Abstract
A numerical model of ice phase growth in an ascending parcel is used to delineate seeding requirements under the competing embryo and glaciation hypotheses. The strong updraft core is found to remain virtually all liquid until homogeneous freezing occurs, AgI or dry ice seeding having negligible effects with achievable seeding rates. This suggests that the glaciation hypothesis is untenable.
Natural hail embryo formation is noted to be limited to updrafts less than 3 to 4 m sec−1 at cloud base. AgI seeding of such updraft regions at rates currently used is found to produce concentrations of hail embryos sufficient to enhance competition in multi-cell hailstorms, although super-cell storms may require significantly greater seeding rates.
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Young, K.C. Growth of the ice phase in strong cumulonimbus updrafts. PAGEOPH 113, 1005–1017 (1975). https://doi.org/10.1007/BF01592971
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DOI: https://doi.org/10.1007/BF01592971