Behavior of Silicon Electrodepositing in Fluoride Molten Salts

"The behavior of electrochemically depositing silicon in a molten high-melting-point fluoride electrolyte was studied at 1300 °C. The cathodic product was characterized by XRD, SEM and EDS. Though the analysis of structure and composition of deposition, it could certify that silicon deposited on the Mo rod and alloyed with molybdenum. A series of tests had been performed on the cathodic behavior of Si4+ ions in BaF 2-CaF 2-Na2S iF 6 molten salt. The influence of electrochemical parameters on the cathodic deposition of silicon was also investigated. The electrochemical behavior of Si4+ ions in applied fluoride melts was observed to proceed according to one-step reaction.IntroductionGreenhouse warming has been a serious global issue. lt is increasingly urgent for clean and renewable energy. Effective utilization of clean and inexhaustible solar energy has become very important. Solar cell (especially poly-Si solar cell) production has significantly increased this decade, as there is a growing demand for clean energy. Since the early 1980s, the annual growth of the photovoltaic (PY) solar cell industry is more than 30%. More than 90% of the annual solar cell production is based on crystalline silicon wafers. This rapid growth leads to a shortage of silicon of the adequate quality and price for the continued growth of this industry [I , 2J. The most conunonly used technology to produce silicon is the so-called Siemens process. This technology, involves the forming of gaseous Si compounds such as trichlorosilane (SiHCli) or silane (SiH4) with subsequent thermal decomposition of these back to Si. This technology is associated with transformations from solid to gas, and then back to solid phase, which lead to high irreversible thermodynamic losses and subsequent high energy consumption, the energy cost being around 200kWh/kg Si [3l_ The purity of the material from this process is very high (9 to 11 N). In general, what is needed for solar cell purposes are reported to require 4 to 6 N quality. To promote continued growth of the silicon-based PY industry, there is need for a low-energy silicon production process which can produce large amounts of silicon with an acceptable quality and a lower price particularly."