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http://dx.doi.org/10.14191/Atmos.2012.22.1.073

Implementation of Improved Ice Particle Collision Efficiency in Takahashi Cloud Model  

Lee, Hannah (Department of Atmospheric Sciences, Yonsei University)
Yum, Seong Soo (Department of Atmospheric Sciences, Yonsei University)
Publication Information
Atmosphere / v.22, no.1, 2012 , pp. 73-85 More about this Journal
Abstract
The collision efficiency data for collision between graupel or hail particles and cloud drops that take into account the differences of particle density are applied to the Takahashi cloud model. The original setting assumes that graupel or hail collision efficiency is the same as that of the cloud drops of the same volume. The Takahashi cloud model is run with the new collision efficiency data and the results are compared with those with the original. As an initial condition, a thermodynamic profile that can initiate strong convection is provided. Three different CCN concentration values and therefore three initial cloud drop spectra are prescribed that represent maritime (CCN concentration = 300 $cm^{-3}$), continental (1000 $cm^{-3}$) and extreme continental (5000 $cm^{-3}$) air masses to examine the aerosol effects on cloud and precipitation development. Increase of CCN concentration causes cloud drop sizes to decrease and cloud drop concentrations to increase. However, the concentration of ice particles decreases with the increase of CCN concentration because small drops are difficult to freeze. These general trends are well captured by both model runs (one with the new collision efficiency data and the other with the original) but there are significant differences: with the new data, the development of cloud and raindrop formation are delayed by (1) decrease of ice collision efficiency, (2) decrease of latent heat from riming process and (3) decrease of ice crystals generated by ice multiplication. These results indicate that the model run with the original collision efficiency data overestimates precipitation rates.
Keywords
Ice particle collision efficiency; Takahashi cloud model; bin microphysics;
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