Scaling laws for two-dimensional dendritic crystal growth in a narrow channel

Abstract

We investigate analytically and computationally the dynamics of 2D needle crystal growth from the melt in a narrow channel. Our analytical theory predicts that, in the low supersaturation limit, the growth velocity V decreases in time t as a power law V t-2/3, which we validate by phase-field and dendritic-needle-network simulations. Simulations further reveal that, above a critical channel width ≈ 5lD, where lD the diffusion length, needle crystals grow with a constant V<Vs, where Vs is the free-growth needle crystal velocity, and approaches Vs in the limit lD.

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