在的应用前景。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Direct fabrication of high-performance multi-response e-skin based on a graphene nanosheet film
With the increasing popularity of wearable devices, lightweight electronic skin (e-skin) has attracted significant attention. However, current fabrication technologies make it difficult to directly fabricate sensing materials on flexible substrates at low temperatures. Hence, we propose a flexible graphene nanosheet-embedded carbon (F-GNEC) film, which is directly grown on a flexible substrate using an electron cyclotron resonance low-temperature sputtering system. The direct batch manufacturing of e-skin is obtained by the unique plasma generation mode of electron cyclotron resonance and the polariton energy transfer mode between the plasma and substrate surface. The F-GNEC film contains a large number of graphene nanosheets grown vertically and the graphene edges can serve as electron capture centers, thereby enabling the multi-response properties. We achieve a high gauge factor of 14,699 under a tensile strain of ε = 0.5% and the changing rate of the resistance reaches to 113.2% when the e-skin is bent to 120°. Furthermore, the e-skin achieves a photocurrent of 1.2 μA under 532 nm laser illumination. The F-GNEC film exhibits a sensitive temperature response and achieves a coefficient of -0.58%/°C in a wide temperature range (30-100 °C). The directly fabricated F-GNEC film-based e-skin is stable and firm and exhibits multi-response detection capabilities, which enable its potential application in virtual reality technology and flexible robots.
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