A Phase-Field Model of Spiral Dendritic Growth

A. A. Wheeler; A. Boesch; A. Karma; C. M. Knobler; E. Ben-Jacob; E. Brener; G. B. McFadden; G. Caginalp; Herbert Levine; J. B. Collins; J. S. Langer; J. V. Selinger; K. Stine; O. Penrose; R. Kam; R. Kobayashi; R. Kupferman; R. Kupferman; R. Viswanathan; R. Weis; Royce Kam; T. Fischer; V. M. Kaganer; W. M. Heckl; Xiao-Min Yang

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A Phase-Field Model of Spiral Dendritic Growth

Authors: A. A. Wheeler
A. Boesch
A. Karma
C. M. Knobler
E. Ben-Jacob
E. Brener
G. B. McFadden
G. Caginalp
Herbert Levine
J. B. Collins
J. S. Langer
J. V. Selinger
K. Stine
O. Penrose
R. Kam
R. Kobayashi
R. Kupferman
R. Kupferman
R. Viswanathan
R. Weis
Royce Kam
T. Fischer
V. M. Kaganer
W. M. Heckl
Xiao-Min Yang
Publication date: 1 January 1996
Publisher: 'American Physical Society (APS)'
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Abstract

Domains of condensed-phase monolayers of chiral molecules exhibit a variety of interesting nonequilibrium structures when formed via pressurization. To model these domain patterns, we add a complex field describing the tilt degree of freedom to an (anisotropic) complex-phase-field solidification model. The resulting formalism allows for the inclusion of (in general, non-reflection symmetric) interactions between the tilt, the solid-liquid interface, and the bond orientation. Simulations demonstrate the ability of the model to exhibit spiral dendritic growth.Comment: text plus Four postscript figure file

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