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    Journals >Journal of Inorganic Materials >Volume 34 >Issue 4 >Page 349 > Article
    • Journal of Inorganic Materials
    • Vol. 34, Issue 4, 349 (2019)
    Silicon-based Anode Materials Applied in High Specific Energy Lithium-ion Batteries: a Review
    Yi TAN1、2 and Kai WANG1、2
    Author Affiliations
  • 1School of Materials Science and Engineering, Dalian University of Technology, Dalian 116024, China
  • 2Key Laboratory for Solar Energy Photovoltaic System of Liaoning Province, Dalian 116024, China
    • show less
    DOI: 10.15541/jim20180347 Cite this Article
    Yi TAN, Kai WANG. Silicon-based Anode Materials Applied in High Specific Energy Lithium-ion Batteries: a Review[J]. Journal of Inorganic Materials, 2019, 34(4): 349 Copy Citation Text show less
    Performance comparison of common anode materials
    1. Performance comparison of common anode materials
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    Illustration of Si volume expansion during charge and discharge[9]
    2. Illustration of Si volume expansion during charge and discharge[9]
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    Schematic of the failure mechanism of silicon[13]
    3. Schematic of the failure mechanism of silicon[13]
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    The composite map of synthesis of CNT@mp-Si and meso-porous Si nanotube [20]
    4. The composite map of synthesis of CNT@mp-Si and meso-porous Si nanotube [20]
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    Schematic of the pomegranate-inspired design[25](a) Three dimensional view and (b) simplified two-dimensional cross-section view
    5. Schematic of the pomegranate-inspired design[25](a) Three dimensional view and (b) simplified two-dimensional cross-section view
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    (a) Schematic diagram of the novel core-shell Si@C@void@C, TEM images of (b) raw Si, (c) Si@SiO2@C, (d) Si@void@C, (e) Si@C, (f) Si@C@SiO2@C, and (g) Si@C@void@C[26]
    6. (a) Schematic diagram of the novel core-shell Si@C@void@C, TEM images of (b) raw Si, (c) Si@SiO2@C, (d) Si@void@C, (e) Si@C, (f) Si@C@SiO2@C, and (g) Si@C@void@C[26]
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    Scanning diagrams of (a) Ag-deposited on Si and (b, c) metal induced etching Si[28]
    7. Scanning diagrams of (a) Ag-deposited on Si and (b, c) metal induced etching Si[28]
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    Schematic illustration of the preparation process from Al-Si alloy to the Si/C composite[30]
    8. Schematic illustration of the preparation process from Al-Si alloy to the Si/C composite[30]
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    Schematic diagram of the basic electrochemical mechanism of SiOx-based materials[46]
    9. Schematic diagram of the basic electrochemical mechanism of SiOx-based materials[46]
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    Schematic diagram of short-circuit prelithiation treatment of metal foil circuit of batteries[50]
    10. Schematic diagram of short-circuit prelithiation treatment of metal foil circuit of batteries[50]
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    Schematic diagram of preparation of the SiOx/Si/C[54]
    11. Schematic diagram of preparation of the SiOx/Si/C[54]
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    SEM images of (a) initial SiO@C, surface ((b) secondary electron phase, (c) back scattered) and (d) cross-section of hollow SiO@void@C material[59]
    12. SEM images of (a) initial SiO@C, surface ((b) secondary electron phase, (c) back scattered) and (d) cross-section of hollow SiO@void@C material[59]
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    Performance comparisons of common Si-based anode materials[25, 30, 35-39, 47, 53-54, 59-62]
    13. Performance comparisons of common Si-based anode materials[25, 30, 35-39, 47, 53-54, 59-62]
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    Composite typeSi sourceCarbon sourceElectrochemical performanceMethodRef.
    Si/Porous-CNano-silicon powderPitch723.8 mAh/g (1st)600 mAh/g (100 mA/g, 100 )aSpray drying + High-temperature pyrolysis[35]
    Si@C@RGOSilicon powder (80 nm)Sucrose1599 mAh/g (1st)1517 mAh/g (100 mA/g, 100 )Spray drying + High-temperature pyrolysis[36]
    Si/C/GSilicon powder (325 mesh)Phenol-formaldehyde resin (PFR)700 mAh/g (1st)550 mAh/g (100 mA/g, 40 )High-temperature pyrolysis[37]
    Silicon-spongeSi wafer (>20 μm)Acetylene790 mAh/g (1st)726 mAh/g (100 mA/g, 300 )Electrochemical etching+ High-temperature pyrolysis[38]
    PS@CSi powder(5 μm)Propylene1980 mAh/g (1st)1287 mAh/g (100 mA/g, 100)Chemical etching + CVD[39]
    Si/CAl-Si alloy(2-10 μm)Polyacrylonitrile (PAN)952 mAh/g (1st)826.3 mAh/g (200 mA/g, 300)Chemical etching + High-temperature pyrolysis[30]
    Table 1. Electrochemical performance of some silicon/carbon composite anodes for lithium-ion batteries
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    Yi TAN, Kai WANG. Silicon-based Anode Materials Applied in High Specific Energy Lithium-ion Batteries: a Review[J]. Journal of Inorganic Materials, 2019, 34(4): 349
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