Characteristics of Mesoscale Convective Systems over the East Part of Continental China during the Meiyu from 2001 to 2003

Zhang, Chengzhong; Uyeda, Hiroshi; Yamada, Hiroyuki; Geng, Biao; Yunqi, Ni

doi:10.2151/jmsj.84.763

Cited by 30 publications

(31 citation statements)

References 19 publications

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“…Convection dominated by warm rain process was found to exist to south of the front (Maesaka 2001). Such convection, whose reflectivity structure was characterized by low altitude of reflectivity peak and low echo top height (15 dBZ ), corresponds to the CMD introduced by Zhang et al (2006). They analyzed 3 years of radar data over the east part of continental China, and concluded that the CMD predominated to the south of the Meiyu front.…”

Section: Summary and Discussionmentioning

confidence: 99%

“…Both LNB and LCL are low (Fig. 8), which are favorable condition for formation of the CMD south of the front (Zhang et al 2006). In the region between the front and 30 km south of the front, the CMD could form in the place where both LNB and LCL are low.…”

Section: Environment For the Cmd South Of The Meiyu Frontmentioning

confidence: 98%

“…To further understand the characteristics of the convection of medium depth (CMD) that was introduced by Zhang et al (2006), the dynamic and thermodynamic aspects of the CMD were examined with the use of a cloud-resolving numerical model. A typical case of the CMD south of the Meiyu front over the east part of continental China, which occurred between 00 UTC and 12 UTC 22 July 2002, was simulated and analyzed.…”

Section: Introductionmentioning

confidence: 99%

“…In an attempt to understand the characteristics of relatively low echo top convection, Zhang et al (2006) proposed the concept of convection of medium depth (CMD). The CMD was defined as a group of convective cells whose echo top height with the reflectivity of 15 dBZ was equal to or less than 8 km, and in which the reflectivity peak was below 4 km throughout their lifetime, by examining 3 years of radar and other observational data during the Meiyu period over the east part of continental China.…”

Section: Introductionmentioning

confidence: 99%

“…

AbstractTo further understand the characteristics of the convection of medium depth (CMD) that was introduced by Zhang et al (2006), the dynamic and thermodynamic aspects of the CMD were examined with the use of a cloud-resolving numerical model. A typical case of the CMD south of the Meiyu front over the east part of continental China, which occurred between 00 UTC and 12 UTC 22 July 2002, was simulated and analyzed.

Based on realistic simulation, results of a case study indicated that the CMD possessed the following features: 1) dominated by warm rain process, 2) rapid formation of raindrops and their rapid falling down to the surface, by comparison with those of deep convection.

…”

mentioning

confidence: 99%

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Characteristics of Convections of Medium Depth to South of the Meiyu Front Analyzed by Using Numerical Simulation

Zhang

Uyeda

Yamada

et al. 2006

SOLA

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To further understand the characteristics of the convection of medium depth (CMD) that was introduced by Zhang et al. (2006), the dynamic and thermodynamic aspects of the CMD were examined with the use of a cloud-resolving numerical model. A typical case of the CMD south of the Meiyu front over the east part of continental China, which occurred between 00 UTC and 12 UTC 22 July 2002, was simulated and analyzed.Based on realistic simulation, results of a case study indicated that the CMD possessed the following features: 1) dominated by warm rain process, 2) rapid formation of raindrops and their rapid falling down to the surface, by comparison with those of deep convection. It is expected that the CMD south of the Meiyu front over the east part of continental China shares such characteristics.

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Section: Summary and Discussionmentioning

confidence: 99%

Section: Environment For the Cmd South Of The Meiyu Frontmentioning

confidence: 98%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

“…

…”

mentioning

confidence: 99%

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Characteristics of Convections of Medium Depth to South of the Meiyu Front Analyzed by Using Numerical Simulation

Zhang

Uyeda

Yamada

et al. 2006

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Spatial and temporal characteristics of warm season convection over Pearl River Delta region, China, based on 3 years of operational radar data

2014

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This study examines the temporal and spatial characteristics and distributions of convection over the Pearl River Delta region of Guangzhou, China, during the May-September warm season, using, for the first time for such a purpose, 3 years of operational Doppler radar data in the region. Results show that convective features occur most frequently along the southern coast and the windward slope of the eastern mountainous area of Pearl River Delta, with the highest frequency occurring in June and the lowest in September among the 5 months. The spatial frequency distribution pattern also roughly matches the accumulated precipitation pattern. The occurrence of convection in this region also exhibits strong diurnal cycles. During May and June, the diurnal distribution is bimodal, with the maximum frequency occurring in the early afternoon and a secondary peak occurring between midnight and early morning. The secondary peak is much weaker in July, August, and September. Convection near the coast is found to occur preferentially on days when a southerly low-level jet (LLJ) exists, especially during the Meiyu season. Warm, moist, and unstable air is transported from the ocean to land by LLJs on these days, and the lifting along the coast by convergence induced by differential surface friction between the land and ocean is believed to be the primary cause for the high frequency along the coast. In contrast, the high frequency over mountainous area is believed to be due to orographic lifting of generally southerly flows during the warm season.

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Idealized numerical experiments on the microphysical evolution of warm‐type heavy rainfall

et al. 2017

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Recent satellite observations suggested that medium‐depth heavy rain systems (i.e., warm‐type heavy rainfall) were predominantly found in the Korean peninsula under moist‐adiabatically near neutral conditions in contrast to the traditional view that deep convection induced by convective instability produced heavy rainfall (i.e., cold‐type heavy rainfall). In order to examine whether a numerical model could explain the microphysical evolution of the warm‐type as well as cold‐type heavy rainfall, numerical experiments were implemented with idealized thermodynamic conditions. Under the prescribed humid and weakly unstable conditions, the warm‐type experiments resulted in a lower storm height, earlier onset of precipitation, and heavier precipitation than was found for the cold‐type experiments. The growth of ice particles and their melting process were important for developing cold‐type heavy rainfall. In contrast, the collision and coalescence processes between liquid particles were shown to be the mechanism for increasing the radar reflectivity toward the surface in the storm core region for the warm‐type heavy rainfall.

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Characteristics of Mesoscale Convective Systems over the East Part of Continental China during the Meiyu from 2001 to 2003

Cited by 30 publications

References 19 publications

Characteristics of Convections of Medium Depth to South of the Meiyu Front Analyzed by Using Numerical Simulation

Characteristics of Convections of Medium Depth to South of the Meiyu Front Analyzed by Using Numerical Simulation

Spatial and temporal characteristics of warm season convection over Pearl River Delta region, China, based on 3 years of operational radar data

Idealized numerical experiments on the microphysical evolution of warm‐type heavy rainfall

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