Electrically Enhanced Free Dendrite Growth in Polar and Non-polar Systems
Abstract
We describe the electrically enhanced growth of needle crystals from the vapor phase, for which there exists a morphological instability above a threshold applied potential. Our improved theoretical treatment of this phenomenon shows that the instability is present in both polar and non-polar systems, and we provide an extension of solvability theory to include electrical effects. We present extensive experimental data for ice needle growth above the electrical threshold, where at T=-5C high-velocity shape-preserving growth is observed. These data indicate that the needle tip assumes an effective radius R which is nearly independent of both supersaturation and the applied potential. The small scale of R and its response to chemical additives suggest that the needle growth rate is being limited primarily by structural instabilities, possibly related to surface melting. We also demonstrate experimentally that non-polar systems exhibit this same electrically induced morphological instability.
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