Abstract
In this study, we investigated the macro- and microstructures of layered precipitation clouds in spring in Jilin Province, China. The premise of the campaign was to observe cloud particles in the melting layer (ML). The weather was developed under the influence of the Mongolia cyclone, which brought a large range of precipitation to the northeast. Combining the Droplet Measurement Technology (DMT) and Particle Measuring Systems (PMS) data, small particles accounted for the majority of all particles at each level above and below the ML. In our observations, both ice crystals (50–300 μm) and snowflakes (>300 μm) had two peaks between −5 and −2 °C. The high concentration of ice crystals at a temperature of −2.65 °C (4865 m) attained a maximum value of 287 L−1 and snowflakes with 47 L−1, which was similar to the previous studies. The Hallett–Mossop ice multiplication process operated most effectively at the temperature of −5 °C in this study. Even at the cloud dissipation stage, new droplets were still generated between −5 and −6 °C, providing abundant liquid water content (LWC) for the upper cloud. Although irregulars were observed, needles and spheres dominated in the observed cloud region of low LWC (<0.1 g m−3) at temperatures of −6 to −3 °C. These cloud conditions fit into the Hallett–Mossop criteria.
Highlights
Regarding precipitation clouds, the vertical cloud structure reflects the dynamic and thermal structural characteristics and microphysical characteristics of precipitation cloud clusters [1,2,3,4]
Many observations and analyses have revealed that the structure of stratiform clouds and the precipitation process are complicated, related to the concentration of ice crystals in clouds, cloud thickness, and supercooled water content, and to the characteristics of the warm layer and the microphysical and dynamic processes in clouds [5,6,7,8,9]
We investigated the macro- and microstructures of layered precipitation clouds in spring in Jilin Province, China
Summary
The vertical cloud structure reflects the dynamic and thermal structural characteristics and microphysical characteristics of precipitation cloud clusters [1,2,3,4]. To better understand the characteristics of stratiform cloud precipitation, we must consider the detailed microphysical processes and properties of the melting layer (ML). Such as the continuous growth of aggregates via the agglomeration of small particles, the fragmentation of these aggregates, and the effect on particle melting, which have not been resolved [16]. ML properties were modified by the ambient environment, and microphysical processes taking place in the ML [23] Such melting effects lead to a decrease in particle size, the consequent decrease in particle concentration, and a signal reduction below the radar-bright band [24].
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