高等学校化学学报

高等学校化学学报

• 研究论文 • 上一篇    下一篇

三维多孔结构及与铟合金化协同提升 锑电极储钠性能

孙雨涵,敬茂森,赵宝雁,鲍晓冰,罗巧梅,苟蕾,樊小勇   

  1. 长安大学材料科学与工程学院
  • 收稿日期:2025-02-04 修回日期:2025-04-15 网络首发:2025-04-15 发布日期:2025-04-15
  • 通讯作者: 樊小勇 E-mail:xyfan@chd.edu.cn
  • 基金资助:
    国家自然基金面上项目(No.22179011)、西藏自治区重点研发项目(XZ202401ZY0104)和陕西省国资委项目(ZXZJ-2024-018)

Three-dimensional Porous Structure and alloying with Indium synergistically Enhance the Sodium Storage Performance of Antimony Electrodes

SUN Yuhan, JING Maoseng, ZHAO Baoyan, BAO Xiaobing, LUO Qiaomei, GOU Lei, FAN Xiaoyong   

  1. School of Materials Science and Engineering, Chang’ an University
  • Received:2025-02-04 Revised:2025-04-15 Online First:2025-04-15 Published:2025-04-15
  • Contact: FAN Xiaoyong E-mail:xyfan@chd.edu.cn
  • Supported by:
    Supported by the National Natural Science Foundation of China(22179011), the Key Research and Development Projects in Tibet Autonomous Region, China(XZ202401ZY0104) and the Project of Shaanxi State-owned Assets Supervision and Administration Commission, China(ZXZJ-2024-018)

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摘要: 锑因其高达660 mAh g?1的理论储钠容量, 被认为是钠离子电池的理想负极材料之一, 然而其在充放电循环过程中发生巨大的体积变化, 导致活性材料粉化脱落, 限制了其实际应用. 为解决这一问题, 本研究采用简单的电沉积方法, 在具有微米级孔的三维多孔铜集流体内构筑了InSb合金. 引入的In元素能够有效抑制Sb电极的团聚现象, 同时减少了副反应的发生, 提升首次库仑效率; 三维多孔结构提供较大的比表面积和丰富的活性位点, 不仅有助于增加储钠容量、提高离子扩散速率, 还能为体积膨胀提供缓冲空间, 进而增强材料的结构稳定性. 在In合金元素和三维多孔结构协同作用下, 3D Cu@InSb展现出较高的首次库伦效率(80.7 %)、良好循环稳定性(在10 A g-1的电流密度下循环400圈容量保持率为97.6 %)和倍率性能(在20 A g?1电流密度下比容量为225.4 mAh g?1).

关键词: 钠离子电池, 负极, InSb合金, 三维多孔铜, 电沉积

Abstract: Antimony (Sb) is considered as an ideal anode for sodium-ion batteries due to its high theoretical sodium storage capacity of 660 mAh g?1. However, its commercial application is impeded by significant volume changes during charge-discharge cycling, which lead to the pulverization and shedding of the active materials. To address these issues, this study employs a simple electro-deposition method to fabricate an InSb alloy on a three-dimensional porous copper current collector with micrometer-sized pores. The introduced indium (In) element effectively suppresses the aggregation of Sb electrodes, the occurrence of irreversible reactions, and thus enhances the initial Coulombic efficiency. Meanwhile, the three-dimensional porous structure provides a large specific surface area and abundant active sites, which not only increase the sodium storage capacity and ion diffusion rate but also offer buffer enough space for volume expansion, thereby enhancing the structural stability of the material. Under the synergistic effect of the In element and the three-dimensional porous structure, the 3D Cu@InSb electrode exhibits a high initial Coulombic efficiency of 80.7 %, good cycling stability (a capacity retention rate of 97.6 % after 400 cycles at a current density of 10 A g?1), and excellent rate performance (a specific capacity of 225.4 mAh g?1 at a high current density of 20 A g?1).

Key words: Sodium-ion battery, Anode, InSb alloy, Three-dimensional porous copper, Electrodeposition

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