Solidification structure evolution in undercooled Fe82.5Ni17.5 melts

Yu Zeng Chen; Feng Liu; Lian Qiang Zhang; Qing Jun Leng; Bin Bin Sun; Gen Cang Yang

Solidification structure evolution in undercooled Fe_82.5Ni_17.5 melts

Yu Zeng Chen, Feng Liu, Lian Qiang Zhang, Qing Jun Leng, Bin Bin Sun, Gen Cang Yang

School of Materials Sience and Engineering

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

Abstract

Fe_82.5Ni_17.5 alloys were undercooled by means of molten glass fluxing and cycling superheating methods. The maximum undercooling of 330 K was achieved. In combination of the theoretical calculations and experimental observations, the solidification behavior and structure formation mechanisms were systematically investigated. If the bulk undercooling ΔT < 63 K, the coarsening dendritic structures result. When AT is in the range of 63 K < ΔT < 158 K, influenced by the serious remelting, which is produced by recalescence, the primary dendrite is remelted into refined spherical crystals. As ΔT increases to the range of 158 K < δT < 203 K, due to the remelting effect decrease to a low level, the as-solidified structure evolve into dendritic structure. While δ T > 203 K, the grain refinement is caused by the stress originating from the rapid solidification contraction.

Original language	English
Pages (from-to)	178-182
Number of pages	5
Journal	Hangkong Xuebao/Acta Aeronautica et Astronautica Sinica
Volume	28
Issue number	SUPPL.
State	Published - Aug 2007

Keywords

Crystal growth
Fe-Ni alloy
Grain refinement
Microstructure
Rapid solidification

Cite this

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title = "Solidification structure evolution in undercooled Fe82.5Ni17.5 melts",

abstract = "Fe82.5Ni17.5 alloys were undercooled by means of molten glass fluxing and cycling superheating methods. The maximum undercooling of 330 K was achieved. In combination of the theoretical calculations and experimental observations, the solidification behavior and structure formation mechanisms were systematically investigated. If the bulk undercooling ΔT < 63 K, the coarsening dendritic structures result. When AT is in the range of 63 K < ΔT < 158 K, influenced by the serious remelting, which is produced by recalescence, the primary dendrite is remelted into refined spherical crystals. As ΔT increases to the range of 158 K < δT < 203 K, due to the remelting effect decrease to a low level, the as-solidified structure evolve into dendritic structure. While δ T > 203 K, the grain refinement is caused by the stress originating from the rapid solidification contraction.",

keywords = "Crystal growth, Fe-Ni alloy, Grain refinement, Microstructure, Rapid solidification",

author = "Chen, {Yu Zeng} and Feng Liu and Zhang, {Lian Qiang} and Leng, {Qing Jun} and Sun, {Bin Bin} and Yang, {Gen Cang}",

year = "2007",

month = aug,

language = "英语",

volume = "28",

pages = "178--182",

journal = "Hangkong Xuebao/Acta Aeronautica et Astronautica Sinica",

issn = "1000-6893",

publisher = "AAAS Press of Chinese Society of Aeronautics and Astronautics",

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TY - JOUR

T1 - Solidification structure evolution in undercooled Fe82.5Ni17.5 melts

AU - Chen, Yu Zeng

AU - Liu, Feng

AU - Zhang, Lian Qiang

AU - Leng, Qing Jun

AU - Sun, Bin Bin

AU - Yang, Gen Cang

PY - 2007/8

Y1 - 2007/8

N2 - Fe82.5Ni17.5 alloys were undercooled by means of molten glass fluxing and cycling superheating methods. The maximum undercooling of 330 K was achieved. In combination of the theoretical calculations and experimental observations, the solidification behavior and structure formation mechanisms were systematically investigated. If the bulk undercooling ΔT < 63 K, the coarsening dendritic structures result. When AT is in the range of 63 K < ΔT < 158 K, influenced by the serious remelting, which is produced by recalescence, the primary dendrite is remelted into refined spherical crystals. As ΔT increases to the range of 158 K < δT < 203 K, due to the remelting effect decrease to a low level, the as-solidified structure evolve into dendritic structure. While δ T > 203 K, the grain refinement is caused by the stress originating from the rapid solidification contraction.

AB - Fe82.5Ni17.5 alloys were undercooled by means of molten glass fluxing and cycling superheating methods. The maximum undercooling of 330 K was achieved. In combination of the theoretical calculations and experimental observations, the solidification behavior and structure formation mechanisms were systematically investigated. If the bulk undercooling ΔT < 63 K, the coarsening dendritic structures result. When AT is in the range of 63 K < ΔT < 158 K, influenced by the serious remelting, which is produced by recalescence, the primary dendrite is remelted into refined spherical crystals. As ΔT increases to the range of 158 K < δT < 203 K, due to the remelting effect decrease to a low level, the as-solidified structure evolve into dendritic structure. While δ T > 203 K, the grain refinement is caused by the stress originating from the rapid solidification contraction.

KW - Crystal growth

KW - Fe-Ni alloy

KW - Grain refinement

KW - Microstructure

KW - Rapid solidification

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M3 - 文章

AN - SCOPUS:34948897006

SN - 1000-6893

VL - 28

SP - 178

EP - 182

JO - Hangkong Xuebao/Acta Aeronautica et Astronautica Sinica

JF - Hangkong Xuebao/Acta Aeronautica et Astronautica Sinica

IS - SUPPL.

ER -

Solidification structure evolution in undercooled Fe_82.5Ni_17.5 melts

Abstract

Keywords

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