2008
DOI: 10.1007/s11467-008-0040-0
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Steady needle growth with 3-D anisotropic surface tension

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 extend… Show more

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Cited by 7 publications
(5 citation statements)
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“…[7][8][9][10][11][12][13][14][15][16][17][18][19][20][21][22][23][24] These efforts included precepts and hypotheses on dendritic interfacial physics as varied as the following: Take, for example, item (a), the concept of maximum velocity, which would occur, hypothetically, for a paraboloidal dendrite, the solid-liquid interface of which has interfacial energy, i.e., capillarity. As all interfaces have excess free energy, or surface tension, this idea could, conceivably, have provided a reasonable supposition about the operating state of dendrites: namely, that dendrites grow steadily when they achieve their maximum velocity, as allowed by the thermal conduction field and the level of supercooling specified in the melt.…”
Section: Interfacial Physicsmentioning
confidence: 99%
“…[7][8][9][10][11][12][13][14][15][16][17][18][19][20][21][22][23][24] These efforts included precepts and hypotheses on dendritic interfacial physics as varied as the following: Take, for example, item (a), the concept of maximum velocity, which would occur, hypothetically, for a paraboloidal dendrite, the solid-liquid interface of which has interfacial energy, i.e., capillarity. As all interfaces have excess free energy, or surface tension, this idea could, conceivably, have provided a reasonable supposition about the operating state of dendrites: namely, that dendrites grow steadily when they achieve their maximum velocity, as allowed by the thermal conduction field and the level of supercooling specified in the melt.…”
Section: Interfacial Physicsmentioning
confidence: 99%
“…However, in order to understand the selection mechanism and essence of pattern formation of dendritic growth, one is only interested in the behaviour of the system in a finite region behind the dendrite-tip away from the root, not near the root. It is just in that region, that for a given (ξ, η, θ), as ε → 0 the basic state of dendritic growth can be expanded in the following regular perturbation expansion (RPE): [14,22,24,25]…”
Section: The Basic State For Dendritic Growth With Nonzero Surface Te...mentioning
confidence: 99%
“…[22]- [24], and Ref. [25]). Especially, for the system with isotropic surface tension, the temperature in the liquid is…”
Section: O(ε 2 )mentioning
confidence: 99%
“…From the far field condition, we derive D 1 = 0, and we also have D 3 = D 3 . The connection condition between the coefficients {D 1 , D 3 = D 3 } in sector (S 1 ) and {D 1 = 0, D 3 } in sector (S 2 ) is to be derived by matching the outer solution (8) with the inner solution near the singular point ζ c .…”
Section: Singular Point ζ C Of the Outer Solution And Stokes Phenomenonmentioning
confidence: 99%
“…However, when the parameter of anisotropy of surface tension α 4 is large, the ratio Pe 0 Pe may be quite large (refer to Refs. [8], [9] and [10]. Therefore, it is not surprising, that there is the case for dendritic growth, in which the ε * -criterion may be significantly different from the σ * -criterion.…”
Section: Global Trapped-wave (Gtw) Modes and The Quantization Conditionmentioning
confidence: 99%