A Subtropical Oceanic Mesoscale Convective Vortex Observed during SoWMEX/TiMREX

Lai, Hsiao-Wei; Davis, Christopher A.; Jou, Ben Jong‐Dao

doi:10.1175/2010mwr3411.1

Cited by 23 publications

(26 citation statements)

References 55 publications

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“…Atmosphere 2017, 8,116 10 of 15 reached 70 mm, and the corresponding lifted condensation pressures were 972 and 954 hPa, respectively. Moreover, the dew temperature was very close to the temperature below 500 hPa, and the wind shear was relatively small.…”

Section: The Extra Llj and Unstable Stratificationmentioning

confidence: 98%

“…Atmosphere 2017, 8,116 3 of 15 duration of heavy rainfall with 13 h of hourly rainfall exceeding 20 mm. Figure 2 also shows that the surface temperature increased during the daytime before the occurrence of heavy rainfall and reached 34 °C at 1100 UTC on 19 May at station G1827.…”

Section: Overviewmentioning

confidence: 99%

“…WSTRs caused by the easterly reflux, especially the strong southwest monsoon burst, are directly influenced by low-level processes in the PBL [3]. WSTRs could be triggered by other mesoscale processes within the PBL caused by the mesoscale convective system (e.g., [4][5][6]) and the mesoscale vortex [7][8][9], as well as orographic effects [10][11][12].…”

Section: Introductionmentioning

confidence: 99%

“…Atmosphere 2017, 8,116 14 of 16 vertical profile in the PBL, as well as a better estimation of the precipitation, whereas the YSU scheme underestimated the precipitation and the AMT values. (2) The AMT, extending from the Beibu Gulf and the South China Sea to the coastal areas and providing Shanwei with considerable amounts of moisture in the boundary layer, was one of the important large-scale factors causing the WSTR.…”

mentioning

confidence: 99%

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The Impacts of Atmospheric Moisture Transportation on Warm Sector Torrential Rains over South China

Zhong

Chen

2017

Atmosphere

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Warm Sector Torrential Rains (WSTRs) occurring during the outbreak of the monsoon in May of 2015 in South China were studied using surface automatic weather observational data, sounding, European Centre for Medium-Range Weather Forecasts Reanalysis interim Data (ERA-interim), satellite and radar data, and a four-level nested grid simulation with the finest grid spacing of 1 km using the Weather Research and Forecasting model (WRF). The results show that the extreme precipitation event, which had maximum rainfall amounts of 406.3 mm in 10 h and 542.2 mm in 24 h on 20 May 2015, and was characterized by its rapid development and its highly concentrated and long duration of heavy rainfall, occurred over the trumpet-shaped topography of Haifeng. The simulation results indicated that the South China Sea (SCS) atmospheric moisture transportation (AMT) was crucial in triggering the precipitation of the WSTR over South China. The simulation of the WSTR was conducted by using the total energy-mass flux scheme (TEMF), which provided a reasonable simulation of the circulation and the vertical profile in the Planetary Boundary Layer (PBL) as well as the estimation of the precipitation. The AMT, which extends from the Beibu Gulf and the South China Sea to the coastal areas and provides Shanwei with a considerable amount of moisture in the boundary layer, and the effects within the PBL, which include orographic effects, an extra low-level jet, and a high-energy tongue characterized by a high-potential pseudo-equivalent temperature tongue with a warm and moist southwesterly wind, were the important large-scale factors causing the WSTR.

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Section: The Extra Llj and Unstable Stratificationmentioning

confidence: 98%

Section: Overviewmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

mentioning

confidence: 99%

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The Impacts of Atmospheric Moisture Transportation on Warm Sector Torrential Rains over South China

Zhong

Chen

2017

Atmosphere

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“…Previous studies have investigated the intensification of pre-existing convective systems on the Central Mountain Range (CMR; width, 120 km; length, 320 km; height, 4 km; extending southwestÁnortheast) of Taiwan (an isolated elliptically shaped terrain), under southwesterly monsoon flows dominant at low altitudes during the rainy season (May to mid-June) (Chen and Yu, 1988;Chen et al, 1991;Jou and Deng, 1992;Akaeda et al, 1995;Chen et al, 2001;Wang et al, 2005;Lai et al, 2011). Wang et al (2005) investigated the enhancement mechanisms of a northÁsouth elongated pre-existing rainfall system approaching the northwestern side of the CMR with low Fr.…”

Section: Introductionmentioning

confidence: 99%

Effect of an isolated elliptical terrain (Jeju Island) on rainfall enhancement in a moist environment

Lee¹,

Uyeda²,

Lee³

2014

Tellus A: Dynamic Meteorology and Oceanography

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A B S T R A C T A series of idealised experiments using a cloud-resolving storm simulator (CReSS) was performed to investigate the effects of the isolated elliptically shaped terrain of Jeju Island (oriented eastÁwest), southern Korea, on the enhancement of pre-existing rainfall systems under the influence of prevailing southwesterly moist flows. Control parameters were the low-altitude wind speed (Froude numbers: 0.2, 0.4, 0.55) and the initial location of the elongated (oriented northÁeast) rainfall system (off the northwestern or western shores of the island). Simulations were conducted for all combinations of initial location and wind regime. Overall, results indicate that weak southwesterlies flowing around the steep mountain on the island (height, 2 km) generate two local convergences, on the northern lateral side and on the lee side of the island, both in regions of moist environments, thus producing conditions favourable for enhanced rainfall. As an eastward-moving rainfall system approaches the northwestern shore of the island, the southwesterlies at low altitudes accelerate between the system and the terrain, generating a local updraft region that causes rainfall enhancement onshore in advance of the system's arrival over the terrain. Thus, the prevailing southwesterlies at low altitudes that are parallel to the terrain are a crucial element for the enhancement. Relatively weak southwesterlies at low altitudes allow system enhancement on the lee side by generating a convergence of relatively weak go-around northwesterlies from the northern island and relatively strong moist southwesterlies from the southern island, thus producing a relatively long-lived rainfall system. As the southwesterlies strengthen, a dry descending air mass intensifies on the northeastern downwind side of the terrain, rapidly dissipating rainfall and resulting in a relatively short-lived rainfall system. A coexisting terrain-generated local convergence, combined with the absence of dry descending air on the downwind side of the terrain, prolongs the lifetime of the rainfall system.

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Convective intensity, vertical precipitation structures, and microphysics of two contrasting convective regimes during the 2008 TiMREX

Zipser

2015

JGR Atmospheres

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This study investigates the convective/microphysical properties and precipitation structures of seven rainfall events in southwest Taiwan during the 2008 Terrain-influenced Monsoon Rainfall Experiment (TiMREX). TiMREX heavy rainfall events (>50 mm d À1 ) are characterized by upstream low-level jets, unstable upstream conditions, and a nearly moist neutral stratification within the heavy rain region. Three heavy rainfall events (2, 5, and 16 June) have only weak to moderate convection and little lightning; e.g., less than 10% of their rainfall is associated with intense convective cells (maximum 40 dBZ height > 8 km). Polarimetric radar measurements indicate that large precipitation-size ice particles well above the freezing level (5 km) are rare in these events. Their vertical profiles of radar reflectivity (VPRR) decrease rapidly above the 0°C level but increase downward below that level. These VPRRs are believed to be associated with weak updrafts and active warm-rain collision and coalescence processes at low levels with raindrops falling through the updraft. In contrast, the 14 June heavy rainfall event is more intense, is ice-based, and exhibits continental characteristics; e.g., 60% of its rainfall is contributed by active thunderstorms (>10 flashes min À1 ). This and other intense storms (26 May and 13 June) have robust lightning (>500 strikes h À1) and pronounced radar reflectivity in the mixed-phase region, indicating strong updrafts and vigorous ice-based processes. Significant amounts of large graupel/small hail are present in the mixed-phase region of these events. Furthermore, their VPRRs decrease or stay constant downward below the freezing level.

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A Subtropical Oceanic Mesoscale Convective Vortex Observed during SoWMEX/TiMREX

Cited by 23 publications

References 55 publications

The Impacts of Atmospheric Moisture Transportation on Warm Sector Torrential Rains over South China

The Impacts of Atmospheric Moisture Transportation on Warm Sector Torrential Rains over South China

Effect of an isolated elliptical terrain (Jeju Island) on rainfall enhancement in a moist environment

Convective intensity, vertical precipitation structures, and microphysics of two contrasting convective regimes during the 2008 TiMREX

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