Twins and polytypic stacking faults in the ν phase formed in rapidly quenched Mn-Si alloys

•Twins and polytypic stacking faults form in the rapidly quenched ν phase.•Subunits of the ν phase reconstruct at twin boundaries and stacking faults.•An orthorombic structure forms across twin boundaries in the ν phase.•Monoclinic structures form across polytypic stacking faults in the ν phase. Mn-...

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Published in:Materials letters 2020-07, Vol.271, p.127746, Article 127746
Main Authors: Gao, C.T., Cheng, S.D., Mi, S.B., Qiang, J.B., Wang, Y.M.
Format: Article
Language:English
Subjects:
Atomic structure
Binary alloys
Crystallography
Defects
Electric arc melting
Electron microscopy
Interfaces
Intermetallic alloys and compounds
Materials science
Microstructure
Rapid quenching (metallurgy)
Scanning transmission electron microscopy
Silicon base alloys
Stacking faults
Structural models
Twin boundaries
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Mi, S.B.
Qiang, J.B.
Wang, Y.M.
description •Twins and polytypic stacking faults form in the rapidly quenched ν phase.•Subunits of the ν phase reconstruct at twin boundaries and stacking faults.•An orthorombic structure forms across twin boundaries in the ν phase.•Monoclinic structures form across polytypic stacking faults in the ν phase. Mn-rich Mn-Si binary alloys containing the ν phase have been prepared by arc-melting and rapid-quenching methods. In comparison, twins and polytypic stacking faults (SFs) are observed in the rapidly quenched ν phase, and the atomic-scale structure properties of twins and SFs have been determined by using aberration-corrected scanning transmission electron microscopy techniques. Both twins and SFs break the crystallographic symmetry of the ν phase, and lead to reconstruction of the subunits of the ν phase at twin boundaries and SFs. On the basis of experimental results, new structural models are proposed to explain the twin and SFs formation in the rapidly quenched ν phase.
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Mn-rich Mn-Si binary alloys containing the ν phase have been prepared by arc-melting and rapid-quenching methods. In comparison, twins and polytypic stacking faults (SFs) are observed in the rapidly quenched ν phase, and the atomic-scale structure properties of twins and SFs have been determined by using aberration-corrected scanning transmission electron microscopy techniques. Both twins and SFs break the crystallographic symmetry of the ν phase, and lead to reconstruction of the subunits of the ν phase at twin boundaries and SFs. 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Mn-rich Mn-Si binary alloys containing the ν phase have been prepared by arc-melting and rapid-quenching methods. In comparison, twins and polytypic stacking faults (SFs) are observed in the rapidly quenched ν phase, and the atomic-scale structure properties of twins and SFs have been determined by using aberration-corrected scanning transmission electron microscopy techniques. Both twins and SFs break the crystallographic symmetry of the ν phase, and lead to reconstruction of the subunits of the ν phase at twin boundaries and SFs. 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subjects Atomic structure
Binary alloys
Crystallography
Defects
Electric arc melting
Electron microscopy
Interfaces
Intermetallic alloys and compounds
Materials science
Microstructure
Rapid quenching (metallurgy)
Scanning transmission electron microscopy
Silicon base alloys
Stacking faults
Structural models
Twin boundaries
title Twins and polytypic stacking faults in the ν phase formed in rapidly quenched Mn-Si alloys
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