A Review of Design Strategies in SiO/C Composite Anodes for Rechargeable Lithium‐Ion Batteries

Abstract

Lithium‐ion batteries (LIBs) are widely used in electric vehicles, portable electronic devices, clean energy storage, and other fields due to their long service life, high energy density, and low self‐discharge rate, which also puts forward higher requirements for the performance of lithium‐ion batteries. As an anode for lithium‐ion batteries, SiO materials have garnered significant attention from researchers due to its high specific capacity (2400 mAh·g‐1), abundance of raw materials, and simple preparation. However, its large volume change (~ 200%) and poor electrical conductivity hinder its large‐scale commercial application. Researchers employ various methods to reduce the volume change of SiO during lithium intercalation and improve its structural stability during cycling. This work mainly reviews the chemical structure and lithium storage mechanism of SiO, as well as the latest research progress on the preparation methods of SiO/C anode materials, focusing on summarizing the following preparation strategies: chemical vapor deposition, mechanical ball milling, spray drying, and in‐situ reduction/oxidation methods. The obtained SiO‐based anode materials' structural characteristics and electrochemical properties are compared and summarized. Finally, this review discusses the advantages and disadvantages of the current preparation methods, the future research directions, and the development prospects of SiO‐based anode materials.