Comprehensive Study of the Resistance of Pencil-Stroked Graphite on Paper Electrodes

The Physics Educator Pub Date : 2022-03-01 DOI:10.1142/s2661339522500019

Jeevakaarthik Dhanabalan, Gareth Rui Jye Chua, Bernard Ricardo

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引用次数: 1

Abstract

In this paper, we comprehensively study the electrical resistance of pencil-stroked graphite electrodes, which is a cheap electrical conductor. Thin graphite on paper (GOP) electrodes were manually fabricated by unidirectionally stroking rectangular areas defined by grids on graph paper, allowing the physical dimensions of the layer to be accurately represented. The physical dimensions of the electrode were then varied and the I–V relationship for the layer was characterized. Our findings indicate that these thin electrodes behave as ohmic conductors over the low voltage range (0–12 V), and their resistance can be quantitatively described by Pouillet’s Law [Formula: see text]. The deviation of the experimentally obtained linear I–V characteristic from the theoretical nonlinear I–V characteristic of graphite has been explained by measuring the temperature rise of the graphite electrode, which was found to be insignificant [Formula: see text] in the low voltage range. The effects of saturation level of the electrode and pencil grade on electrode resistance are also elaborated in this paper. By showing the turbostratic nature of graphite in GOP and analyzing its electronic conduction mechanism, the experimental observations have been explained theoretically. We also note the highly interesting low-energy electron dynamics in GOP reported previously in misoriented multilayer graphitic systems. We observed insignificant changes in electrode resistivity over five-minute intervals and repeated use. Hence, these electrodes exhibit great stability as a low-voltage electrical conductor. The flexibility, usability, and ease-of-synthesis of these thin graphite layers in large volumes, coupled with their remarkable electrical properties, present a novel approach for adopting them in designs of low-cost and high-performance sensors, foldable electronics, and microfluidics, paving the way for an electronics industry that can meet the stipulations of many more products.

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铅笔笔触石墨在纸电极上电阻的综合研究

本文对石墨电极的电阻进行了全面的研究，它是一种廉价的导电体。薄纸上石墨(GOP)电极是通过在方格纸上单向描划矩形区域来手工制作的，可以准确地表示层的物理尺寸。然后改变电极的物理尺寸，并表征了层的I-V关系。我们的研究结果表明，这些薄电极在低电压范围内(0-12 V)表现为欧姆导体，它们的电阻可以用Pouillet定律定量描述[公式:见文本]。通过测量石墨电极的温升，解释了实验得到的线性I-V特性与理论的非线性I-V特性的偏差，发现在低电压范围内这种偏差不显著[公式:见文]。本文还阐述了电极饱和水平和铅笔等级对电极电阻的影响。通过对石墨在GOP中的涡层特性和电子传导机理的分析，对实验结果进行了理论解释。我们还注意到先前在错取向多层石墨体系中报道的高度有趣的GOP低能电子动力学。我们观察到电极电阻率在五分钟间隔和重复使用中没有显著变化。因此，这些电极作为低压电导体表现出极大的稳定性。这些薄石墨层的灵活性、可用性和易于大量合成，再加上它们卓越的电性能，为采用它们设计低成本和高性能传感器、可折叠电子产品和微流体提供了一种新方法，为电子工业能够满足更多产品的规定铺平了道路。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

The Physics Educator

CiteScore

0.60

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0.00%

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