Understanding particle size effect on fast-charging behavior of graphite anode using ultra-thin-layer electrodes

IF 8.9 2区 工程技术 Q1 ENERGY & FUELS Journal of energy storage Pub Date : 2024-11-17 DOI:10.1016/j.est.2024.114521
Mei Luo , Aleksandar S. Mijailovic , Guanyi Wang , Qingliu Wu , Brian W. Sheldon , Wenquan Lu
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Abstract

Extreme fast charging (≤15 min) of lithium-ion batteries is highly desirable to accelerate mass-market adoption of electric vehicles. However, significant capacity fading, as well as safety issues due to the lithium plating caused by the fast charging rate, limit its implementation. In this study, we investigated the fast-charging capability of graphite materials with various particle sizes. To eliminate the Li+ ion concentration gradient effect across the thickness of the electrode, ultra-thin-layer graphite electrodes were developed to investigate the “real” fast-charging capability of graphite at the particle level. Electrochemical assessments as well as microscopic characterizations revealed that smaller particles exhibited superior fast-charging performance, featuring enhanced capacity reversibility, faster charging rate, and less lithium plating under the same fast-charging conditions. It is shown that small-particle graphite (mean radius of 3.3 μm) could withstand a 4C charge (to 80 % state-of-charge) without plating, with minimal plating occurring at 6C. Thicker particles exhibited plating at lower C-rates. Since the experimental data could not directly explain whether intra-particle diffusion limitations or interfacial reaction limitations dominated the plating mechanism, the pseudo-2-dimensional model was used to evaluate the most likely plating mechanism. The model suggested that particle-level diffusion is the dominant mechanism contributing to plating at high rates. This work provides comprehensive insights into the particle size effects on fast-charging capability, offering a better understanding of fast-charging behavior and valuable guidance for designing optimal electrode architecture for high-rate lithium-ion batteries.

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利用超薄层电极了解粒度对石墨负极快速充电行为的影响
锂离子电池的极快速充电(≤15 分钟)是加速电动汽车大规模市场应用的理想选择。然而,由于快速充电导致的容量衰减以及锂镀层引起的安全问题,限制了其实施。在本研究中,我们研究了不同粒度石墨材料的快速充电能力。为了消除电极厚度上的锂离子浓度梯度效应,我们开发了超薄层石墨电极,以研究石墨在颗粒级别上的 "真实 "快速充电能力。电化学评估和显微特性分析表明,在相同的快速充电条件下,更小的颗粒表现出更优越的快速充电性能,具有更高的容量可逆性、更快的充电速度和更少的锂镀层。研究表明,小颗粒石墨(平均半径为 3.3 μm)可以承受 4C 充电(达到 80% 的充电状态)而不产生电镀,在 6C 时电镀现象极少。较厚的颗粒在较低的 C 速率下会出现电镀现象。由于实验数据无法直接解释电镀机制是由颗粒内扩散限制还是界面反应限制所主导,因此采用了伪二维模型来评估最可能的电镀机制。该模型表明,颗粒级扩散是导致高速率电镀的主要机制。这项研究全面揭示了颗粒尺寸对快速充电能力的影响,从而更好地理解了快速充电行为,并为设计高倍率锂离子电池的最佳电极结构提供了宝贵的指导。
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来源期刊
Journal of energy storage
Journal of energy storage Energy-Renewable Energy, Sustainability and the Environment
CiteScore
11.80
自引率
24.50%
发文量
2262
审稿时长
69 days
期刊介绍: Journal of energy storage focusses on all aspects of energy storage, in particular systems integration, electric grid integration, modelling and analysis, novel energy storage technologies, sizing and management strategies, business models for operation of storage systems and energy storage developments worldwide.
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