储能科学与技术 ›› 2023, Vol. 12 ›› Issue (4): 1045-1050.doi: 10.19799/j.cnki.2095-4239.2022.0718

• 储能材料与器件 • 上一篇    下一篇

原位固化对硅氧负极性能的影响

张文(), 李爽, 陈诚, 谌强   

  1. 天目湖先进储能技术研究院有限公司,江苏 常州 213300
  • 收稿日期:2022-12-02 修回日期:2022-12-21 出版日期:2023-04-05 发布日期:2023-05-08
  • 通讯作者: 张文 E-mail:zhangwen@aesit.com.cn
  • 作者简介:张文(1992—),男,硕士,工程师,研究方向为高比能负极体系开发,E-mail:zhangwen@aesit.com.cn

Effect of in situ solidification on the performance of silicon oxide anode

Wen ZHANG(), Shuang LI, Cheng CHEN, Qiang SHEN   

  1. Tianmu Lake Institute of Advanced Energy Storage Technologies, Changzhou 213300, Jiangsu, China
  • Received:2022-12-02 Revised:2022-12-21 Online:2023-04-05 Published:2023-05-08
  • Contact: Wen ZHANG E-mail:zhangwen@aesit.com.cn

摘要:

利用聚合物单体与引发剂在加热情况下能自发聚合的特点,在硅负极电解液中引入高离子电导率单体和引发剂,注液后采用热聚合的方式制备了原位固化的硅负极电芯。通过充放电设备测试了电芯的循环、倍率等性能,通过扫描电子显微镜(SEM)、X射线衍射光谱仪(XRD)、电化学工作站以及压汞仪等表征测试手段,对硅负极极片形貌和电化学性能进行表征。结果表明,固化后电芯常温0.5 C循环次数为349周,相比于液态电芯的230周,循环次数提升51.74%,同时固化后硅负极极片膨胀率相比液态电芯降低4.6%,极片孔隙率降低3.8%,且减少了循环后EIS和DCIR的增长,电芯性能明显优于液态电芯。从极片表征结果看出,固化可以改善硅负极极片界面,在硅负极表面和极片孔隙内形成一层聚合物电解质层,避免硅负极在嵌锂时膨胀粉化脱落,并稳定极片离子和电子导电网络。本研究有助于推动硅负极应用,为高能量密度电池技术的研发提供实验依据。

关键词: 原位聚合, 硅氧负极, 极片界面, 膨胀

Abstract:

In this study, high ionic conductivity monomers and initiators were introduced into the silicon anode electrode electrolyte by taking advantage of the spontaneous polymerization of polymer monomers and initiators under heating. The in situ solidified silicon anode electrode cell was prepared by thermal polymerization after liquid injection. The cycle and rate properties of the cell were tested using charging and discharging equipment. The morphology and electrochemical properties of the silicon anode electrode were characterized using scanning electron microscopy, X-ray diffraction spectrometer, and electrochemical workstation and mercury porosimeter. The results show that the number of cycles of the solidified cell at room temperature of 0.5 C is 349 cycles, which is 51.74% higher than that of the liquid cell at 230 cycles. The swelling rate of the silicon anode electrode after solidification is 4.6% lower than that of the liquid cell, and the porosity of the electrode is 3.8% lower than that of the liquid cell. The EIS and DCIR growths after cycling are reduced, and the performance of the cell is significantly better than that of the liquid core. The electrode sheet characterization results show that solidification can improve the interface of the silicon anode electrode plate, form a layer of polymer electrolyte on the surface of the silicon anode electrode and in the hole of the electrode plate, prevent the silicon anode electrode plate from swelling, powdering and falling off when lithium is embedded, and stabilize the ion and electronic conductive network of the electrode plate. This research promotes the application of silicon anodes and provide an experimental basis for the research and development of battery technology involving high energy density.

Key words: in-situ solidification, silicon oxide anode, electrode interface, swelling

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