Deep learning image segmentation for the reliable porosity measurement of high-capacity Ni-based oxide cathode secondary particles

IF 2.5 4区 化学 Q3 CHEMISTRY, ANALYTICAL Journal of Analytical Science and Technology Pub Date : 2023-11-21 DOI:10.1186/s40543-023-00407-z
Hee-Beom Lee, Min-Hyoung Jung, Young-Hoon Kim, Eun-Byeol Park, Woo-Sung Jang, Seon-Je Kim, Ki-ju Choi, Ji-young Park, Kee-bum Hwang, Jae-Hyun Shim, Songhun Yoon, Young-Min Kim
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Abstract

The optimization of geometrical pore control in high-capacity Ni-based cathode materials is required to enhance the cyclic performance of lithium-ion batteries. Enhanced porosity improves lithium-ion mobility by increasing the electrode–electrolyte contact area and reducing the number of ion diffusion pathways. However, excessive porosity can diminish capacity, thus necessitating optimizing pore distribution to compromise the trade-off relation. Accordingly, a statistically meaningful porosity estimation of electrode materials is required to engineer the local pore distribution inside the electrode particles. Conventional scanning electron microscopy (SEM) image-based porosity measurement can be used for this purpose. However, it is labor-intensive and subjected to human bias for low-contrast pore images, thereby potentially lowering measurement accuracy. To mitigate these difficulties, we propose an automated image segmentation method for the reliable porosity measurement of cathode materials using deep convolutional neural networks specifically trained for the analysis of porous cathode materials. Combined with the preprocessed SEM image datasets, the model trained for 100 epochs exhibits an accuracy of > 97% for feature segmentation with regard to pore detection on the input datasets. This automated method considerably reduces manual effort and human bias related to the digitization of pore features in serial section SEM image datasets used in 3D electron tomography.
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基于深度学习图像分割的高容量镍基氧化物阴极二次粒子孔隙度可靠测量
为了提高锂离子电池的循环性能,需要优化高容量镍基正极材料的几何孔隙控制。孔隙率的提高通过增加电极-电解质接触面积和减少离子扩散途径的数量来提高锂离子的迁移率。然而,过高的孔隙度会降低产能,因此有必要优化孔隙分布以折衷关系。因此,需要对电极材料进行统计上有意义的孔隙率估计,以设计电极颗粒内部的局部孔隙分布。传统的基于扫描电子显微镜(SEM)图像的孔隙度测量可用于此目的。然而,对于低对比度的孔隙图像,它是劳动密集型的,并且容易受到人为偏见的影响,从而潜在地降低了测量精度。为了减轻这些困难,我们提出了一种自动图像分割方法,用于可靠的阴极材料孔隙度测量,该方法使用深度卷积神经网络,专门用于多孔阴极材料的分析。结合预处理后的SEM图像数据集,经过100次epoch训练的模型对输入数据集的孔隙检测进行特征分割的准确率达到了> 97%。这种自动化方法大大减少了与三维电子断层扫描中使用的连续切片SEM图像数据集的孔隙特征数字化相关的人工努力和人为偏差。
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来源期刊
Journal of Analytical Science and Technology
Journal of Analytical Science and Technology Environmental Science-General Environmental Science
CiteScore
4.00
自引率
4.20%
发文量
39
审稿时长
13 weeks
期刊介绍: The Journal of Analytical Science and Technology (JAST) is a fully open access peer-reviewed scientific journal published under the brand SpringerOpen. JAST was launched by Korea Basic Science Institute in 2010. JAST publishes original research and review articles on all aspects of analytical principles, techniques, methods, procedures, and equipment. JAST’s vision is to be an internationally influential and widely read analytical science journal. Our mission is to inform and stimulate researchers to make significant professional achievements in science. We aim to provide scientists, researchers, and students worldwide with unlimited access to the latest advances of the analytical sciences.
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