The influence of solid–liquid interfacial energy anisotropy on equilibrium shapes, nucleation, triple lines and growth morphologies

The anisotropy of the solid–liquid interfacial energy plays a key role during the formation of as-solidified microstructures. Using the ξ-vector formalism of Cahn and Hoffman, this contribution presents the effect that anisotropy has on the equilibrium shapes of crystals and on surface tension equil...

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Veröffentlicht in:	Scripta materialia 2010-06, Vol.62 (12), p.904-909
Hauptverfasser:	Rappaz, M., Friedli, J., Mariaux, A., Salgado-Ordorica, M.
Format:	Artikel
Sprache:	eng
Schlagworte:	Alloys Anisotropy Crystals Dendrite morphology Equilibrium shape Formalism Heterogeneous nucleation Interfacial energy Microstructure Morphology Nucleation Solid–liquid interfacial energy anisotropy
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description	The anisotropy of the solid–liquid interfacial energy plays a key role during the formation of as-solidified microstructures. Using the ξ-vector formalism of Cahn and Hoffman, this contribution presents the effect that anisotropy has on the equilibrium shapes of crystals and on surface tension equilibrium at triple lines. Consequences for heterogeneous nucleation of anisotropic crystals and for dendritic growth morphologies are detailed with specific examples related to Al–Zn and Zn–Al alloys.
doi_str_mv	10.1016/j.scriptamat.2010.02.039
format	Article
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subjects	Alloys Anisotropy Crystals Dendrite morphology Equilibrium shape Formalism Heterogeneous nucleation Interfacial energy Microstructure Morphology Nucleation Solid–liquid interfacial energy anisotropy
title	The influence of solid–liquid interfacial energy anisotropy on equilibrium shapes, nucleation, triple lines and growth morphologies
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