Unveiling the Effect of Surface and Bulk Structure on Electrochemical Properties of Disproportionated SiO<sub>x</sub> Anodes
Zuxin Long, Rusheng Fu, Jingjing Ji, Zuyong Feng, Zhaoping Liu
Abstract
Abstract As a promising lithium‐ion battery anode materials, silicon suboxides (SiO x ) exhibit elusive microstructure with atomic‐scale disproportionation which reveals a strong relation to performance. Generally, the structure of SiO x could be tuned via high‐temperature treatment. In this work, disproportionated SiO x are prepared to systematically discuss the internal relationship among microstructure, physicochemical properties and electrochemical performance. After annealing, amorphous SiO 2 and nanocrystalline Si appear, and the SiO 2 accumulating on the surface results in large resistance and low Li‐ion diffusivity, which leads to large overpotential and poor performance. If mechanical milling is employed followed by annealing, the SiO 2 layer can be crushed, SiO x and Si with electrochemical activity are uncovered. Further research on the SiO x with diverse degrees of disproportionation indicates that proper amount of Si and SiO 2 determines the optimal electrochemical performance. This result gives an in‐depth understanding and probable guidance to the modification investigation of SiO x anode for Li‐ion batteries.