Understanding the Relationship Between Stress Change and Electrochemical Performance of a Heated SiO Anode Through In Situ Raman Spectrum

Li, Haoyu; Li, Haodong; Wang, Zhenyu; Yang, Qing; Wang, Ruoyang; Lai, Yizhu; Wang, Dong; Zhong, Benhe; Song, Yang; Guo, Xiaodong; Chen, Ting; Wu, Zhenguo

doi:10.1021/acs.jpcc.3c03556

Cited by 5 publications

(1 citation statement)

References 46 publications

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“…According to ref. 26,27 the higher the disproportionation reaction temperature, the lower the reversible capacity and ICE will be (at 1000 °C, the capacity is 696.41 mA h g −1 and the ICE is 61.39%; at 1200 °C, the capacity is 113.54 mA h g −1 and the ICE is 48.04%). In this study, Na 2 CO 3 was used for the first time to assist the disproportionation of SiO.…”

Section: Introductionmentioning

confidence: 99%

Effective disproportionation of SiO induced by Na₂CO₃ and improved cycling stability via PDA-based carbon coating as anode materials for Li-ion batteries

Chen,

Yang

et al. 2023

Dalton Trans.

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Section: Introductionmentioning

confidence: 99%

Effective disproportionation of SiO induced by Na₂CO₃ and improved cycling stability via PDA-based carbon coating as anode materials for Li-ion batteries

Chen,

Yang

et al. 2023

Dalton Trans.

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Unveiling the Oxygen Migration Retarding Effort of Carbon Coating During Disproportionation Enabling High‐ICE and Long‐Cycle‐Life SiO Anodes

Wang,

Wu,

Yang

et al. 2024

Adv Funct Materials

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Low initial coulombic efficiency (ICE) and poor cycling performance are the pain points that hinder the commercialization of silicon monoxide (SiO) anode materials. Unfortunately, disproportionation commonly used to enhance cycling performance significantly reduces prelithiation efficiency, making it difficult to achieve both high‐ICE and long‐cycle‐life SiO anodes. Herein, the intrinsic contradiction between disproportionation and prelithiation is successfully reconciled through the ingenious application of the carbon coating strategy, achieving a synergistic enhancement among the three processes (carbon coating, disproportionation, and prelithiation). The prepared SiO anode exhibits excellent electrochemical performance with an ICE as high as 113.74% and a reversible capacity of 713.68 mAh g−1 after 750 cycles. In‐depth investigations reveal that carbon optimizes the distribution of Si and O within the disproportionated SiO, effectively thinning the SiO2 surface layer and releasing the shielded Si, thereby enhancing reversible capacity and prelithiation efficiency. TG‐FTIR analysis further elucidates the underlying mechanism, demonstrating that the carbon effectively inhibits the outward migration and escape of O during disproportionation. In summary, this study uncovers the pivotal role of carbon coating in regulating the disproportionation behavior, promoting efficient prelithiation, and enhancing the capacity recovery of SiO.

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Favored Amorphous Li_xSi Process with Restrained Volume Change Enabling Long Cycling Quasi‐Solid‐State SiO_x anode

Wang,

Wu,

Niu

et al. 2024

ChemSusChem

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Silicon‐based anodes are becoming promising materials due to their high specific capacity. However, the intrinsically large volume change brought about by the alloying reaction results in the crushing of the active particles and destruction of the electrode structure, which severely limits its practical application. Various structured and modified silica‐based anodes exhibit improved cycling stability and the demonstrated ability to mitigate their volume changes through interfacial and binder strategies. However, the issue of large volume changes in silicon‐based anodes remains. Herein, we report a gel polymer electrolyte (GPE) prepared through an in situ thermal polymerization process that is suitable for SiOx anode materials and achieving long‐term cycling stability. GPE‐based cells essentially mitigate the volume change of SiOx anodes by guiding the unique lithiation/delithiation mechanism that tends to favor the formation and delithiation of amorphous‐LixSi (a‐LixSi) with smaller volume change, thereby mitigating electrode damage and cracking, and achieving the significant improvement in cycling performance. The prepared GPE‐SiOx cells retained 693.80 mAh g‐1 reversible capacity after 450 cycles at 500 mA g‐1. In addition, the prelithiation process was incorporated to mitigate capacity fluctuations and improve the Initial Coulombic Efficiency (ICE), and a reversible capacity of 641.90 mAh g‐1 was retained after 480 cycles.

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Understanding the Relationship Between Stress Change and Electrochemical Performance of a Heated SiO Anode Through In Situ Raman Spectrum

Cited by 5 publications

References 46 publications

Effective disproportionation of SiO induced by Na₂CO₃ and improved cycling stability via PDA-based carbon coating as anode materials for Li-ion batteries

Effective disproportionation of SiO induced by Na₂CO₃ and improved cycling stability via PDA-based carbon coating as anode materials for Li-ion batteries

Unveiling the Oxygen Migration Retarding Effort of Carbon Coating During Disproportionation Enabling High‐ICE and Long‐Cycle‐Life SiO Anodes

Favored Amorphous Li_xSi Process with Restrained Volume Change Enabling Long Cycling Quasi‐Solid‐State SiO_x anode

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Understanding the Relationship Between Stress Change and Electrochemical Performance of a Heated SiO Anode Through In Situ Raman Spectrum

Cited by 5 publications

References 46 publications

Effective disproportionation of SiO induced by Na2CO3 and improved cycling stability via PDA-based carbon coating as anode materials for Li-ion batteries

Effective disproportionation of SiO induced by Na2CO3 and improved cycling stability via PDA-based carbon coating as anode materials for Li-ion batteries

Unveiling the Oxygen Migration Retarding Effort of Carbon Coating During Disproportionation Enabling High‐ICE and Long‐Cycle‐Life SiO Anodes

Favored Amorphous LixSi Process with Restrained Volume Change Enabling Long Cycling Quasi‐Solid‐State SiOx anode

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Effective disproportionation of SiO induced by Na₂CO₃ and improved cycling stability via PDA-based carbon coating as anode materials for Li-ion batteries

Effective disproportionation of SiO induced by Na₂CO₃ and improved cycling stability via PDA-based carbon coating as anode materials for Li-ion batteries

Favored Amorphous Li_xSi Process with Restrained Volume Change Enabling Long Cycling Quasi‐Solid‐State SiO_x anode