Velocity Selection in 3D Dendrites: Phase Field Computations and Microgravity Experiments

TL;DR

This study combines phase field modeling and microgravity experiments to analyze 3D dendrite growth, revealing insights into tip velocity behavior and dimensional effects with high computational resolution.

Contribution

It introduces a high-resolution 3D phase field simulation aligned with microgravity experiments to investigate dendrite tip velocity and anisotropy effects.

Findings

Tip velocity aligns with microgravity experiment results.

Tip velocity does not increase with anisotropy.

3D growth differs from 2D by a factor of about 1.9.

Abstract

The growth of a single needle of succinonitrile (SCN) is studied in three dimensional space by using a phase field model. For realistic physical parameters, namely, the large differences in the length scales, i.e., the capillarity length (10^{-8}cm - 10^{-6}cm), the radius of the curvature at the tip of the interface (10^{-3}cm - 10^{-2}cm) and the diffusion length (10^{-3}cm - 10^{-1}cm), resolution of the large differences in length scale necessitates a 500^{3} grid points on the supercomputer. The parameters, initial and boundary conditions used are identical to those of the microgravity experiments of Glicksman et al for SCN. The numerical results for the tip velocity are (i) largely consistent with the Space Shuttle experiments; (ii) compatible with the experimental conclusion that tip velocity does not increase with increased anisotropy; (iii) different for 2D versus 3D by a factor of approximately 1.9; (iv) essentially identical for fully versus rotationally symmetric 3D.