Modelling of grain size transition with alloy concentration in solidified Al-Si alloys

Xiangdong Yao; Arne K. Dahle; Cameron J. Davidson; David H. Stjohn

doi:10.1007/s10853-007-1997-8

Modelling of grain size transition with alloy concentration in solidified Al-Si alloys

Xiangdong Yao
, Arne K. Dahle
, Cameron J. Davidson
, David H. Stjohn

School of Energy and Power Engineering

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

10 Scopus citations

Abstract

The transition in grain size with Si content in Al-Si alloys has been systematically investigated by the Cellular Automaton-Finite control Volume Method (CAFVM) to understand the operating mechanisms for this behavior. Three aspects: growth restriction factor (GRF), the chemical driving force (CDF) and the constitutional undercooling (ΔT _C ) have been demonstrated to affect the microstructure formation, and among them the ΔT _C plays the most important role. Furthermore, it is also shown that the surface modification of the nucleant particles by silicon significantly influences the grain formation. However, the combined effects of the investigated factors on the grain size were not sufficiently strong to cause a grain size change similar to that observed experimentally. This implies that there could be other mechanisms that control the transition.

Original language	English
Pages (from-to)	9756-9764
Number of pages	9
Journal	Journal of Materials Science
Volume	42
Issue number	23
DOIs	https://doi.org/10.1007/s10853-007-1997-8
State	Published - Dec 2007

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10.1007/s10853-007-1997-8

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title = "Modelling of grain size transition with alloy concentration in solidified Al-Si alloys",

abstract = "The transition in grain size with Si content in Al-Si alloys has been systematically investigated by the Cellular Automaton-Finite control Volume Method (CAFVM) to understand the operating mechanisms for this behavior. Three aspects: growth restriction factor (GRF), the chemical driving force (CDF) and the constitutional undercooling (ΔT C ) have been demonstrated to affect the microstructure formation, and among them the ΔT C plays the most important role. Furthermore, it is also shown that the surface modification of the nucleant particles by silicon significantly influences the grain formation. However, the combined effects of the investigated factors on the grain size were not sufficiently strong to cause a grain size change similar to that observed experimentally. This implies that there could be other mechanisms that control the transition.",

author = "Xiangdong Yao and Dahle, \{Arne K.\} and Davidson, \{Cameron J.\} and Stjohn, \{David H.\}",

year = "2007",

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TY - JOUR

T1 - Modelling of grain size transition with alloy concentration in solidified Al-Si alloys

AU - Yao, Xiangdong

AU - Dahle, Arne K.

AU - Davidson, Cameron J.

AU - Stjohn, David H.

PY - 2007/12

Y1 - 2007/12

N2 - The transition in grain size with Si content in Al-Si alloys has been systematically investigated by the Cellular Automaton-Finite control Volume Method (CAFVM) to understand the operating mechanisms for this behavior. Three aspects: growth restriction factor (GRF), the chemical driving force (CDF) and the constitutional undercooling (ΔT C ) have been demonstrated to affect the microstructure formation, and among them the ΔT C plays the most important role. Furthermore, it is also shown that the surface modification of the nucleant particles by silicon significantly influences the grain formation. However, the combined effects of the investigated factors on the grain size were not sufficiently strong to cause a grain size change similar to that observed experimentally. This implies that there could be other mechanisms that control the transition.

AB - The transition in grain size with Si content in Al-Si alloys has been systematically investigated by the Cellular Automaton-Finite control Volume Method (CAFVM) to understand the operating mechanisms for this behavior. Three aspects: growth restriction factor (GRF), the chemical driving force (CDF) and the constitutional undercooling (ΔT C ) have been demonstrated to affect the microstructure formation, and among them the ΔT C plays the most important role. Furthermore, it is also shown that the surface modification of the nucleant particles by silicon significantly influences the grain formation. However, the combined effects of the investigated factors on the grain size were not sufficiently strong to cause a grain size change similar to that observed experimentally. This implies that there could be other mechanisms that control the transition.

UR - https://www.scopus.com/pages/publications/34748845126

U2 - 10.1007/s10853-007-1997-8

DO - 10.1007/s10853-007-1997-8

M3 - 文章

AN - SCOPUS:34748845126

SN - 0022-2461

VL - 42

SP - 9756

EP - 9764

JO - Journal of Materials Science

JF - Journal of Materials Science

IS - 23

ER -

Modelling of grain size transition with alloy concentration in solidified Al-Si alloys

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