SiC–Sb–C nanocomposites as high-capacity and cycling-stable anode for sodium-ion batteries

Abstract

SiC–Sb–C nanocomposites with core–shell structure were prepared by simple mechanical ball-milling method. This core–shell structure is composed of rigid SiC nanoparticles as inner core, Sb nanoparticles as an electrochemical active layer anchored on the surface of SiC, and carbon outlayer. The electrochemical experiments show that the SiC–Sb–C electrode improve electrochemical utilization and cycling stability of Sb during Na-storage reaction in comparison with Sb–C composites, indicating that such core–shell structure can effectively buffer the volume change and remain structural stability. Particularly, after incorporating Cu into Sb layer, the SiC–Sb–Cu–C electrode exhibits higher capacity and cycling stability (595mAhg−1 after 100 cycles) than the SiC–Sb–C electrode. Therefore, the core–shell structure can provide a viable strategy to develop high capacity and stable cycling alloy anode for sodium ion batteries.