Modeling motion and growth of multiple dendrites during solidification based on vector-valued phase field and two-phase flow models

[Display omitted] •Vector-valued phase field model is used to simulate polycrystalline solidification.•Motion and collision of multiple dendrites are simulated.•A Navier-stokes solver robust to huge viscosity variation has been built.•Adaptive two-level time stepping scheme is adopted. Movement and...

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Bibliographic Details
Published in:Journal of materials science & technology 2020-12, Vol.58, p.171-187
Main Authors: Ren, Jian-kun, Chen, Yun, Cao, Yan-fei, Sun, Ming-yue, Xu, Bin, Li, Dian-zhong
Format: Article
Language:English
Subjects:
Dendrite’s motion
Phase field
Solidification
Two-phase flow
Variable viscosity
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Summary:[Display omitted] •Vector-valued phase field model is used to simulate polycrystalline solidification.•Motion and collision of multiple dendrites are simulated.•A Navier-stokes solver robust to huge viscosity variation has been built.•Adaptive two-level time stepping scheme is adopted. Movement and growth of dendrites are common phenomena during solidification. To numerically investigate these phenomena, two-phase flow model is employed to formulate the FSI (fluid-structure interaction) problem during dendritic solidification. In this model, solid is assumed to have huge viscosity to maintain its own shape and an exponential expression is constructed to describe variable viscosity across s-l (solid-liquid) interface. With an effective preconditioner for saddle point structure, we build a N-S (Navier-Stokes) solver robust to tremendous viscosity ratio (as large as 1010) between solid and liquid. Polycrystalline solidification is computed by vector-valued phase field model, which is computationally convenient to handle contact between dendrites. Locations of dendrites are updated by solving advection equations. Orientation change due to dendrite’s rotation has been considered as well. Calculation is accelerated by two-level time stepping scheme, adaptive mesh refinement, and parallel computation. Settlement and growth of a single dendrite and multiple dendrites in Al-Cu alloy were simulated, showing the availability of the provided model to handle anisotropic growth, motion and impingement of dendrites. This study lays foundation to simulate solidification coupled with deformation in the future.
ISSN:1005-0302
1941-1162
DOI:10.1016/j.jmst.2020.05.005