Your search keyword '"Rao, Xiao"' showing total 3 results

1. Comparison of Microphysical Characteristics of Warm-sector, Frontal and Shear-line Heavy Rainfall During the Pre-summer Rainy Season in South China.

Author

XIA Feng, LIU Xian-tong, HU Sheng, LI Hui-qi, RAO Xiao-na, LIN Qing, XIAO Hui, FENG Lu, and LAI Rui-ze

Subjects

RAINFALL, HAIL, WATER vapor, RAINDROPS, SEASONS, VERTICAL drafts (Meteorology)

Abstract

Warm-sector heavy rainfall (WR), shear-line heavy rainfall (SR), and frontal heavy rainfall (FR) are three types of rainfall that frequently occur during the pre-summer rainy season in south China. In this research, we investigated the differences in microphysical characteristics of heavy rainfall events during the period of 10-15 May 2022 based on the combined observations from 11 S-band polarimetric radars in south China. The conclusions are as follows: (1) WR has the highest radar echo top height, the strongest radar echo at all altitudes, the highest lightning density, and the most active ice-phase process, which suggests that the convection is the most vigorous in the WR, moderate in the FR, and the weakest in the SR. (2) Three types of rainfall are all marine-type precipitation, the massweighted mean diameter (Dm, mm) and the intercept parameter (Nw, mm-1m-3) of the raindrops in the WR are the largest. (3) The WR possesses the highest proportion of graupel compared with the FR and SR, and stronger updrafts and more abundant water vapor supply may lead to larger raindrops during the melting and collision-coalescence processes. (4) Over all the heights, liquid and ice water content in the WR are higher than those in the SR and FR, the ratio of ice to liquid water content in the WR is as high as 27% when ZH exceeds 50 dBZ, definitely higher than that in the SR and FR, indicating that the active ice-phase process existing in the WR is conducive to the formation of heavy rainfall. [ABSTRACT FROM AUTHOR]

Published

2023

2. Thermodynamics and Microphysical Characteristics of an Extreme Rainfall Event Under the Influence of a Low-level Jet over the South China Coast.

Author

XU Bi-yu, LI Hui-qi, YE Lang-ming, LIU Xian-tong, RAO Xiao-na, XIAO Hui, XU Jia-min, LIN Qing, PU Yi-liang, and HUANG Qing-lan

Subjects

RAINFALL, RAINSTORMS, VERTICAL wind shear, WATER vapor transport, AUTOMATIC meteorological stations, THERMODYNAMICS

Abstract

In this paper, the data of Automatic Weather Stations (AWSs), ERA5 reanalysis, sounding, wind profile radar, and dual-polarization radar are used to study an extreme rainfall event in the south China Coast on 11 to 12 May 2022 from the aspects of thermodynamics and microphysical characteristics under the influence of low-level jets (LLJs). Results show that: (1) The extreme rainfall event can be divided into two stages: the first stage (S1) from 0000 to 0600 LST on May 12 and the second stage (S2) from 0700 to 1700 LST on the same day. During S1, the rainfall is mainly caused by the upper-level shortwave trough and the boundary layer jet (BLJ), characterized by strong upward motion on the windward side of mountains. In S2, the combined influence of the BLJ and synoptic-system-related low-level jet (SLLJ) increases the vertical wind shear and vertical vorticity, strengthening the rainstorm. In combination with the effect of topography, a warm and humid southwest flow continuously transports water vapor to farther north, resulting in a significant increase in rainfall over the study area (on the terrain's windward slope). From S1 to S2, the altitude of a divergence center in the upper air decreases obviously. (2) The rainfalls in the two stages are both associated with the mesoscale convergence line (MCL) on the surface, and the wind field from the mesoscale outflow boundary (MOB) in S1 is in the same direction as the environmental winds. Due to a small area of convergence that is left behind the MOB, convection moves eastward quickly and causes a short duration of heavy rainfall. In S2, the convergence along the MOB is enhanced, which strengthens the rainfall and leads to strong outflows, further enhancing the surface convergence near the MOB and forming a positive feedback mechanism. It results in a slow motion of convection and a long duration of heavy rainfall. (3) In terms of microphysics, the center of a strong echo in S1 is higher than in S2. The warm-rain process of the oceanic type characterizes both stages, but the convective intensity in S2 is significantly stronger than that in S1, featuring bigger drop sizes and lower concentrations. It is mainly due to the strengthening of LLJs, which makes small cloud droplets lift to melting levels, enhancing the ice phase process (riming process), producing large amounts of graupel particles and enhancing the melting and collision processes as they fall, resulting in the increase of liquid water content (LWC) and the formation of large raindrops near the surface. [ABSTRACT FROM AUTHOR]

Published

2023

3. The Longmen Cloud Physics Field Experiment Base, China Meteorological Administration.

Author

LIU Xian-tong, RUAN Zheng, HU Sheng, WAN Qi-lin, LIU Li-ping, LUO Ya-li, HU Zhi-qun, LI Hui-qi, XIAO Hui, LEI Wei-yan, XIA Feng, RAO Xiao-na, FENG Lu, LAI Rui-ze, WU Chong, YE Lang-ming, GUO Ze-yong, ZHANG Yu, WANG Yao, and YAN Zhao-chao

Subjects

CLOUD physics, FIELD research, PHYSICS experiments, MARINE meteorology, MICROPHYSICS, PREDICTION models, RAINSTORMS

Abstract

Aiming at the needs of mechanism analysis of rainstorms and development of numerical prediction models in south China, the Guangzhou Institute of Tropical and Marine Meteorology of China Meteorological Administration and the Chinese Academy of Meteorological Sciences jointly set up the Longmen Cloud Physics Field Experiment Base, China Meteorological Administration. This paper introduces the instruments and field experiments of this base, provides an overview of the recent advances in retrieval algorithms of microphysical parameters, improved understanding of microphysical characteristics, as well as the formation mechanisms and numerical prediction of heavy rainfalls in south China based on the field experiments dataset. [ABSTRACT FROM AUTHOR]

Published

2023