压阻效应
标准化
功勋
可穿戴技术
水准点(测量)
标度系数
计算机科学
可穿戴计算机
纳米复合材料
电阻式触摸屏
医疗保健
材料科学
纳米技术
机械工程
复合材料
制作
光电子学
工程类
经济
大地测量学
嵌入式系统
医学
地理
替代医学
操作系统
病理
计算机视觉
经济增长
出处
期刊:ACS Nano
[American Chemical Society]
日期:2019-11-25
卷期号:13 (12): 13627-13636
被引量:48
标识
DOI:10.1021/acsnano.9b06847
摘要
Electrically conductive nanocomposites are an exciting ever-expanding area of research that has yielded many versatile technologies for wearable health devices. Acting as strain-sensing materials, real-time medical diagnostic tools based on these materials may very well lead to a golden age of healthcare. Currently, the goal in research is to create a material that simultaneously has both a large gauge factor (G) and sensing range. However, a weakness in the area of electromechanical research is the lack of standardization in the reporting of the figure of merit (i.e., G) and the need for other intrinsic metrics to give researchers a more complete view of the research landscape of resistive-type sensors. A paradigm shift in the way in which data are reported is required, to push research in the right direction and to facilitate achieving research goals. Here, we report a standardized method for reporting strain-sensing performance and the introduction of the working factor (W) and the Young's modulus (Y) of a material as figures of merit for sensing materials. Using this standard method, we can define the benchmarks for an optimum sensing material (G > 7, W > 1, Y < 300 kPa) using limits set by standard commercial materials and the human body. Using extrapolated data from 200 publications normalized to this standard method, we can review what composite types meet these benchmark limits, what governs composite performances, the literary trends in composites, and the future prospects of research.
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