Study of the Composition of Impurities in High-Purity Monosilane Obtained from Magnesium Silicide Using the Method of Chromatography–Mass Spectrometry

Study of the Composition of Impurities in High-Purity Monosilane Obtained from Magnesium Silicide Using the Method of Chromatography–Mass Spectrometry

The method of chromatography–mass spectrometry is used to study the impurity composition in monosilane obtained in the reaction of magnesium silicide with ammonium chloride in liquid ammonia. To improve the reliability of the impurity identification, along with the study of pure monosilane samples,...

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Bibliographic Details
Published in:Inorganic materials Vol. 55; no. 14; pp. 1371 - 1376
Main Authors: Sozin, A. Yu, Kotkov, A. P., Grishnova, N. D., Anoshin, O. S., Skosyrev, A. I., Arhiptsev, D. F., Chernova, O. Yu, Sorochkina, T. G.
Format: Journal Article
Language:English
Published: Moscow Pleiades Publishing 01-12-2019
Springer Nature B.V
Subjects:
Ammonia
Ammonium chloride
Carbon dioxide
Chemistry
Chemistry and Materials Science
Chromatography
Composition
Homology
Hydrides
Hydrocarbons
Impurities
Industrial Chemistry/Chemical Engineering
Inorganic Chemistry
Intermetallic compounds
Ionization cross sections
Ions
Liquid ammonia
Low temperature
Magnesium
Mass spectra
Mass spectrometry
Mass spectroscopy
Materials Science
Mathematical analysis
Scientific imaging
Signal to noise ratio
Silanes
Silica gel
Silicides
Silicon dioxide
Siloxanes
Sorbents
Substances Analysis
chromatography–mass spectrometry
high-purity monosilane
capillary column
impurity identification
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Summary:The method of chromatography–mass spectrometry is used to study the impurity composition in monosilane obtained in the reaction of magnesium silicide with ammonium chloride in liquid ammonia. To improve the reliability of the impurity identification, along with the study of pure monosilane samples, we analyzed monosilane fractions isolated upon purification by low temperature rectification. To separate the impurities of permanent gases, hydrocarbons C 1 –C 3 , volatile inorganic hydrides, disilane, and alkylsilanes, we used an adsorption capillary column GS-GasPro 60 m × 0.32 mm with a modified silica gel. To separate the homologs of monosilane, siloxanes, and alkylsilanes, we used a column 25 m × 0.26 mm, d f = 0.25 μm with a polytrimethylsilylpropyne (PTMSP) sorbent. The impurities were identified by comparison of their experimental mass spectra with the NIST database. In the absence of the mass spectra of analytes in the NIST electronic database or in the case of their low coincidence with the database spectra, the identification was performed using mass spectra and retention times published in the literature. The impurities of permanent gases, carbon dioxide, hydrocarbons C 1 –C 3 , volatile inorganic hydrides, monosilane homologies, siloxanes, and alkyl silanes were identified in monosilane. Quantitative determination of the impurities was carried out in the mode of selective ion detection using the mass numbers for which the signal-to-noise ratio was maximal. Their concentrations were calculated using a method of absolute calibration by the peak areas; in the case where reference samples were absent, the concentrations were determined using the dependence of the sensitivity coefficients of their detection on the magnitude of the total ionization cross sections. The detection limits of the impurities range within 1 × 10 –5 –2 × 10 –7 mol %. The accuracy of the analysis was verified by the method of sample size variation. The results of determination of the impurities in monosilane after synthesis, as well as in monosilane purified by low temperature rectification and in the isolated fractions with concentrated higher and lower boiling impurities, are reported.
ISSN:0020-1685
1608-3172
DOI:10.1134/S0020168519140139