Interface evolution of a particle in a supersaturated solution affected by a far-field uniform flow

Chen, Mingwen; Wang, Zidong

doi:10.1088/1674-1056/22/9/098104

Cited by 2 publications

(1 citation statement)

References 23 publications

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“…However, since the nonlinear system of the crystal growth with flow has no exact analytical solutions available generally, theoretical studies on the crystal growth with flow are relatively few. Chen et al [20,21] studied the effect of the far-field flow on the interface morphology of the spherical crystal. In this paper, the effect of the convective flow caused by the far-field flow on the interface evolution of the columnar crystal is discussed by using the asymptotic expansion method, the results obtained show the interface morphology of the columnar crystal affected by the far-field flow.…”

Section: Introductionmentioning

confidence: 99%

Effect of far-field flow on a columnar crystal in the convective undercooled melt

Xiao-Jian¹,

Chen²,

Xiao-Hua³

et al. 2015

Chinese Phys. B

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The growth behavior of a columnar crystal in the convective undercooled melt affected by the far-field uniform flow is studied and the asymptotic solution for the interface evolution of the columnar crystal is derived by means of the asymptotic expansion method. The results obtained reveal that the far-field flow induces a significant change of the temperature around the columnar crystal and the convective flow caused by the far-field flow accelerates the growth velocity of the interface of the growing columnar crystal in the upstream direction and inhibits its growth velocity in the downstream direction. Our results are similar to the experimental data and numerical simulations.

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Section: Introductionmentioning

confidence: 99%

Effect of far-field flow on a columnar crystal in the convective undercooled melt

Xiao-Jian¹,

Chen²,

Xiao-Hua³

et al. 2015

Chinese Phys. B

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Phase-field crystal method investigated the dislocation annihilation and grain boundary migration in grain shrink process

Shang-Jie¹,

Chen²,

Jiang-Juan³

et al. 2014

Acta Phys. Sin.

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The phase-field crystal method is used to analysis the dislocation annihilation and grain boundary migration mechanism in the grain shrink process of the circular grain which has three different misorientations from the matrix grain. Results show that when the misorientation between the circular grain and the matrix grain is 17°, the structure of grain boundary is composed of dislocations whose cores is so near that can not find a single dislocation. This grain boundary can not be explained by the dislocation model. However the circular grain area decreases linearly with time, which is in good agreement with the classical boundary migration theory. When the misorientation is 4°, the grain boundary structure is composed of discrete dislocations. Dislocations climb along the radial dierction and the grain rotation occurs for the circular grain to adjust the space of dislocations in the process of circular grain shrinkage. Reactions may take place with the dislocatins becoming closer. For the misorientation of 10°, portion of the grain boundary is composed of discrete dislocations and portion of dislocations with cores overlapped. Dislocations climb along the radial direction and tangential motion occurs at the same time in the grain shrinkage process. The coupled motion lead to the dislocations becoming close and reacting with each other.

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Interface evolution of a particle in a supersaturated solution affected by a far-field uniform flow

Cited by 2 publications

References 23 publications

Effect of far-field flow on a columnar crystal in the convective undercooled melt

Effect of far-field flow on a columnar crystal in the convective undercooled melt

Phase-field crystal method investigated the dislocation annihilation and grain boundary migration in grain shrink process

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