Multi-phase-field simulation of austenite peritectic solidification based on a ferrite grain

Chao Yang; Jing Wang; Junsheng Wang; Yu Liu; Guomin Han; Haifeng Song; Houbing Huang

doi:10.1088/1674-1056/abc54b

Multi-phase-field simulation of austenite peritectic solidification based on a ferrite grain

Chao Yang, Jing Wang, Junsheng Wang, Yu Liu, Guomin Han, Haifeng Song, Houbing Huang^*

^*Corresponding author for this work

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

2 Citations (Scopus)

Abstract

A multi-phase-field model is implemented to investigate the peritectic solidification of Fe-C alloy. The nucleation mode of austenite is based on the local driving force, and two different thicknesses of the primary austenite on the surface of the ferrite equiaxed crystal grain are used as the initial conditions. The simulation shows the multiple interactions of ferrite, austenite, and liquid phases, and the effects of carbon diffusion, which presents the non-equilibrium dynamic process during Fe-C peritectic solidification at the mesoscopic scale. This work not only reveals the influence of the austenite nucleation position, but also clarifies the formation mechanism of liquid phase channels and molten pools. Therefore, the present study contributes to the understanding of the micro-morphology and micro-segregation evolution mechanisms of Fe-C alloy during peritectic solidification.

Original language	English
Article number	018201
Journal	Chinese Physics B
Volume	30
Issue number	1
DOIs	https://doi.org/10.1088/1674-1056/abc54b
Publication status	Published - Jan 2021

Keywords

Fe- C alloy
carbon diffusion
morphology evolution
multi-phase-field simulation
peritectic solidification

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10.1088/1674-1056/abc54b

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title = "Multi-phase-field simulation of austenite peritectic solidification based on a ferrite grain",

abstract = "A multi-phase-field model is implemented to investigate the peritectic solidification of Fe-C alloy. The nucleation mode of austenite is based on the local driving force, and two different thicknesses of the primary austenite on the surface of the ferrite equiaxed crystal grain are used as the initial conditions. The simulation shows the multiple interactions of ferrite, austenite, and liquid phases, and the effects of carbon diffusion, which presents the non-equilibrium dynamic process during Fe-C peritectic solidification at the mesoscopic scale. This work not only reveals the influence of the austenite nucleation position, but also clarifies the formation mechanism of liquid phase channels and molten pools. Therefore, the present study contributes to the understanding of the micro-morphology and micro-segregation evolution mechanisms of Fe-C alloy during peritectic solidification.",

keywords = "Fe- C alloy, carbon diffusion, morphology evolution, multi-phase-field simulation, peritectic solidification",

author = "Chao Yang and Jing Wang and Junsheng Wang and Yu Liu and Guomin Han and Haifeng Song and Houbing Huang",

note = "Publisher Copyright: {\textcopyright} 2021 Chinese Physical Society and IOP Publishing Ltd.",

year = "2021",

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doi = "10.1088/1674-1056/abc54b",

language = "English",

volume = "30",

journal = "Chinese Physics B",

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T1 - Multi-phase-field simulation of austenite peritectic solidification based on a ferrite grain

AU - Yang, Chao

AU - Wang, Jing

AU - Wang, Junsheng

AU - Liu, Yu

AU - Han, Guomin

AU - Song, Haifeng

AU - Huang, Houbing

PY - 2021/1

Y1 - 2021/1

N2 - A multi-phase-field model is implemented to investigate the peritectic solidification of Fe-C alloy. The nucleation mode of austenite is based on the local driving force, and two different thicknesses of the primary austenite on the surface of the ferrite equiaxed crystal grain are used as the initial conditions. The simulation shows the multiple interactions of ferrite, austenite, and liquid phases, and the effects of carbon diffusion, which presents the non-equilibrium dynamic process during Fe-C peritectic solidification at the mesoscopic scale. This work not only reveals the influence of the austenite nucleation position, but also clarifies the formation mechanism of liquid phase channels and molten pools. Therefore, the present study contributes to the understanding of the micro-morphology and micro-segregation evolution mechanisms of Fe-C alloy during peritectic solidification.

AB - A multi-phase-field model is implemented to investigate the peritectic solidification of Fe-C alloy. The nucleation mode of austenite is based on the local driving force, and two different thicknesses of the primary austenite on the surface of the ferrite equiaxed crystal grain are used as the initial conditions. The simulation shows the multiple interactions of ferrite, austenite, and liquid phases, and the effects of carbon diffusion, which presents the non-equilibrium dynamic process during Fe-C peritectic solidification at the mesoscopic scale. This work not only reveals the influence of the austenite nucleation position, but also clarifies the formation mechanism of liquid phase channels and molten pools. Therefore, the present study contributes to the understanding of the micro-morphology and micro-segregation evolution mechanisms of Fe-C alloy during peritectic solidification.

KW - Fe- C alloy

KW - carbon diffusion

KW - morphology evolution

KW - multi-phase-field simulation

KW - peritectic solidification

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JO - Chinese Physics B

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ER -

Multi-phase-field simulation of austenite peritectic solidification based on a ferrite grain

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Keywords

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