Multiscale finite-difference-diffusion-Monte-Carlo method for simulating dendritic solidification

Abstract We present a novel hybrid computational method to simulate accurately dendritic solidification in the low undercooling limit where the dendrite tip radius is one or more orders of magnitude smaller than the characteristic spatial scale of variation of the surrounding thermal or solutal diffusion field. The first key feature of this method is an efficient multiscale diffusion Monte Carlo (DMC) algorithm which allows off-lattice random walkers to take longer and concomitantly rarer steps with increasing distance away from the solid–liquid interface. As a result, the computational cost of evolving the large-scale diffusion field becomes insignificant when compared to that of calculating the interface evolution. The second key feature is that random walks are only permitted outside of a thin liquid layer surrounding the interface. Inside this layer and in the solid, the diffusion equation is solved using a standard finite difference algorithm that is interfaced with the DMC algorithm using the local conservation law for the diffusing quantity. Here we combine this algorithm with a previously developed phase-field formulation of the interface dynamics and demonstrate that it can accurately simulate three-dimensional dendritic growth in a previously unreachable range of low undercoolings that is of direct experimental relevance.

[1]  W. Kurz,et al.  Fundamentals of Solidification , 1990 .

[2]  Martin E. Glicksman,et al.  Dendritic grown kinetics and structure I. Pivalic acid , 1991 .

[3]  A. Karma,et al.  Multiscale random-walk algorithm for simulating interfacial pattern formation. , 2000, Physical review letters.

[4]  Temkin,et al.  Structure formation and the morphology diagram of possible structures in two-dimensional diffusional growth. , 1996, Physical review. E, Statistical physics, plasmas, fluids, and related interdisciplinary topics.

[5]  Martin E. Glicksman,et al.  Overview 12: Fundamentals of dendritic solidification—I. Steady-state tip growth , 1981 .

[6]  Bruce T. Murray,et al.  Adaptive phase-field computations of dendritic crystal growth , 1997 .

[7]  J. Langer Instabilities and pattern formation in crystal growth , 1980 .

[8]  Karma Beyond steady-state lamellar eutectic growth. , 1987, Physical review letters.

[9]  Ihle,et al.  Fractal and compact growth morphologies in phase transitions with diffusion transport. , 1994, Physical review. E, Statistical physics, plasmas, fluids, and related interdisciplinary topics.

[10]  A. Schmidt Computation of Three Dimensional Dendrites with Finite Elements , 1996 .

[11]  A. Karma,et al.  Quantitative phase-field modeling of dendritic growth in two and three dimensions , 1996 .

[12]  Martin E. Glicksman,et al.  FUNDAMENTALS OF DENDRITIC SOLIDIFICATION—I. STEADY-STATE TIP GROWTH , 1981 .

[13]  J. Sethian,et al.  Crystal growth and dendritic solidification , 1992 .

[14]  M. Sano,et al.  Fractal structures of zinc metal leaves grown by electrodeposition , 1984 .

[15]  A. Karma,et al.  Phase-field model of dendritic sidebranching with thermal noise. , 1999, Physical review. E, Statistical physics, plasmas, fluids, and related interdisciplinary topics.

[16]  Barbieri,et al.  Predictions of dendritic growth rates in the linearized solvability theory. , 1989, Physical review. A, General physics.

[17]  C. Beckermann,et al.  Scaling behavior of three-dimensional dendrites , 1998 .

[18]  N. Goldenfeld,et al.  Adaptive Mesh Refinement Computation of Solidification Microstructures Using Dynamic Data Structures , 1998, cond-mat/9808216.

[19]  Paul Meakin,et al.  Diffusion-controlled cluster formation in 2—6-dimensional space , 1983 .

[20]  Dougherty,et al.  Development of side branching in dendritic crystal growth. , 1987, Physical review letters.

[21]  E. Brener,et al.  Pattern selection in two-dimensional dendritic growth , 1991 .

[22]  Leo P. Kadanoff,et al.  Simulating hydrodynamics: A pedestrian model , 1985 .

[23]  H. Stanley,et al.  Tip splitting without interfacial tension and dendritic growth patterns arising from molecular anisotropy , 1986, Nature.

[24]  Lee,et al.  Three-dimensional dendrite-tip morphology at low undercooling , 2000, Physical review. E, Statistical physics, plasmas, fluids, and related interdisciplinary topics.

[25]  Department of Physics,et al.  EFFICIENT COMPUTATION OF DENDRITIC MICROSTRUCTURES USING ADAPTIVE MESH REFINEMENT , 1998 .

[26]  Herbert Levine,et al.  Pattern selection in fingered growth phenomena , 1988 .

[27]  Liu,et al.  Surface-tension-anisotropy measurements of succinonitrile and pivalic acid: Comparison with microscopic solvability theory. , 1992, Physical review. A, Atomic, molecular, and optical physics.

[28]  Saito,et al.  Monte Carlo studies of equilibrium and growth shapes of a crystal. , 1989, Physical review. A, General physics.

[29]  Langer Dendritic sidebranching in the three-dimensional symmetric model in the presence of noise. , 1987, Physical review. A, General physics.

[30]  Steven E. Koonin,et al.  Computational Physics , 1986 .

[31]  Liang Random-walk simulations of flow in Hele Shaw cells. , 1986, Physical review. A, General physics.

[32]  Tamás Vicsek,et al.  Pattern Formation in Diffusion-Limited Aggregation , 1984 .

[33]  M. Glicksman,et al.  Dendritic growth velocities in microgravity. , 1994, Physical review letters.

[34]  A. Karma,et al.  Regular Article: Modeling Melt Convection in Phase-Field Simulations of Solidification , 1999 .

[35]  Bisang,et al.  Shape of the tip and the formation of sidebranches of xenon dendrites. , 1996, Physical review. E, Statistical physics, plasmas, fluids, and related interdisciplinary topics.

[36]  E. Ben-Jacob,et al.  Adaptive self-organization during growth of bacterial colonies , 1992 .

[37]  Temkin,et al.  Noise-induced sidebranching in the three-dimensional nonaxisymmetric dendritic growth. , 1995, Physical review. E, Statistical physics, plasmas, fluids, and related interdisciplinary topics.