Microstructural transitions of metastable phase in undercooled Fe-7.5 at% Ni alloy

Y. Z. Chen; G. C. Yang; F. Liu; H. Xie; Y. P. Su; N. Liu; C. L. Yang; Y. H. Zhou

doi:10.1016/j.jcrysgro.2005.10.128

Microstructural transitions of metastable phase in undercooled Fe-7.5 at% Ni alloy

Y. Z. Chen, G. C. Yang, F. Liu, H. Xie, Y. P. Su, N. Liu, C. L. Yang, Y. H. Zhou

School of Materials Sience and Engineering

Northwestern Polytechnical University Xian

Research output: Contribution to journal › Article › peer-review

11 Scopus citations

Abstract

Microstructure characterization and transition of undercooled Fe-7.5 at% Ni melt were investigated, adopting melt fluxing and cyclical overheating. For the samples subjected to low undercoolings, single-phase microstructure results, whereas many second-phase particles, which are deemed as the so-called dendrite core originating from the primary solidification of the metastable δ phase, were observed in the as-solidified samples after high undercoolings. Applying the classical nucleation theory, the competitive nucleation between δ and γ phases was studied, thus giving calculations consistent with the observed experiment results. In order to understand the forming mechanism of the dendrite core, a schematic diagram incorporating solidification and solid-state transformation was given. On this basis the microstructural transition of the metastable phase was declared.

Original language	English
Pages (from-to)	1-5
Number of pages	5
Journal	Journal of Crystal Growth
Volume	289
Issue number	1
DOIs	https://doi.org/10.1016/j.jcrysgro.2005.10.128
State	Published - 15 Mar 2006

Keywords

A1. Metastable phase
A1. Microstructure
A1. Solidification
A1. Undercooling

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10.1016/j.jcrysgro.2005.10.128

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title = "Microstructural transitions of metastable phase in undercooled Fe-7.5 at% Ni alloy",

abstract = "Microstructure characterization and transition of undercooled Fe-7.5 at% Ni melt were investigated, adopting melt fluxing and cyclical overheating. For the samples subjected to low undercoolings, single-phase microstructure results, whereas many second-phase particles, which are deemed as the so-called dendrite core originating from the primary solidification of the metastable δ phase, were observed in the as-solidified samples after high undercoolings. Applying the classical nucleation theory, the competitive nucleation between δ and γ phases was studied, thus giving calculations consistent with the observed experiment results. In order to understand the forming mechanism of the dendrite core, a schematic diagram incorporating solidification and solid-state transformation was given. On this basis the microstructural transition of the metastable phase was declared.",

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author = "Chen, {Y. Z.} and Yang, {G. C.} and F. Liu and H. Xie and Su, {Y. P.} and N. Liu and Yang, {C. L.} and Zhou, {Y. H.}",

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T1 - Microstructural transitions of metastable phase in undercooled Fe-7.5 at% Ni alloy

AU - Chen, Y. Z.

AU - Yang, G. C.

AU - Liu, F.

AU - Xie, H.

AU - Su, Y. P.

AU - Liu, N.

AU - Yang, C. L.

AU - Zhou, Y. H.

PY - 2006/3/15

Y1 - 2006/3/15

N2 - Microstructure characterization and transition of undercooled Fe-7.5 at% Ni melt were investigated, adopting melt fluxing and cyclical overheating. For the samples subjected to low undercoolings, single-phase microstructure results, whereas many second-phase particles, which are deemed as the so-called dendrite core originating from the primary solidification of the metastable δ phase, were observed in the as-solidified samples after high undercoolings. Applying the classical nucleation theory, the competitive nucleation between δ and γ phases was studied, thus giving calculations consistent with the observed experiment results. In order to understand the forming mechanism of the dendrite core, a schematic diagram incorporating solidification and solid-state transformation was given. On this basis the microstructural transition of the metastable phase was declared.

AB - Microstructure characterization and transition of undercooled Fe-7.5 at% Ni melt were investigated, adopting melt fluxing and cyclical overheating. For the samples subjected to low undercoolings, single-phase microstructure results, whereas many second-phase particles, which are deemed as the so-called dendrite core originating from the primary solidification of the metastable δ phase, were observed in the as-solidified samples after high undercoolings. Applying the classical nucleation theory, the competitive nucleation between δ and γ phases was studied, thus giving calculations consistent with the observed experiment results. In order to understand the forming mechanism of the dendrite core, a schematic diagram incorporating solidification and solid-state transformation was given. On this basis the microstructural transition of the metastable phase was declared.

KW - A1. Metastable phase

KW - A1. Microstructure

KW - A1. Solidification

KW - A1. Undercooling

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DO - 10.1016/j.jcrysgro.2005.10.128

M3 - 文章

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SN - 0022-0248

VL - 289

SP - 1

EP - 5

JO - Journal of Crystal Growth

JF - Journal of Crystal Growth

IS - 1

ER -

Microstructural transitions of metastable phase in undercooled Fe-7.5 at% Ni alloy

Abstract

Keywords

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