Silicon Graphite Composite Anode Degradation: Effects of Silicon Ratio, Current Density, and Temperature

Choi, Jongeun; Kim, Giyong; Kim, Sung Yeol

doi:10.1002/ente.202201444

Cited by 4 publications

(1 citation statement)

References 34 publications

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“…Research has explored Si-graphite blending to address the challenging issues associated with Si as a viable method for developing next-generation anode materials that offer higher specific capacity and more enhanced energy densities than graphite systems. − In electrodes containing a blend of graphite with Si, graphite offers excellent conductivity and facilitates the process of electrode calendaring, ultimately leading to increased electrode density. Moreover, graphite enhances the ICE values, cyclability, and calendar life of the electrode and accommodates the anisotropic expansion of Si upon a continuous cycling process. , However, the efficient use of this blending strategy is constrained by the obligation to maintain a SiO x content level below 4 wt %.…”

Section: Introductionmentioning

confidence: 99%

Stabilizing the Solid Electrolyte Interface Using a Zero-Strain Feature Protective Layer for a High-Performance Silicon–Graphite Anode

Jayasubramaniyan,

Lee,

Kim

et al. 2024

Energy Fuels

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Commercial graphite-based Li-ion batteries almost reached their maximum energy density limits, and the need for high-energy batteries increased tremendously. Silicon (Si) has become a viable anode; however, its enormous volume expansion limits its application. In this regard, the silicon−graphite (Si-G) composite is considered a potential anode to boost the energy density of graphite and alleviate the limitations of silicon. However, the formation of an unstable solid electrolyte interface (SEI) layer impedes its use in practical applications. Hence, constructing a stable SEI layer is crucial to attaining stable and long-term cyclability for Si-G. In this study, we investigated the influence of the Li 4 Ti 5 O 12 (LTO) protective coating on the Si-G composite anode toward the stable SEI layer formation. We found that the LTO coating on Si-G effectively suppresses the parasitic reaction of organic electrolytes with Si and facilitates stable SEI layer formation. In particular, the cross-sectional analysis of the LTO-Si-G electrode using transmission electron microscopy after cycling confirms the presence of stable and thin SEI. In addition, the electrode showed a higher Coulombic efficiency of 99.82%, a high specific capacity of 570.48 mAh g −1 , and enhanced capacity retention of 97.7% after 75 cycles. Our findings highlight that constructing a stable SEI by encasing the Si-G surface with LTO is a promising way to enhance the cycling performance of high-energy Li-ion batteries with the Si-G composite anode.

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Section: Introductionmentioning

confidence: 99%

Stabilizing the Solid Electrolyte Interface Using a Zero-Strain Feature Protective Layer for a High-Performance Silicon–Graphite Anode

Jayasubramaniyan,

Lee,

Kim

et al. 2024

Energy Fuels

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Vertical channels enable excellent lithium storage kinetics and cycling stability in silicon/carbon thick electrode

Zhang,

Wang

et al. 2024

Carbon Energy

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Constructing silicon (Si)‐based composite electrodes that possess high energy density, long cycle life, and fast charging capability simultaneously is critical for the development of high performance lithium‐ion batteries for mitigating range anxiety and slow charging issues in new energy vehicles. Herein, a thick silicon/carbon composite electrode with vertically aligned channels in the thickness direction (VC‐SC) is constructed by employing a bubble formation method. Both experimental characterizations and theoretical simulations confirm that the obtained vertical channel structure can effectively address the problem of sluggish ion transport caused by high tortuosity in conventional thick electrodes, conspicuously enhance reaction kinetics, reduce polarization and side reactions, mitigate stress, increase the utilization of active materials, and promote cycling stability of the thick electrode. Consequently, when paired with LiNi0.6Co0.2Mn0.2O2 (NCM622), the VC‐SC||NCM622 pouch type full cell (~6.0 mAh cm−2) exhibits significantly improved rate performance and capacity retention compared with the SC||NCM622 full cell with the conventional silicon/carbon composite electrode without channels (SC) as the anode. The assembled VC‐SC||NCM622 pouch full cell with a high energy density of 490.3 Wh kg−1 also reveals a remarkable fast charging capability at a high current density of 2.0 mA cm−2, with a capacity retention of 72.0% after 500 cycles.

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Deciphering the Impact of Current, Composition, and Potential on the Lithiation Behavior of Si‐Rich Silicon‐Graphite Anodes

Schweigart,

Hua,

Sánchez

et al. 2024

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Adding silicon (Si) to graphite (Gr) anodes is an effective approach for boosting the energy density of lithium‐ion batteries, but it also triggers mechanical instability due to Si volume changes upon (de)lithiation reactions. In this work, component‐specific (de)lithiation dynamics on Si‐rich (30 and 70 wt.% Si) SiGr anodes at various charge/discharge C‐rates are unveiled and compared to a graphite‐only electrode (100Gr) via operando synchrotron X‐ray diffraction coupled with differential capacity plots analysis. Results show preferential lithiation of amorphous Si above ≈200 mV and competing lithiation of Gr, amorphous Si, and crystalline Si below ≈200 mV. Discharge proceeds via sequential delithiation of Gr and amorphous lithium silicide. Si shifts the interconversion potentials of graphite intercalation compounds, lowering the Gr state of charge compared to 100Gr. In the 30% Si electrode, crystalline Si amorphization at potentials <110 mV is found to be kinetically hindered at C‐rates higher than C/5, which can be key for enhancing the cycling stability of SiGr anodes. The 70% Si electrode exhibits restricted lithium diffusion in Gr, full Si amorphization, and Li15Si4 formation. These findings related to the potential‐ and current‐dependent dynamic changes on SiGr blends are crucial for designing stable high energy density SiGr anodes.

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Silicon Graphite Composite Anode Degradation: Effects of Silicon Ratio, Current Density, and Temperature

Cited by 4 publications

References 34 publications

Stabilizing the Solid Electrolyte Interface Using a Zero-Strain Feature Protective Layer for a High-Performance Silicon–Graphite Anode

Stabilizing the Solid Electrolyte Interface Using a Zero-Strain Feature Protective Layer for a High-Performance Silicon–Graphite Anode

Vertical channels enable excellent lithium storage kinetics and cycling stability in silicon/carbon thick electrode

Deciphering the Impact of Current, Composition, and Potential on the Lithiation Behavior of Si‐Rich Silicon‐Graphite Anodes

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