Enhanced electrochemical performance and decreased strain of graphite anode by Li2SiO3 and Li2CO3 co-modifying
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- 作者:Yao Xiaoa ; Guixin Wanga ; guixin66@scu.edu.cn ; guixinwang1@gmail.com ; Shuo Zhoua ; Yuhan Suna ; Qiang Zhaoa ; Yichao Gongb ; Tiecheng Lub ; Chunhui Luoa ; Kangping Yana
- 关键词:Graphite ; Lithium silicate ; Co-modification ; Electrochemical performance ; Stress strain analysis
- 刊名:Electrochimica Acta
- 出版年:2017
- 出版时间:1 January 2017
- 年:2017
- 卷:223
- 期:Complete
- 页码:8-20
- 全文大小:3692 K
- 卷排序:223
文摘
In order to improve the electrochemical performance and decrease the volume changes of artificial graphite, Li2SiO3 and Li2CO3 have been in situ prepared to co-modify the graphite by ball milling and heating the precursors of Li4SiO4 and graphite. The as-obtained graphite-based samples were characterized using various techniques, and the effects of Li4SiO4 content were investigated. The results show that the co-modified graphite with 20 wt.% Li4SiO4 exhibits the highest reversible capacity and the best cycling performance among the graphite-based samples. Compared to the pristine graphite, the initial reversible capacities of the co-modified graphite with 20 wt.% Li4SiO4 respectively increase 10.1%, 16.4%, 28.9%, and 62.4% at the current rates of 0.1, 1.0, 2.0 and 5.0C, while the capacity fade ratios respectively decrease 3.8%, 10.0%, and 23.2% at the current rates of 1.0, 2.0 and 5.0C after 50 cycles. Furthermore, co-modification by Li2SiO3 and Li2CO3 decreases the polarization degree as well as the charge transfer reaction and diffusion resistances of pure graphite. Non-destructive stress-strain tests were adopted to real time monitor the macroscopic stress safety properties of the cells, and the results indicate that the combination of Li2SiO3 and Li2CO3 relieves the swelling of the graphite electrode during cycles, and the stress value of the cell surface decreases 34.4% after 50 cycles at the current rate of 1.0C. The relationship between residue stress and capacity fade along with possible reaction mechanisms is discussed. The good results pave a novel facile way to enhance the performance of current energy materials using combined lithium salts via in situ reaction.