1. Effective carbon constraint of MnS nanoparticles as high-performance anode of lithium-ion batteries.
- Author
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Paredes Camacho, Ramon A., Wu, Ai-Min, Jin, Xiao-Zhe, Dong, Xu-Feng, Li, Xiao-Na, and Huang, Hao
- Subjects
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LITHIUM-ion batteries , *CHEMICAL stability , *ENERGY storage , *ARCHITECTURAL design , *CARBON - Abstract
Despite possessing a high theoretical capacity, MnS has a rather complex lithium kinetic diffusion and poor mechanical stability that hinders its application in energy storage devices like lithium-ion batteries. This study is focused on overcoming the drawbacks of MnS anode material by assembling a carbon-constraint MnS nanocomposite in a core-shell configuration. This structure is obtained by a simple route involving DC plasma evaporation of Mn@C nanoparticles and posterior thermal sulfurization process. As anode material in a Li-ion battery, MnS@C-300 attains high specific capacity of 890 mAh g−1 after 500 cycles at 500 mA g−1. It also shows remarkable high rate capability with capacity values of 705, 684, 643, 578, and 495 mAh g−1 at current densities of 100, 200, 500, 1000, and 2000 mA g−1, respectively. This exceptional electrochemical response is endorsed to the synergetic effect of the smart design of a core-shell architecture. The carbonaceous shell enhances the lithium-ion diffusion towards the active MnS core and preserves structural stability during the long cycling process. Image 1 • Simple plasma evaporation and sulfuration are used to produce MnS@C nanocomposites. • Carbon constraint avoids the sintering of MnS nanoparticles during synthesis. • Core-shell structure provides outstanding stability and lithium storage properties. • High capacitive contribution generates excellent high-rate capability results. [ABSTRACT FROM AUTHOR]
- Published
- 2019
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