Preparation of Fine-grained Silicon from Serpentine Mineral by Magnesiothermic Reduction of Silica in the Presence of Reaction Products as Diluents

In the work, the preparation of fine-grained silicon was performed in combustion mode by magnesiothermic reduction of silica, obtained from serpentine mineral, which is characterized by a high specific surface area (about 560 m 2 /g) and high reaction activity. It is manifested by the fact that the...

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Bibliographic Details
Published in:SILICON 2017-11, Vol.9 (6), p.841-846
Main Authors: Zakaryan, M. K., Aydinyan, S. V., Kharatyan, S. L.
Format: Article
Language:English
Subjects:
Aluminum
Chemistry
Chemistry and Materials Science
Combustion products
Combustion temperature
Electrons
Environmental Chemistry
Inorganic Chemistry
Lasers
Magnesium
Materials Science
Optical Devices
Optics
Original Paper
Particle size
Photonics
Polymer Sciences
Propagation velocity
Reaction products
Reagents
Reduction
Serpentine
Silicon dioxide
Silicon wafers
Temperature
Thermocouples
Wave propagation
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Summary:In the work, the preparation of fine-grained silicon was performed in combustion mode by magnesiothermic reduction of silica, obtained from serpentine mineral, which is characterized by a high specific surface area (about 560 m 2 /g) and high reaction activity. It is manifested by the fact that the measured combustion temperature exceeded the adiabatic combustion temperature calculated with the ISMAN THERMO software, by about 200 °C. In order to mitigate the synthesis conditions, combustion products (Si+2MgO) were used as diluting agents allowing a significant decrease of combustion temperature and a finer silicon powder without contaminating the target product with incidental reagents and without decreasing the yield of the target product. Based on the measured values of combustion parameters (combustion temperature and combustion wave propagation velocity) vs diluent amount, it was estimated that the effective activation energy for SiO 2 +2Mg reaction by the solid+liquid mechanism in the temperature interval 1400–2100 °C was about 65±3 kJ/mol.
ISSN:1876-990X
1876-9918
DOI:10.1007/s12633-017-9583-4