# Interplay of Inhomogeneous Electrochemical Reactions with Mechanical   Responses in Silicon-Graphite Anode and its Impacts on Degradation

**Authors:** Junhyuk Moon (1), Shinya Wakita (1,3), Heechul Jung (1,3), Sungnim Cho, (1,3), Jaegu Yoon (1,3), Joowook Lee (1,3), Sihyung Lee (1), Kimihiko Ito, (2), Yoshimi Kubo (2), Heung Chan Lee (1), Young-Gyoon Ryu (1,3) ((1) Samsung, Advanced Institute of Technology, (2) C4GR-GREEN, National Institute for, Materials Science, (3) Samsung SDI)

arXiv: 1901.01491 · 2019-06-12

## TL;DR

This study investigates the electrochemical and mechanical interactions in silicon-graphite anodes, revealing degradation mechanisms and proposing material modifications to improve long-term battery cycle stability and energy density.

## Contribution

It uncovers electrochemical phenomena like lithium crosstalk and capacity depression, and demonstrates material modifications that enhance cycle life and energy density of silicon-graphite anodes.

## Key findings

- Silicon-graphite anodes achieve over 750 cycles with high energy density.
- Lithium crosstalk affects capacity and degradation.
- Material modifications improve reaction homogeneity and durability.

## Abstract

Enhanced EV market penetration requires durability of the battery with high energy throughput. For long-term cycle stability of silicon-graphite anode capable of high energy density, the reversible redox reactions are crucial. Here, we unveil intriguing electrochemical phenomena such as crosstalk of lithium ion ($Li^{+}$) between silicon and graphite, $Li^{+}$ accumulation in silicon, and capacity depression of graphite under high pressure, which engender the irreversible redox reactions. Active material properties, i.e. the size of silicon and the hardness of graphite, silicon-graphite anode, are modified based on the unveiled results to enhance the reaction homogeneity and reduce subsequent degradation. Owing to the property change of the anode active materials, silicon-graphite anode paired with high nickel cathode allows the prismatic cell with 8.7 Ah to reach cycling performance over 750 cycles with volumetric energy density of 665 $Whl^{-1}$, which is corresponding to 800 $Whl^{-1}$ in the prismatic cell with 87 Ah. Finally, the cycling performance can be tailored by the design of electrode regulating $Li^{+}$ crosstalk. Our findings provide electrochemical insights into degradation mechanisms and a promising direction on the progressive improvement of materials and the design of electrodes in silicon-graphite anode.

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Source: https://tomesphere.com/paper/1901.01491