Cole-Cole Modelling of Reduced Graphene Oxide Decorated CuO Nano-Spheres Based Waterproof Conductive Ink for Flexible Electrodes

2021 38th National Radio Science Conference (NRSC) Pub Date : 2021-07-27 DOI:10.1109/NRSC52299.2021.9509778

A. Maged, A. Madian, Amany I. Raafat, A. E. Ali

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Abstract

Flexible electrodes are developed using a novel conductive ink with various ratios of graphene nanoflakes decorated with copper nanospheres as a conductive filler. These electrodes represent potential candidates for energy storage devices and solid-state batteries. The electrodes are studied by AC measurements in the range of (0.1 Hz–500 kHz). Electrical impedance measurement data have been utilized for modeling the electrical properties of the conductive ink. The fitting is done using Z-Fit software and a randomized method followed by the Levenberg-Marquardt using the Cole-Cole model. The equivalent circuits are simulated by the Z-Sim software and values are compared with the theoretical values. The error between simulation value and theoretical value was found to be minimum. The aim of the work described in the present paper is to establish an equivalent electrical circuit for the conductive ink electrodes. The best and simplest circuit representation which gives the best fitting for the Cole-Cole and Nyquist plots consists of two resistors in parallel with a capacitor in series. The values of the electrical components are tabled, and the Cole-Cole plot is fitted to the measured data.

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柔性电极用还原氧化石墨烯修饰CuO纳米球基防水导电油墨的Cole-Cole建模

采用不同比例的石墨烯纳米片和铜纳米球作为导电填料，制备了柔性电极。这些电极代表了能量存储设备和固态电池的潜在候选者。通过交流测量(0.1 Hz-500 kHz)对电极进行了研究。利用电阻抗测量数据对导电油墨的电性能进行了建模。使用Z-Fit软件和随机方法进行拟合，然后使用Cole-Cole模型进行Levenberg-Marquardt。利用Z-Sim软件对等效电路进行了仿真，并与理论值进行了比较。仿真值与理论值之间的误差最小。本文所述工作的目的是建立导电油墨电极的等效电路。最适合Cole-Cole和Nyquist图的最佳和最简单的电路表示由两个并联电阻和一个串联电容组成。将电子元件的数值制成表格，并用Cole-Cole图拟合测量数据。

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2021 38th National Radio Science Conference (NRSC)

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