Morphology diagram of thermal dendritic solidification by means of phase-field models in two and three dimensions

Morphology diagram of thermal dendritic solidification by means of phase-field models in two and three dimensions

We have determined morphology diagrams in two and three dimensions for two different phase-field models [A.A Wheeler, B.T. Murray, R.J. Schaefer, Physica D 66 (1993) 243; A. Karma, W.-J. Rappel, Phys. Rev. E 57 (1998) 4323] for the parameters undercooling and anisotropy of surface tension. The compa...

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Veröffentlicht in:Journal of crystal growth 2006-10, Vol.296 (1), p.58-68
Hauptverfasser: Singer, H.M., Singer-Loginova, I., Bilgram, J.H., Amberg, G.
Format: Artikel
Sprache:eng
Schlagworte:
3 dimensions
A1. Computer simulation
A1. Crystal morphology
A1. Dendrites
A1. Morphological stability
A1. Solidification
A2. Growth from melt
computer simulation
Cross-disciplinary physics: materials science
rheology
crystal morphology
crystal-growth
dendrites
diffusional growth
Exact sciences and technology
growth from melt
Growth from melts
zone melting and refining
Materials science
Methods of crystal growth
physics of crystal growth
morphological stability
parameters
pattern-formation
Phase diagrams and microstructures developed by solidification and solid-solid phase transformations
Physics
simulations
Solidification
systems
xenon dendrites
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Zusammenfassung:We have determined morphology diagrams in two and three dimensions for two different phase-field models [A.A Wheeler, B.T. Murray, R.J. Schaefer, Physica D 66 (1993) 243; A. Karma, W.-J. Rappel, Phys. Rev. E 57 (1998) 4323] for the parameters undercooling and anisotropy of surface tension. The comparison with analytical predictions show a qualitative correspondence, however, the predicted shape of the morphology boundary differs significantly from the shape found in our simulations. The two investigated models show the same quantitative behavior. Our simulations in 3D have shown that the shape of the morphology boundary is qualitatively similar to the one in 2D. However, we find that the border is shifted by an amount of 0.3% on the anisotropy axis. Our simulated 3D structures show a qualitative correspondence to the ones we have found in in situ experiments with xenon.
ISSN:0022-0248
1873-5002
1873-5002
DOI:10.1016/j.jcrysgro.2006.07.033