Recycling Silicon Waste from the Photovoltaic Industry to Prepare Yolk–Shell Si@void@C Anode Materials for Lithium–Ion Batteries

Abstract: Silicon is considered to have significant potential for anode materials in lithium–ion batteries (LIBs) with a theoretical specific capacity of 4200 mAh g−1. However, the development of commercial applications is impacted by the volume shift that happens in silicon when charging and discharging. In this paper, a yolk–shell–structured Si@void@C anode material has been developed to address this problem. The silicon nanoparticle yolk material is obtained by recycling kerf loss (KL) Si waste from the process of sl… Show more

“…The CV curves of the pSi/Ag and pSi/Ag@C electrode for the first three cycles are shown in Figure 8a,b, respectively. During the first cathodic scan, a wide cathodic peak appears at 0.79 V in pSi/Ag and 0.61 V in pSi/Ag@C, which is related to the generation of the SEI layer [44]. The reduction peak for both electrodes appears at approximately 0.2 V, which can be attributed to the transformation from the crystalline silicon to the amorphous LixSi alloy in the first cathodic scan.…”

High-Performance Porous pSi/Ag@C Anode for Lithium-Ion Batteries

“…The CV curves of the pSi/Ag and pSi/Ag@C electrode for the first three cycles are shown in Figure 8a,b, respectively. During the first cathodic scan, a wide cathodic peak appears at 0.79 V in pSi/Ag and 0.61 V in pSi/Ag@C, which is related to the generation of the SEI layer [44]. The reduction peak for both electrodes appears at approximately 0.2 V, which can be attributed to the transformation from the crystalline silicon to the amorphous LixSi alloy in the first cathodic scan.…”

High-Performance Porous pSi/Ag@C Anode for Lithium-Ion Batteries

Cost-effective preparation of high-performance Si@C anode for lithium-ion batteries

A low-cost Si@C composite for lithium-ion batteries anode materials synthesized via freeze-drying process using kerf loss Si waste