Abstract
The phase composition, microstructure, and interphase interfaces of the disordered CrSi2–FeSi2 solid solution obtained by spontaneous crystallization (before and after annealing) have been investigated by scanning, transmission electron microscopy, electron diffraction, and X-ray energy dispersive spectrometry. The as-grown samples contained the phases of CrSi2 with the P6422 hexagonal structure and FeSi2 with the P4/mmm tetragonal structure. Annealing of the samples led to the phase transformation of tetragonal FeSi2 into the orthorhombic modification Cmca. Precipitates of cubic iron monosilicide FeSi with space group P213, nano-precipitates of Si and silicon silicide Cr5Si3 with a tetragonal structure I4/mcm were observed inside the FeSi2 grains. Impurities of interstitial Cr atoms with a concentration up to 2.0 at % are found in iron (di)silicides grains in all samples. The structure of the CrSi2 phase remains unchanged after annealing; the concentration of impurity iron atoms is about 0.7 at %. Orientation relationships between the crystal lattices of the phases are established and strains due to the mismatch of the crystal lattices are determined.
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The work was supported by the Ministry of Science and Higher Education of the Russian Federation.
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Suvorova, E.I., Solomkin, F.Y., Arkharova, N.A. et al. Microstructure and Phase Composition of an Alloy of Iron and Chrome Disilicides. Semiconductors 57, 143–147 (2023). https://doi.org/10.1134/S106378262303017X
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DOI: https://doi.org/10.1134/S106378262303017X