1. A Commercial Carbonaceous Anode with a-Si Layers by Plasma Enhanced Chemical Vapor Deposition for Lithium Ion Batteries
- Author
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Ing Song Yu, Chao Yu Lee, and Fa Hsing Yeh
- Subjects
Battery (electricity) ,anode ,Materials science ,chemistry.chemical_element ,02 engineering and technology ,010402 general chemistry ,Electrochemistry ,lcsh:Technology ,01 natural sciences ,silicon-carbon composites ,Lithium-ion battery ,Plasma-enhanced chemical vapor deposition ,lcsh:Science ,Engineering (miscellaneous) ,lcsh:T ,plasma enhanced chemical vapor deposition ,021001 nanoscience & nanotechnology ,0104 chemical sciences ,Anode ,chemistry ,Chemical engineering ,Electrode ,Ceramics and Composites ,lithium ion battery ,lcsh:Q ,Lithium ,0210 nano-technology ,Faraday efficiency - Abstract
In this study, we propose a mass production-able and low-cost method to fabricate the anodes of Li-ion battery. Carbonaceous anodes, integrated with thin amorphous silicon layers by plasma enhanced chemical vapor deposition, can improve the performance of specific capacity and coulombic efficiency for Li-ion battery. Three different thicknesses of a-Si layers (320, 640, and 960 nm), less than 0.1 wt% of anode electrode, were deposited on carbonaceous electrodes at low temperature 200 °C. Around 30 mg of a-Si by plasma enhanced chemical vapor deposition (PECVD) can improve the specific capacity ~42%, and keep coulombic efficiency of the half Li-ion cells higher than 85% after first cycle charge-discharge test. For the thirty cyclic performance and rate capability, capacitance retention can maintain above 96%. The thicker a-Si layers on carbon anodes, the better electrochemical performance of anodes with silicon-carbon composites we get. The traditional carbonaceous electrodes can be deposited a-Si layers easily by plasma enhanced chemical vapor deposition, which is a method with high potential for industrialization.
- Published
- 2020
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