Abstract
Stratiform clouds with embedded convective cells is an important precipitation system. Precise knowledge of the cloud’s microphysical structure can be useful for the development of a numerical weather prediction model and precipitation enhancement. Airborne measurement is one of the important ways for determining the microphysical structure of clouds. However, cloud particle shattering during measurement poses a serious problem to the measured microphysical characterization of clouds. In order to study the different influences of the shattered ice particles on the standard cloud imaging probe (CIP) measurement in the stratiform cloud region and the convective cloud region, a time-variant threshold method to identify the shattered fragments is presented. After application of this algorithm, the shattered fragments were recognized and their impacts on the particle size distribution (PSD), particle number concentration and ice water content measurement were analyzed. It was found that the shattering effect on the PSD decreases with the increasing size of less than 400 μm, fluctuates between 400 μm and 1000 μm and slightly increases with the increasing size of larger than 1000 μm on average in a stratiform region and a convective region. However, the average ratio of PSD uncorrected to that corrected for shattering events using the presented algorithm in convective clouds is larger than that in the stratiform regions in the whole size, and nearly twice that in the size of less than 1000 μm. The measured number concentration can be overestimated by up to a factor of 3.9 on average in a stratiform region, while in a convective region, it is 7.7, nearly twice that of a stratiform region. The ice water content in a stratiform region can be overestimated by 29.5% on average, but by 60.7% in a convective region. These findings can be helpful for the cloud physics community to use the airborne CIP measurement data for numerical weather and climate models.
Highlights
In China, most of the airborne imaging probes are of the standard form [21], and quite a significant number of cloud microphysical field measurements have been carried out in stratiform clouds with embedded convective cells at the service of weather modification in the past 15 years [22,23,24]
It is very important to answer the following question: What is the difference in the shattering effects on the standard cloud imaging probe (CIP) measurements in the stratiform cloud region and the convective cell region?
The data used in this study were from the Beijing Cloud Experiment (BCE), which was conducted from April to May 2009 in the upstream area of Beijing, Zhangjiakou area [27]
Summary
The long interarrival time mode represented the real cloud structure while the short interarrival time mode resulted from fragments of shattered ice particles They used the interarrival time threshold method to identify the shattered fragments and study the effects of shattering on measurements. In China, most of the airborne imaging probes are of the standard form [21], and quite a significant number of cloud microphysical field measurements have been carried out in stratiform clouds with embedded convective cells at the service of weather modification in the past 15 years [22,23,24]. It is very important to answer the following question: What is the difference in the shattering effects on the standard CIP measurements in the stratiform cloud region and the convective cell region?.
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