Numerical Modeling of the Influence of Nanometric Ceramic Particles on the Nucleation of AlSi10MnMg Alloy

Ane Jimenez; Jon Mikel Sanchez; Franck Girot; Mario Renderos; Pedro Egizabal

doi:10.3390/met12050855

Numerical Modeling of the Influence of Nanometric Ceramic Particles on the Nucleation of AlSi10MnMg Alloy

Ane Jimenez
, Jon Mikel Sanchez
, Franck Girot
, Mario Renderos
, Pedro Egizabal

Ikerbasque Basque Foundation for Science

Producción científica: Contribución a una revista › Artículo › revisión exhaustiva

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Resumen

In recent years, many researchers have attempted to model the solidification process of nano-reinforced materials. In the present document, the effect on the heterogeneous solidification regime of the different sizes, shapes, and chemical compositions of nanometric ceramic particles in an AlSi10MnMg alloy is studied. This article develops a mathematical model to predict the solidification behavior of a general nano-reinforced alloy, then validates the results using experimental techniques. The main objective of the model is to minimize the costly and time-consuming experimental process of fabricating nano-reinforced alloys. The proposed model predicts the critical Gibbs energy and the critical radius required for nucleation in the heterogeneous solidification regime. Conversely, the experimental part focuses on understanding the solidification process from the differential thermal analysis (DTA) of the solidification curves. It was concluded that if subcooling is involved, cubic and pyramidal particles work better as nucleating particles in the studied alloy.

Idioma original	Inglés
Número de artículo	855
Páginas (desde-hasta)	855
Número de páginas	1
Publicación	Metals
Volumen	12
N.º	5
DOI	https://doi.org/10.3390/met12050855
Estado	Publicada - 17 may 2022

Palabras clave

Heterogeneous solidification
Modeling
Shaped particles
Mechanical properties
Titanium carbide
Alumina

Project and Funding Information

Funding Info
This work was supported by project ICME—Methodology for multi-scale process-microstructure-properties-performance modelling for the improvement of the design of materials, processes and components in the metal industry of the Basque Country. ICME project has received funding from the Basque Government under the ELKARTEK Program (KK-2021/00022).

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title = "Numerical Modeling of the Influence of Nanometric Ceramic Particles on the Nucleation of AlSi10MnMg Alloy",

abstract = "In recent years, many researchers have attempted to model the solidification process of nano-reinforced materials. In the present document, the effect on the heterogeneous solidification regime of the different sizes, shapes, and chemical compositions of nanometric ceramic particles in an AlSi10MnMg alloy is studied. This article develops a mathematical model to predict the solidification behavior of a general nano-reinforced alloy, then validates the results using experimental techniques. The main objective of the model is to minimize the costly and time-consuming experimental process of fabricating nano-reinforced alloys. The proposed model predicts the critical Gibbs energy and the critical radius required for nucleation in the heterogeneous solidification regime. Conversely, the experimental part focuses on understanding the solidification process from the differential thermal analysis (DTA) of the solidification curves. It was concluded that if subcooling is involved, cubic and pyramidal particles work better as nucleating particles in the studied alloy.",

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AU - Jimenez, Ane

AU - Sanchez, Jon Mikel

AU - Girot, Franck

AU - Renderos, Mario

AU - Egizabal, Pedro

PY - 2022/5/17

Y1 - 2022/5/17

N2 - In recent years, many researchers have attempted to model the solidification process of nano-reinforced materials. In the present document, the effect on the heterogeneous solidification regime of the different sizes, shapes, and chemical compositions of nanometric ceramic particles in an AlSi10MnMg alloy is studied. This article develops a mathematical model to predict the solidification behavior of a general nano-reinforced alloy, then validates the results using experimental techniques. The main objective of the model is to minimize the costly and time-consuming experimental process of fabricating nano-reinforced alloys. The proposed model predicts the critical Gibbs energy and the critical radius required for nucleation in the heterogeneous solidification regime. Conversely, the experimental part focuses on understanding the solidification process from the differential thermal analysis (DTA) of the solidification curves. It was concluded that if subcooling is involved, cubic and pyramidal particles work better as nucleating particles in the studied alloy.

AB - In recent years, many researchers have attempted to model the solidification process of nano-reinforced materials. In the present document, the effect on the heterogeneous solidification regime of the different sizes, shapes, and chemical compositions of nanometric ceramic particles in an AlSi10MnMg alloy is studied. This article develops a mathematical model to predict the solidification behavior of a general nano-reinforced alloy, then validates the results using experimental techniques. The main objective of the model is to minimize the costly and time-consuming experimental process of fabricating nano-reinforced alloys. The proposed model predicts the critical Gibbs energy and the critical radius required for nucleation in the heterogeneous solidification regime. Conversely, the experimental part focuses on understanding the solidification process from the differential thermal analysis (DTA) of the solidification curves. It was concluded that if subcooling is involved, cubic and pyramidal particles work better as nucleating particles in the studied alloy.

KW - Heterogeneous solidification

KW - Modeling

KW - Shaped particles

KW - Mechanical properties

KW - Titanium carbide

KW - Alumina

KW - Heterogeneous solidification

KW - Modeling

KW - Shaped particles

KW - Mechanical properties

KW - Titanium carbide

KW - Alumina

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M3 - Article

SN - 2075-4701

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SP - 855

JO - Metals

JF - Metals

IS - 5

M1 - 855

ER -

Numerical Modeling of the Influence of Nanometric Ceramic Particles on the Nucleation of AlSi10MnMg Alloy

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