Abstract
Novel technical solutions and ideas for increasing the yield of solar and semiconductor grade polycrystalline silicon processes have been analyzed. The predominant polycrystalline silicon technology is currently still the Siemens process including the conversion of technical grade silicon (synthesized by carbon-thermal reduction of quartzites) to trichlorosilane followed by rectification and hydrogen reduction. The cost of product silicon can be cut down by reducing the trichlorosilane synthesis costs through process and equipment improvement. Advantages, drawbacks and production cost reduction methods have been considered with respect to four common trichlorosilane synthesis processes: hydrogen chloride exposure of technical grade silicon (direct chlorination, DC), homogeneous hydration of tetrachlorosilane (conversion), tetrachlorosilane and hydrogen exposure of silicon (hydro chlorination silicon, HC), and catalyzed tetrachlorosilane and dichlorosilane reaction (redistribution of anti-disproportioning reaction). These processes remain in use and are permanently improved. Catalytic processes play an important role on silicon surface, and understanding their mechanisms can help find novel applications and obtain new results. It has been noted that indispensable components of various equipment and process designs are recycling steps and combined processes including active distillation. They provide for the most complete utilization of raw trichlorosilane, increase the process yield and cut down silicon cost.
Highlights
The world’s total electric power consumption reached ~229 bn. kWh in 2020 and is predicted to show a further 1.4 times growth by 2050 [1]
Along with conventional energy sources, solar energy conversion is in growing demand
Analysts predict [2] that solar energy consumption will be able to compete with gas generation power consumption by 2025, whereas solar energy consumption growth rate is already ahead of that of the nuclear power
Summary
Trichlorosilane is the key raw material for silicon production both in the Siemens process and in the silane process It is currently synthesized by hydrogen chloride exposure of technical grade silicon, homogeneous hydration of trichlorosilane, tetrachlorosilane and hydrogen exposure of silicon, sometimes with hydrogen chloride addition, and catalyzed tetrachlorosilane and dichlorosilane reaction. The former of the above methods is the best known and most widely used one and is referred to in scientific and patent literature as direct synthesis or silicon hydrochlorination, most recently it has been suggested to use the term “direct chlorination” [18, 19].
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