National Meteorological Information Center,Beijing 100081; Chinese Academy of Meteorological Sciences,Beijing 100081; Wuhan Institute of Heavy Rain,Wuhan 430000; Anhui Meteorological Observatory,Hefei 230031
The evolution of a mesoscale convective system (MCS) that caused strong precipitation in the northern
area of Dabie Mountain during 21–22 June 2008 is analyzed, along with the evolution of the associated
meso-β-scale convective vortex (MCV). The mesoscale reanalysis data generated by the Local Analysis and
Prediction System (LAPS) at a 3-km horizontal resolution and a 1-h time resolution during the South China
Heavy Rainfall Experiment (SCHeREX) were utilized. The results show that two processes played key roles
in the enhancement of convective instability. First, the mesoscale low-level jet strengthened and shifted
eastward, leading to the convergence of warm-wet airflow and increasing convective instability at middle
and low levels. Second, the warm-wet airflow interacted with the cold airflow from the north, causing
increased vertical vorticity in the vicinity of steeply sloping moist isentropic surfaces. The combined action
of these two processes caused the MCS to shift progressively eastward. Condensation associated with the
MCS released latent heat and formed a layer of large diabatic heating in the middle troposphere, increasing
the potential vorticity below this layer. This increase in potential vorticity created favorable conditions for
the development of a low-level vortex circulation. The vertical motion associated with this low-level vortex
further promoted the development of convection, creating a positive feedback between the deep convection
and the low-level vortex circulation. This feedback mechanism not only promoted the maturation of the
MCS, but also played the primary role in the evolution of the MCV. The MCV formed and developed due
to the enhancement of the positive feedback that accompanied the coming together of the center of the
vortex and the center of the convection. The positive feedback peaked and the MCV matured when these
two centers converged. The positive feedback weakened and the MCV began to decay as the two centers
separated and diverged.
Guanshun Zhang, Jiangyu Mao, Wei Hua, et al. Synergistic Effect of the Planetary-scale Disturbance, Typhoon and Meso-β-scale Convective Vortex on the Extremely Intense Rainstorm on 20 July 2021 in Zhengzhou. Advances in Atmospheric Sciences, 2023, 40(3): 428.
DOI:10.1007/s00376-022-2189-9
2.
Chunguang Cui, Rong Wan, Bin Wang, et al. The Mesoscale Heavy Rainfall Observing System (MHROS) over the middle region of the Yangtze River in China. Journal of Geophysical Research: Atmospheres, 2015, 120(19)
DOI:10.1002/2015JD023341
3.
Jinxin Wang, Yinong Pan, Shicheng Wang. A numerical study of the evolution of a mesoscale convective vortex on the Meiyu front. Acta Meteorologica Sinica, 2013, 27(6): 889.
DOI:10.1007/s13351-013-0509-9
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XU Wenhui, NI Yunqi, WANG Xiaokang, QIU Xuexing. 2012: The Evolution of a Meso-β-Scale Convective Vortex in the Dabie Mountain Area. Journal of Meteorological Research, 26(5): 597-613. DOI: 10.1007/s13351-012-0505-5
XU Wenhui, NI Yunqi, WANG Xiaokang, QIU Xuexing. 2012: The Evolution of a Meso-β-Scale Convective Vortex in the Dabie Mountain Area. Journal of Meteorological Research, 26(5): 597-613. DOI: 10.1007/s13351-012-0505-5
XU Wenhui, NI Yunqi, WANG Xiaokang, QIU Xuexing. 2012: The Evolution of a Meso-β-Scale Convective Vortex in the Dabie Mountain Area. Journal of Meteorological Research, 26(5): 597-613. DOI: 10.1007/s13351-012-0505-5
Citation:
XU Wenhui, NI Yunqi, WANG Xiaokang, QIU Xuexing. 2012: The Evolution of a Meso-β-Scale Convective Vortex in the Dabie Mountain Area. Journal of Meteorological Research, 26(5): 597-613. DOI: 10.1007/s13351-012-0505-5
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