锂离子电池恒电流间歇滴定技术原理及应用

IF 2.2 4区 工程技术 Q3 ELECTROCHEMISTRY Journal of electrochemical science and technology Pub Date : 2021-10-18 DOI:10.33961/jecst.2021.00836
Jaeyoung Kim, Sangbin Park, Sunhyun Hwang, W. Yoon
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引用次数: 25

摘要

锂离子电池的发展是当代最活跃的研究领域之一,近年来随着储能技术的日益重要而受到越来越多的关注。恒流间歇滴定技术(git)已成为电池研究中各种电化学分析的重要方法。在GITT的一个滴定步骤中,包括一个恒流脉冲,然后是一个松弛期,测量了瞬态和稳态电压变化。它同时绘制热力学和动力学参数。通过一系列的滴定步骤,可以推导出不同电荷状态下锂离子的扩散系数、开路电压和过电位。这篇小型综述详细介绍了GITT分析的理论和实践方面,从测量方法到根据具体实验目的推导研究案例的扩散方程。这将有助于更好地理解电化学反应,并为提高锂离子电池性能的方法提供见解。
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Principles and Applications of Galvanostatic Intermittent Titration Technique for Lithium-ion Batteries
Lithium-ion battery development is one of the most active contemporary research areas, gaining more attention in recent times, following the increasing importance of energy storage technology. The galvanostatic intermittent titration technique (GITT) has become a crucial method among various electrochemical analyses for battery research. During one titration step in GITT, which consists of a constant current pulse followed by a relaxation period, transient and steady-state voltage changes were measured. It draws both thermodynamic and kinetic parameters. The diffusion coefficients of the lithium ion, open-circuit voltages, and overpotentials at various states of charge can be deduced by a series of titration steps. This mini-review details the theoretical and practical aspects of GITT analysis, from the measurement method to the derivation of the diffusivity equation for research cases according to the specific experimental purpose. This will shed light on a better understanding of electrochemical reactions and provide insight into the methods for improving lithium-ion battery performance.
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来源期刊
CiteScore
6.30
自引率
8.10%
发文量
44
期刊介绍: Covering fields: - Batteries and Energy Storage - Biological Electrochemistry - Corrosion Science and Technology - Electroanalytical Chemistry and Sensor Technology - Electrocatalysis - Electrochemical Capacitors & Supercapcitors - Electrochemical Engineering - Electrodeposition and Surface Treatment - Environmental Science and Technology - Fuel Cells - Material Electrochemistry - Molecular Electrochemistry and Organic Electrochemistry - Physical Electrochemistry - Solar Energy Conversion and Photoelectrochemistry
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