基于摩擦电源的高压离子迁移率气体识别可行性研究

D. Hasan, Jianxiong Zhu, Hao Wang, Othman Bin Sulaiman, Mahmut Sami Yazici, T. Grzebyk, R. Walczak, J. Dziuban, Chengkuo Lee
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引用次数: 2

摘要

我们报告了一种用于可穿戴应用的小型化和自供电气体识别平台,该平台基于离子迁移瞬态原理,为各种气体提供了高度的选择性。传感器的自供电操作利用了系统设计的摩擦纳米发电机(TENG)的高电压输出。多层TENG平台仅通过手指触发即可提供千伏数量级的电压,并进一步利用特殊类型的电极(尖端板)配置,使其能够在大气条件下获得大范围气体分子的等离子体放电。通过在器件配置的特定距离上添加一个额外的集电极,我们成功地证明了不同气体分子的不同瞬态特性,这可以直接归因于它们在离子迁移率方面的差异。我们的分析清楚地表明,在各种混合条件和大气压下,独特和可重复的放电特性。我们进一步利用机器学习根据在集热器板上观察到的瞬态动力学对不同的气体进行分类。即使使用浅层网络,对四种不同的气体也获得了很高的分类精度,这表明该平台有潜力成为一种低功耗、小占地面积的可穿戴物联网(iot)气体泄漏检测设备。设想所提出的平台可以通过将大量时域指纹的瞬态发展纳入机器学习模型来实现气体种类的早期检测。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Feasibility Study of High-Voltage Ion Mobility for Gas Identification Based on Triboelectric Power Source
We report a type of miniaturized and self-powered gas identification platform for wearable applications that works on the principle of ion mobility transients offering a high degree of selectivity for a variety of gas species. The self-powered operation of the sensor exploited the high voltage output from a systematically designed triboelectric nanogenerator (TENG). The multi-layer TENG platform provided a voltage of the order kV just by finger triggering, which was further leveraged in a special type of electrode (tip-plate) configuration making it possible to obtain plasma discharge of a wide range of gas molecules at atmospheric condition. By adding an additional collector plate at a specific distance within the device configuration, we successfully demonstrated different transient characteristics for different gas molecules which can be directly attributed to their differences in terms of ion-mobility. Our analysis clearly indicated unique and repeatable discharge characteristics at various mixture conditions and atmospheric pressure. We further employ machine learning to classify different gases based on the transient dynamics observed at the collector plate. High classification accuracy was obtained for four different gases even using a shallow network that indicated the potential of the proposed platform as a low-power, small foot-print wearable Internet of Things (IoTs) device for gas leak detection. It is envisioned that the proposed platform can enable early detection of gas species by incorporating the transient development of the multitude of time-domain finger-prints into the machine learning model.
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