Facile Synthesis of Sponge-Like Porous Nano Carbon-Coated Silicon Anode with Tunable Pore Structure for High-Stability Lithium-Ion Batteries

• Published in: Molecules (Basel, Switzerland) Vol. 26; no. 11; p. 3211
• Main Authors: Song, Shugui, Li, Jingcang, Zheng, Anqi, Yang, Yongqiang, Yin, Kuibo
• Format: Journal Article
• Language: English
• Published: Basel MDPI AG 27.05.2021; MDPI
• Subjects: Adsorption; Anode effect; Anodes; Anodic coatings; Batteries; Carbon; carbon-coated silicon; Chemical bonds; Coatings; Conductivity; Cycles; Electrochemistry; Heating rate; Interface stability; Lithium; Lithium-ion batteries; lithium-ion battery; Material properties; mechanical simulation; Methods; Nanoparticles; Oxidation; porous structure; Pressure effects; Silicon; Spectrum analysis; Structural stability
• ISSN: 1420-3049; 1420-3049
• DOI: 10.3390/molecules26113211

To address the challenge of the huge volume expansion of silicon anode, carbon-coated silicon has been developed as an effective design strategy due to the improved conductivity and stable electrochemical interface. However, although carbon-coated silicon anodes exhibit improved cycling stability, the complex synthesis methods and uncontrollable structure adjustment still make the carbon-coated silicon anodes hard to popularize in practical application. Herein, we propose a facile method to fabricate sponge-like porous nano carbon-coated silicon (sCCSi) with a tunable pore structure. Through the strategy of adding water into precursor solution combined with a slow heating rate of pre-oxidation, a sponge-like porous structure can be formed. Furthermore, the porous structure can be controlled through stirring temperature and oscillation methods. Owing to the inherent material properties and the sponge-like porous structure, sCCSi shows high conductivity, high specific surface area, and stable chemical bonding. As a result, the sCCSi with normal and excessive silicon-to-carbon ratios all exhibit excellent cycling stability, with 70.6% and 70.2% capacity retentions after 300 cycles at 500 mA g−1, respectively. Furthermore, the enhanced buffering effect on pressure between silicon nanoparticles and carbon material due to the sponge-like porous structure in sCCSi is further revealed through mechanical simulation. Considering the facile synthesis method, flexible regulation of porous structure, and high cycling stability, the design of the sCCSi paves a way for the synthesis of high-stability carbon-coated silicon anodes.