English

Three-dimensional dendrite tip morphology at low undercooling

Materials Science 2009-10-31 v1

Abstract

We investigate the three-dimensional morphology of the dendrite tip using the phase-field method. We find that, for low undercoolings, this morphology is ostensibly independent of anisotropy strength except for a localized shape distortion near the tip that only affects the value of the tip radius ρ\rho (which is crudely approximated by ρ(1α)ρIv\rho\approx (1-\alpha)\rho_{Iv} where ρIv\rho_{Iv} is the Ivantsov tip radius of an isothermal paraboloid with the same tip velocity and α\alpha is the stiffness anisotropy). The universal tip shape, which excludes this distortion, is well fitted by the form z=r2/2+A4r4cos4ϕz=-r^2/2+A_4 r^4\cos 4\phi where z|z| is the distance from the tip and all lengths are scaled by ρIv\rho_{Iv}. This fit yields A4A_4 in the range 0.0040.0050.004-0.005 in good quantitative agreement with the existing tip morphology measurements in succinonitrile [LaCombe et al., Phys. Rev. E {\bf 52}, 2778 (1995)], which are reanalyzed here and found to be consistent with a single cos4ϕ\cos 4\phi mode non-axisymmetric deviation from a paraboloid. Moreover, the fin shape away from the tip is well fitted by the power law z=ax5/3z=-a |x|^{5/3} with a0.68a\approx 0.68. Finally, the characterization of the operating state of the dendrite tip is revisited in the light of these results.

Cite

@article{arxiv.cond-mat/9909021,
  title  = {Three-dimensional dendrite tip morphology at low undercooling},
  author = {Alain Karma and Youngyih H. Lee and Mathis Plapp},
  journal= {arXiv preprint arXiv:cond-mat/9909021},
  year   = {2009}
}

Comments

12 pages, 17 eps figures, submitted to Phys. Rev. E