Recycling high purity silicon from solar grade silicon cutting slurry waste by carbothermic reduction in the electric arc furnace

Abstract

The complete separation of ultrafine silicon particles and silicon carbide (SiC) particles is very difficult, which is a great dilemma for recycling high purity kerf loss silicon (Sik) from solar grade silicon cutting slurry waste (SoG-Siw). Here, we report a novel carbothermic reduction process for obtaining high purity silicon from SoG-Siw. SoG-Siw was firstly purified by acid leaching, then cleaned with high purity water and pelleted with high purity silica sand. After refining in an electric arc furnace (50 kW), Sik and SiC particles were completely separated. The obtained silicon had the purity of 99.15 wt% and lower concentration of boron (B, 0.06 ppmw) and phosphorus (P, 0.24 ppmw), which had met the standard of B and P for solar cells. The overall yield of recycling silicon was 63%. The influence of iron, particle size of high purity silica sand and SiO2:SiC ratio on the silicon recycling are investigated. In addition, the mechanism for the separation of Sik and SiC particles by the metallurgical process is analyzed. The reacted reactants with different states inside the crucibles are observed and the reaction process is analyzed. This metallurgical process overcomes the technical bottlenecks for the complete separation of Sik and SiC from SoG-Siw. Specially, this process can be scaled up for commercial production.