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使用数据驱动的机器学习通过界面电传感器对质子陶瓷电化学电池降解进行根本原因分析

Root Cause Analysis of Degradation in Protonic Ceramic Electrochemical Cell with Interfacial Electrical Sensors Using Data-Driven Machine Learning.

作者信息

Wu Wei, Wang Congjian, Bian Wenjuan, Hua Bin, Gomez Joshua Y, Orme Christopher J, Tang Wei, Stewart Frederick F, Ding Dong

机构信息

Energy & Environmental Science and Technology, Idaho National Laboratory, Idaho Falls, ID, 83415, USA.

Nuclear Science and Technology, Idaho National Laboratory, Idaho Falls, ID, 83415, USA.

出版信息

Adv Sci (Weinh). 2023 Oct;10(30):e2304074. doi: 10.1002/advs.202304074. Epub 2023 Aug 26.

DOI:10.1002/advs.202304074
PMID:37632697
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10602546/
Abstract

Protonic ceramic electrochemical cells (PCECs) offer promising paths for energy storage and conversion. Despite considerable achievements made, PCECs still face challenges such as physiochemical compatibility between componenets and suboptimal solid-solid contact at the interfaces between the electrolytes and electrodes. In this study, a novel approach is proposed that combines in situ electrochemical characterization of interfacial electrical sensor embedded PCECs and machine learning to quantify the contributions of different cell components to total degradation, as well as to predict the remaining useful life. The experimental results suggest that the overpotential induced by the oxygen electrode is 48% less than that of oxygen electrode/electrolyte interfacial contact for up to 1171 h. The data-driven machine learning simulation predicts the RUL of up to 2132 h. The root cause of degradation is overpotential increase induced by oxygen electrode, which accounts for 82.9% of total cell degradation. The success of the failure diagnostic model is demonstrated by its consistency with degradation modes that do not manifest in electrolysis fade during early real operations. This synergistic approach provides valuable insights into practical failure diagnosis of PCECs and has the potential to revolutionize their development by enabling improved performance prediction and material selection for enhanced durability and efficiency.

摘要

质子陶瓷电化学电池(PCEC)为能量存储和转换提供了有前景的途径。尽管已取得了相当大的成就,但PCEC仍面临挑战,例如组件之间的物理化学兼容性以及电解质与电极之间界面处的固-固接触不理想。在本研究中,提出了一种新颖的方法,该方法将嵌入界面电传感器的PCEC的原位电化学表征与机器学习相结合,以量化不同电池组件对总降解的贡献,并预测剩余使用寿命。实验结果表明,在长达1171小时的时间内,氧电极引起的过电位比氧电极/电解质界面接触引起的过电位低48%。数据驱动的机器学习模拟预测剩余使用寿命长达2132小时。降解的根本原因是氧电极引起的过电位增加,其占电池总降解的82.9%。故障诊断模型的成功通过其与早期实际运行中未在电解衰减中表现出的降解模式的一致性得到证明。这种协同方法为PCEC的实际故障诊断提供了有价值的见解,并有可能通过实现改进的性能预测和材料选择以提高耐久性和效率来彻底改变其发展。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/eb7a/10602546/252364dddc55/ADVS-10-2304074-g008.jpg
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