<p>Silicon anodes have intrinsically low electronic conductivity and severe volume changes, leading to nonuniform reaction kinetics and progressive structural degradation in both lithium-ion batteries (LIBs) and all-solid-state lithium batteries (ASSLBs). To overcome these limitations, we develop a silicon nanocomposite anode via a scalable and facile synthesis route. The nanocomposite (Si/a-Sn/CoSi<sub>2</sub>/G/C) consists of ultrafine Si nanocrystallites integrated with a well-deformable, electronically conductive amorphous Sn; a mechanically robust and elastic CoSi<sub>2</sub> framework; a highly Li-reversible, electronically conductive, stress-mitigating graphite scaffold; and a highly elastic, electronically conductive PVC-pyrolyzed amorphous carbon shell. This hierarchical and synergistic architecture integrates uniform nanocrystalline Si dispersion, continuous electronic conduction, and mechanically rigid and elastically buffering matrices that accommodate volume expansion, thereby establishing a robust Si nanocomposite anode platform compatible with both LIBs and ASSLBs. The anode has a high reversible capacity, stable long-term cycling performance, high Coulombic efficiency, and improved rate capability. In LIB systems, a Si/a-Sn/CoSi<sub>2</sub>/G/C|NCM811 full-cell achieves an energy density of 434.4 Wh kg<sup>–1</sup> with durable cycling stability. In sulfide-based ASSLB systems employing Li<sub>6</sub>PS<sub>5</sub>Cl, the full-cell has an energy density exceeding 300 Wh kg<sup>–1</sup>, with structural and electrochemical stability. Thus, Si/a-Sn/CoSi<sub>2</sub>/G/C is a practical and scalable Si-based anode platform for next-generation LIBs and ASSLBs.</p>

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Multifunctional Conductive and Elastic Matrices-Engineered Si Nanocomposite Anodes for Liquid and Solid-State Lithium Batteries

  • Young-Han Lee,
  • Je-Hyeon Han,
  • Deok-Gyu Kim,
  • Jung-Woon Yoo,
  • Yoon-Cheol Ha,
  • Jae-Hun Kim,
  • Cheol-Min Park

摘要

Silicon anodes have intrinsically low electronic conductivity and severe volume changes, leading to nonuniform reaction kinetics and progressive structural degradation in both lithium-ion batteries (LIBs) and all-solid-state lithium batteries (ASSLBs). To overcome these limitations, we develop a silicon nanocomposite anode via a scalable and facile synthesis route. The nanocomposite (Si/a-Sn/CoSi2/G/C) consists of ultrafine Si nanocrystallites integrated with a well-deformable, electronically conductive amorphous Sn; a mechanically robust and elastic CoSi2 framework; a highly Li-reversible, electronically conductive, stress-mitigating graphite scaffold; and a highly elastic, electronically conductive PVC-pyrolyzed amorphous carbon shell. This hierarchical and synergistic architecture integrates uniform nanocrystalline Si dispersion, continuous electronic conduction, and mechanically rigid and elastically buffering matrices that accommodate volume expansion, thereby establishing a robust Si nanocomposite anode platform compatible with both LIBs and ASSLBs. The anode has a high reversible capacity, stable long-term cycling performance, high Coulombic efficiency, and improved rate capability. In LIB systems, a Si/a-Sn/CoSi2/G/C|NCM811 full-cell achieves an energy density of 434.4 Wh kg–1 with durable cycling stability. In sulfide-based ASSLB systems employing Li6PS5Cl, the full-cell has an energy density exceeding 300 Wh kg–1, with structural and electrochemical stability. Thus, Si/a-Sn/CoSi2/G/C is a practical and scalable Si-based anode platform for next-generation LIBs and ASSLBs.