Effect of Zr additions on microstructure evolution and phase formation of Nb−Si based ultrahigh temperature alloys

In the present work, the role of Zr addition on the microstructure and phase formation of hypoeutectic Nb−16 at. % Si alloy has been investigated. The results showed that both binary and alloy with 2 at. % Zr resulted in two phase microstructures composed of Nbss and Nb3Si phases. In contrast, the a...

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Published in:Intermetallics 2018-10, Vol.101, p.123-132
Main Authors: Sankar, M., Phanikumar, G., Singh, Vajinder, Satya Prasad, V.V.
Format: Article
Language:English
Subjects:
Aero–engine components
Alloys
Binary alloys
Electron backscatter diffraction
Heat resistant alloys
Heat treating
Heat treatment
Lamellar structure
Microstructure
Niobium base alloys
Phases
Silicides
Solidification
Ultrahigh temperature
Zirconium
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container_title Intermetallics
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creator Sankar, M.
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Satya Prasad, V.V.
description In the present work, the role of Zr addition on the microstructure and phase formation of hypoeutectic Nb−16 at. % Si alloy has been investigated. The results showed that both binary and alloy with 2 at. % Zr resulted in two phase microstructures composed of Nbss and Nb3Si phases. In contrast, the alloys with 4 at. % Zr and 6 at. % Zr revealed two phase microstructures composed of Nbss and α−Nb5Si3 phases. The orientation relationship (OR) obtained between eutectoid lamellar structure comprising of Nbss and α−Nb5Si3 phases is (110) Nb//(110) Nb5Si3. The equilibrium microstructures consisting of Nb and α−Nb5Si3 phases were obtained in as cast condition when the Zr concentration is above 2 at.%. The addition of Zr accelerated the dissociation kinetics of Nb3Si phase in to Nbss and α−Nb5Si3 phases during solidification. The formation of α−Nb5Si3 phase in the as cast condition eliminates heat treatment required for decomposition of Nb3Si phase in Nb-Si alloys. •Binary alloy and alloy with 2 at.%Zr alloys exhibit two phase microstructures composed of Nbss and Nb3Si phases.•Nbss and α−Nb5Si3 phases are obtained in the as cast condition when Zr concentration exceed 2 at. %.•The addition of Zr accelerates the dissociation kinetics of Nb3Si phase.•Zr is predominantly partitioned in Nb5Si3 phase.
doi_str_mv 10.1016/j.intermet.2018.07.010
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subjects Aero–engine components
Alloys
Binary alloys
Electron backscatter diffraction
Heat resistant alloys
Heat treating
Heat treatment
Lamellar structure
Microstructure
Niobium base alloys
Phases
Silicides
Solidification
Ultrahigh temperature
Zirconium
title Effect of Zr additions on microstructure evolution and phase formation of Nb−Si based ultrahigh temperature alloys
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