5 results on '"Liu, Xiantong"'
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2. Contrasts in the Evolution and MMicrophysical Features of Two Convective Systems during a Heavy Rainfall Event along the Coast of South China.
- Author
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Ye, Langming, Liu, Xiantong, Pu, Yiliang, Li, Huiqi, Xia, Feng, and Xu, Biyu
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RAINFALL , *RAINSTORMS , *AUTOMATIC meteorological stations , *STORMS , *COASTS , *RAINDROPS - Abstract
On 1 June 2021, a heavy rainstorm hit the coast of South China (148.6 mm in 1 h, 361 mm over 12 h). The storm process was successively affected by two convective systems (CSs). The initial convection of the two CSs occurred at a similar location; however, they subsequently showed different evolution characteristics. Based on multi-source data, including dual-polarimetric radars, wind profiling radars, sounding, and automatic weather stations, we explored the differences in the key characteristics of these two CSs. It was found that the convection was initially triggered at a similar location for both CSs, closely related to the mesoscale boundary and the hilly terrain. After formation, CS1 moved eastward to the regions with lower surface temperature and weaker lower-level convergence but similar humidity, which means the environmental conditions for sustaining the CS became less favorable. As a result, CS1 dissipated rapidly and only lasted for about 90 min, resulting in 5% of the total precipitation of the overall storm. In contrast, during the lifespan of CS2, the southerly wind over the South China Sea became stronger. This caused an intense lower-level convergence zone along the coastal region of Guangdong Province, which provided favorable dynamic conditions for maintaining CS2. Favored by the strong coastal convergence and abundant moisture, new convective cells (CCs) were generated continuously and merged with CS2, acting as another favorable condition for its sustainment. Overall, CS2 lasted for 8 h, and its precipitation accounted for 95% of the total rainfall. In CS1, CCs showed a notable evaporation process below 4 km, manifested by the large raindrops. However, in CS2, the CCs had a higher concentration of small raindrops and higher ice and liquid water content. Since CS2 was close to the coastal region, the warm local environment promoted convection, leading to intense precipitation. In addition, the riming and melting processes were active, leading to a high precipitation efficiency and strong local precipitation during a short period of time. [ABSTRACT FROM AUTHOR]
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- 2022
- Full Text
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3. Multiscale Perspectives on an Extreme Warm-Sector Rainfall Event over Coastal South China.
- Author
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Pu, Yiliang, Hu, Sheng, Luo, Yali, Liu, Xiantong, Hu, Lihua, Ye, Langming, Li, Huiqi, Xia, Feng, and Gao, Lingyu
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RAINDROP size ,RAINFALL ,RAINSTORMS ,RAINDROPS ,STORMS ,AIR travel - Abstract
On 22 June 2017, an extreme warm-sector rainfall event hit the western coastal area of South China, with maximum hourly and 12-h rainfall accumulations of 189.4 and 464.8 mm, respectively, which broke local historical records. Multisource observations were used to reveal multiscale processes contributing to the extreme rainfall. The results showed that a marine boundary layer jet (BLJ) coupled with a synoptic low-level jet (LLJ) inland played an important role in the formation of an extremely humid environment with a very low lifting condensation level of near-surface air. Under the favorable pre-convective conditions, convection was initialized at a mesoscale convergence line, aided by topographic lifting in the evening. During the nocturnal hours, the rainstorm developed and was maintained by a quasi-stationary mesoscale outflow boundary, which continuously lifted warm, moist air transported by the enhanced BLJ. When producing the extreme rainfall rates, the storm possessed relatively weak convection, with the 40 dBZ echo top hardly reaching 6 km. The extreme rainfall was produced mainly by the warm rain microphysical processes, mainly because the humid environment and the deep warm cloud layer facilitated the clouds' condensational growth and collision–coalescence, and also reduced rain evaporation. As the storm evolved, the raindrop concentration increased rapidly from its initial stage and remained high until its weakening stage, but the mean raindrop size changed little. The extreme rain was characterized by the highest concentration of raindrops during the storm's lifetime with a mean size of raindrops slightly larger than the maritime regime. [ABSTRACT FROM AUTHOR]
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- 2022
- Full Text
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4. Convective and Microphysical Characteristics of Extreme Precipitation Revealed by Multisource Observations Over the Pearl River Delta at Monsoon Coast.
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Yu, Shuting, Luo, Yali, Wu, Chong, Zheng, Dong, Liu, Xiantong, and Xu, Weixin
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RAINDROP size ,RAINDROPS ,COASTS ,HAIL ,MICROPHYSICS ,MONSOONS - Abstract
Extreme precipitation is an issue of worldwide concern, but its microphysics remain elusive. The convective and microphysical characteristics of extreme precipitation features (EPFs) in a monsoon coastal area (South China) are investigated mainly using 2‐year observations from a dual‐polarization radar and distrometers. The EPFs are accompanied by a broad range of convective intensity, and categorized into the "intense", "moderate", and "weak" convection accounting for 17.3%, 48.6% and 34.1% of the total population, respectively. The EPFs with weaker convection show weakened size sorting and less breakup of large raindrops, but a larger ratio of liquid water path to ice water path and more prominent coalescence warm‐rain process. All the three categories are dominated by the coalescence in the liquid‐phase processes, and have much more populous raindrops than the "continental" with a mean size larger than the "maritime" regime. These results improve our understanding of extreme precipitation from the microphysical perspective. Plain Language Summary: Extreme precipitation contributes significantly to the global precipitation and could induce flooding and severe hazards. Such a scenario may become more often in the warming climate. However, we do not know well whether extreme precipitation is mainly produced by intense convection with presence of large solid precipitating particles such as hail and graupel, or by rapid growth of many raindrops below the 0°C level with a lack of large solid precipitating particles aloft. To document the convective and microphysical characteristics of extreme precipitation, we use 2‐year, high‐resolution observations from a dual‐polarization radar, six 2D‐Video‐Distrometers (which measure raindrop size distribution), and Low‐Frequency E‐field Detection Array (which provides the three‐dimensional position and time of flashes) on a typical monsoon coast (South China). Results show that the extreme precipitation events have convective intensities ranging from relatively weak to very intense. The raindrops are larger‐sized than the "tropical maritime type" and much more populous than the "continental type" of convective precipitation. Key Points: Only 17% of the extreme precipitation features (EPFs) overlap with intense convection, while over 30% EPFs show limited mixed‐phase processCoalescence dominates (>75%) the liquid‐phase processes of EPFs over the monsoon coast, even for those with intense convectionMonsoonal EPFs show a mean raindrop size larger than the "maritime" and a raindrop concentration much higher than the "continental" regime [ABSTRACT FROM AUTHOR]
- Published
- 2022
- Full Text
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5. Characteristics of Raindrop Size Distribution in Typhoon Nida (2016) before and after Landfall in Southern China from 2D Video Disdrometer Data.
- Author
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Feng, Lu, Liu, Xiantong, Xiao, Hui, Xiao, Liusi, Xia, Feng, Hao, Xiao, Lu, Haiqi, and Zhang, Chenxian
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RAINDROP size , *LANDFALL , *TYPHOONS , *RAINDROPS , *VIDEOS , *RADAR , *TROPICAL cyclones - Abstract
During the passage of Typhoon Nida, the raindrop size distribution parameters, the raindrop spectra, the shape and slope (μ–Λ) relationship, the radar reflectivity factor, and rain rate (Z–R) relationship were investigated based on a two-dimensional (2D) video disdrometer in Guangdong, China, from August 1 to 2, 2016. Due to the underlying surface difference between the ocean and land, this process was divided into two distinct periods (before landfall and after landfall). The characteristics of raindrop size distribution between the period before landfall and the period after landfall were quite distinct. The period after landfall exhibited higher concentrations of each size bin (particularly small drops) and wider raindrop spectral width than the period before landfall. Compared with the period before landfall, the period after landfall had a higher average mass-weighted mean diameter Dm that was smaller than those of other TCs from the same ocean (the Pacific). The μ–Λ relationship and Z–R relationship in this study were also compared with other TCs from the same ocean (the Pacific). This investigation of the microphysical characteristics of Typhoon Nida before landfall and after landfall may improve radar quantitative precipitation estimation (QPE) products and microphysical schemes by providing useful information. [ABSTRACT FROM AUTHOR]
- Published
- 2021
- Full Text
- View/download PDF
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