Phase field simulation of the interface morphology evolution and its stability during directional solidification of binary alloys

Jin Cheng Wang; Jun Jie Li; Yu Juan Yang; Yu Xiang Zhang; Gen Cang Yang

doi:10.1007/s11431-008-0041-9

Phase field simulation of the interface morphology evolution and its stability during directional solidification of binary alloys

Jin Cheng Wang, Jun Jie Li, Yu Juan Yang, Yu Xiang Zhang, Gen Cang Yang

School of Materials Sience and Engineering

Northwestern Polytechnical University Xian

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

3 Scopus citations

Abstract

The influences of pulling speed V and temperature gradient G on morphology evolution, concentration distribution, solute trapping and interface stability during directional solidification of binary alloys have been studied with the B-S phase field model. Simulated results reproduced the morphology transitions of deep cell to shallow cell and shallow cell to plane front. The primary cellular spacing, depth of groove and effective solute redistribution coefficient for different V and G are compared. The absolute stability under high pulling speed and high temperature gradient has also been predicted, which is in agreement with the Mullins-Sekerka (M-S) stability theory.

Original language	English
Pages (from-to)	362-370
Number of pages	9
Journal	Science in China, Series E: Technological Sciences
Volume	51
Issue number	4
DOIs	https://doi.org/10.1007/s11431-008-0041-9
State	Published - Apr 2008

Keywords

Directional solidification
Morphology evolution
Phase field method
Stability

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10.1007/s11431-008-0041-9

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title = "Phase field simulation of the interface morphology evolution and its stability during directional solidification of binary alloys",

abstract = "The influences of pulling speed V and temperature gradient G on morphology evolution, concentration distribution, solute trapping and interface stability during directional solidification of binary alloys have been studied with the B-S phase field model. Simulated results reproduced the morphology transitions of deep cell to shallow cell and shallow cell to plane front. The primary cellular spacing, depth of groove and effective solute redistribution coefficient for different V and G are compared. The absolute stability under high pulling speed and high temperature gradient has also been predicted, which is in agreement with the Mullins-Sekerka (M-S) stability theory.",

keywords = "Directional solidification, Morphology evolution, Phase field method, Stability",

author = "Wang, {Jin Cheng} and Li, {Jun Jie} and Yang, {Yu Juan} and Zhang, {Yu Xiang} and Yang, {Gen Cang}",

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T1 - Phase field simulation of the interface morphology evolution and its stability during directional solidification of binary alloys

AU - Wang, Jin Cheng

AU - Li, Jun Jie

AU - Yang, Yu Juan

AU - Zhang, Yu Xiang

AU - Yang, Gen Cang

PY - 2008/4

Y1 - 2008/4

N2 - The influences of pulling speed V and temperature gradient G on morphology evolution, concentration distribution, solute trapping and interface stability during directional solidification of binary alloys have been studied with the B-S phase field model. Simulated results reproduced the morphology transitions of deep cell to shallow cell and shallow cell to plane front. The primary cellular spacing, depth of groove and effective solute redistribution coefficient for different V and G are compared. The absolute stability under high pulling speed and high temperature gradient has also been predicted, which is in agreement with the Mullins-Sekerka (M-S) stability theory.

AB - The influences of pulling speed V and temperature gradient G on morphology evolution, concentration distribution, solute trapping and interface stability during directional solidification of binary alloys have been studied with the B-S phase field model. Simulated results reproduced the morphology transitions of deep cell to shallow cell and shallow cell to plane front. The primary cellular spacing, depth of groove and effective solute redistribution coefficient for different V and G are compared. The absolute stability under high pulling speed and high temperature gradient has also been predicted, which is in agreement with the Mullins-Sekerka (M-S) stability theory.

KW - Directional solidification

KW - Morphology evolution

KW - Phase field method

KW - Stability

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M3 - 文章

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SN - 1006-9321

VL - 51

SP - 362

EP - 370

JO - Science in China, Series E: Technological Sciences

JF - Science in China, Series E: Technological Sciences

IS - 4

ER -

Phase field simulation of the interface morphology evolution and its stability during directional solidification of binary alloys

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Keywords

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