1.School of Mathematical Science, Nankai University; 2.School of Mathematical Science, Nankai University;Department of Mathematics and Statistics, McGill University;
Abstract:The effect of the anisotropic interfacial energy on dendritic growth has been an important subject, and has preoccupied many researchers in the field of materials science and condensed matter physics. The present paper is dedicated to the study of the effect of full 3-D anisotropic surface tension on the steady state solution of dendritic growth. We obtain the analytical form of the first order approximation solution in the regular asymptotic expansion around the Ivantsov’s needle growth solution, which extends the steady needle growth solution of the system with isotropic surface tension obtained by Xu and Yu (J. J. Xu and D. S. Yu, J. Cryst. Growth, 1998, 187: 314; J. J. Xu, Interfacial Wave Theory of Pattern Formation: Selection of Dendrite Growth and Viscous Fingering in a Hele-Shaw Flow, Berlin: Springer-Verlag, 1997).The solution is expanded in the general Laguerre series in any finite region around the needle-tip, and it is also expanded in a power series in the far field behind the tip. Both solutions are then numerically matched in the intermediate region. Based on this global valid solution, the dependence of Peclet number Pe and the interface’s morphology on the anisotropy parameter of surface tension as well as other physical parameters involved are determined. On the basis of this global valid solution, we explore the effect of the anisotropy parameter on the Peclet number of growth, as well as the morphology of the interface.
出版日期: 2008-12-05
引用本文:
. Steady needle growth with 3-D anisotropic surface
tension[J]. Frontiers of Physics in China, 2008, 3(4): 418-435.
CHEN Xiao-jun, CHEN Yong-qiang, XU Jian-pu, XU Jian-jun. Steady needle growth with 3-D anisotropic surface
tension. Front. Phys. , 2008, 3(4): 418-435.
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