Predicting the sheet resistance of laser-induced graphitic carbon using machine learning

IF 2.8 4区 工程技术 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY Flexible and Printed Electronics Pub Date : 2023-08-07 DOI:10.1088/2058-8585/acedbf
H. Le, Aamir Minhas-Khan, S. Nambi, Gerd Grau, Wen Shen, Dazhong Wu
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Abstract

While laser-induced graphitic carbon (LIGC) has been used to fabricate cost-effective conductive carbon on flexible substrates for applications such as sensors and energy storage devices, predicting the resistance of the component fabricated via LIGC remains challenging. In this study, a two-step machine learning-based modeling framework is developed to predict the sheet resistance of the materials fabricated using LIGC. The two-step modeling framework consists of classification and regression. First, random forest (RF) is used to classify successful and failed trials. Second, extreme gradient boosting (XGBoost), RF, support vector machine with radial basis function, multivariate adaptive spline regression, and multilayer perceptron are used to predict the sheet resistance in each successful trial. In addition, an analysis of the change in sheet resistance with respect to laser energy per unit area is conducted to remove data points with high sheet resistance. XGBoost is also used to determine the importance of each process parameter. We demonstrate the modeling framework on datasets collected from experiments where LIGC lines (1D) and LIGC squares (2D) are engraved. For the 1D dataset, the RF classification model achieves a 95% accuracy. For both 1D and 2D datasets, a comparative study shows that XGBoost outperforms other algorithms. XGBoost predicts the sheet resistance of the LIGC lines and squares with a MAPE of 7.08% and 8.75%, respectively. XGBoost also identifies laser resolution as the most significant parameter. Moreover, experimental results show that models built on the dataset merging the 1D and 2D datasets result in lower prediction accuracy than those built on the 1D and 2D datasets separately. The modeling framework allows one to determine the sheet resistance of LIGC with varying laser processing conditions without conducting expensive and time-consuming experiments.
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利用机器学习预测激光诱导石墨碳的薄片电阻
虽然激光诱导石墨碳(LIGC)已被用于在柔性基板上制造具有成本效益的导电碳,用于传感器和储能设备等应用,但预测通过LIGC制造的部件的电阻仍然具有挑战性。在这项研究中,开发了一个基于两步机器学习的建模框架来预测使用LIGC制造的材料的薄层电阻。两步建模框架包括分类和回归。首先,随机森林(RF)用于对成功和失败的试验进行分类。其次,在每次成功的试验中,使用极限梯度增强(XGBoost)、RF、具有径向基函数的支持向量机、多元自适应样条回归和多层感知器来预测薄层电阻。此外,对片电阻相对于每单位面积的激光能量的变化进行分析,以去除具有高片电阻的数据点。XGBoost还用于确定每个工艺参数的重要性。我们在从雕刻LIGC线(1D)和LIGC正方形(2D)的实验中收集的数据集上演示了建模框架。对于1D数据集,RF分类模型实现了95%的准确率。对于1D和2D数据集,比较研究表明XGBoost优于其他算法。XGBoost预测LIGC线和正方形的薄层电阻,MAPE分别为7.08%和8.75%。XGBoost还将激光分辨率确定为最重要的参数。此外,实验结果表明,在合并1D和2D数据集的数据集上建立的模型比分别在1D和二维数据集上构建的模型的预测精度更低。该建模框架允许在不进行昂贵和耗时的实验的情况下,在不同的激光加工条件下确定LIGC的薄层电阻。
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来源期刊
Flexible and Printed Electronics
Flexible and Printed Electronics MATERIALS SCIENCE, MULTIDISCIPLINARY-
CiteScore
4.80
自引率
9.70%
发文量
101
期刊介绍: Flexible and Printed Electronics is a multidisciplinary journal publishing cutting edge research articles on electronics that can be either flexible, plastic, stretchable, conformable or printed. Research related to electronic materials, manufacturing techniques, components or systems which meets any one (or more) of the above criteria is suitable for publication in the journal. Subjects included in the journal range from flexible materials and printing techniques, design or modelling of electrical systems and components, advanced fabrication methods and bioelectronics, to the properties of devices and end user applications.
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