优化锂离子电池中三维电极的结构模式,提高快速充电能力并减少锂镀层

IF 4.6 4区 化学 Q2 ELECTROCHEMISTRY Batteries Pub Date : 2024-05-11 DOI:10.3390/batteries10050160
Y. Sterzl, Wilhelm Pfleging
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引用次数: 0

摘要

在全电池和对称电池的可比设置中评估了阳极结构最常见的图案类型,特别是线条、网格和六边形排列孔图案。采用结构化电极的电池与采用非结构化阳极的参考电池进行了比较,两者的平均容量(4.3 mAh cm-2)相近,并通过电压弛豫的差分电压分析和死后分析确定了快速充电期间锂镀层的发生情况。此外,还对对称电池进行了电化学阻抗光谱测量,以确定类似面积容量的结构化电极和非结构化电极的离子电阻。与采用非结构化电极的电池相比,所有采用结构化电极的电池都显示出较低的离子电阻,并且锂镀层开始向较高的 C 速率转移。与采用非结构化电极的参比电池和采用孔状结构化电极的电池相比,采用毛细管结构(即线状和网格状)的结构模式在快速充电过程中明显减少了锂镀层,并具有更高的速率能力。三维电极通过毛细力使液体电解质不断重新润湿电极,并降低了离子电阻,这两点被认为是提高电池整体性能的关键因素。所研究电池的数据被用来计算未来商用袋装电池的能量和功率密度,并找出了与非结构化电极电池相比可能存在的缺陷。
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Optimizing Structural Patterns for 3D Electrodes in Lithium-Ion Batteries for Enhanced Fast-Charging Capability and Reduced Lithium Plating
The most common pattern types for anode structuring, in particular the line, grid, and hexagonal-arranged hole pattern were evaluated in a comparable setup in full-cells and symmetrical cells. The cells with structured electrodes were compared to reference cells with unstructured anodes of similar areal capacity (4.3 mAh cm−2) and the onset of lithium plating during fast-charging was determined in situ by differential voltage analysis of the voltage relaxation and ex situ by post-mortem analysis. Furthermore, electrochemical impedance spectroscopy measurements on symmetrical cells were used to determine the ionic resistance of structured and unstructured electrodes of similar areal capacity. All cells with structured electrodes showed lower ionic resistances and an onset of lithium plating shifted to higher C-rates compared to cells with unstructured electrodes. The structure patterns with capillary structures, i.e., lines and grids, showed significant reduced lithium plating during fast-charging and a higher rate capability compared to reference cells with unstructured electrodes and cells with hole structured electrodes. The continuous rewetting of the electrode with liquid electrolyte by capillary forces and the reduced ionic resistance of the 3D electrode are identified as key factors in improving overall battery performance. The data of the studied cells were used to calculate the resulting energy and power densities of prospective commercial pouch cells and potential pitfalls in the comparison to cells with unstructured electrodes were identified.
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来源期刊
Batteries
Batteries Energy-Energy Engineering and Power Technology
CiteScore
4.00
自引率
15.00%
发文量
217
审稿时长
7 weeks
期刊最新文献
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