The Beijing extreme rainfall of 21 July 2012: “Right results” but for wrong reasons

Zhang, Da‐Lin; Lin, Yuh-Lang; Zhao, Ping; Xiaoding, Yu; Wang, Songqiu; Kang, Hongwen; Ding, Yihui

doi:10.1002/grl.50304

Cited by 149 publications

(104 citation statements)

References 18 publications

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“…The frequent occurrence of rainfall extremes produces multiple disasters, including urban flooding, server soil erosion, landslides and debris flows [1]. Moreover, rainfall extremes affect the ecological process of the terrestrial ecosystem [2,3].…”

Section: Introductionmentioning

confidence: 99%

Spatiotemporal Variations of Extreme Precipitation under a Changing Climate in the Three Gorges Reservoir Area (TGRA)

et al. 2018

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Abstract:The Three Gorges Dam (TGD) is one of the largest hydroelectric projects in the world. Monitoring the spatiotemporal distribution of extreme precipitation offers valuable information for adaptation and mitigation strategies and reservoir management schemes. This study examined variations in extreme precipitation over the Three Gorges Reservoir area (TGRA) in China to investigate the potential role of climate warming and Three Gorges Reservoir (TGR). The trends in extreme precipitation over the TGRA were investigated using the iterative-based Mann-Kendall (MK) test and Sen's slope estimator, based on weather station daily data series and TRMM (Tropical Rainfall Measuring Mission) data series. The mean and density distribution of extreme precipitation indices between pre-dam and post -dam, pre-1985 and post-1985, and near and distant reservoir area were assessed by the Mann-Whitney test and the Kolmogorov-Smirnov test. The ratio of extreme precipitation to non-extreme precipitation became larger. The precipitation was characterized by increases in heavy precipitation as well as decreases in light and moderate rain. Comparing extreme precipitation indices between pre-1985 (cooling) and post-1985 (warming) indicated extreme precipitation has changed to become heavier. Under climate warming, the precipitation amount corresponding to more than the 95th percentile increased at the rate of 6.48%/ • C. Results from comparing extreme precipitation for the pre-and post-dam, near reservoir area (NRA) and away from the reservoir area (ARA) imply an insignificant role of the TGR on rainfall extremes over the TGRA. Moreover, the impoundment of TGR did not exert detectable impacts on the surface relative humidity (RH) and water vapor pressure (WP).

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Section: Introductionmentioning

confidence: 99%

Spatiotemporal Variations of Extreme Precipitation under a Changing Climate in the Three Gorges Reservoir Area (TGRA)

et al. 2018

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“…On 21 July 2012, however, the heaviest daily total rainfall since 1976 occurred in Beijing and the adjacent areas. This rainstorm event had a regional average of 190.3 mm (far more than the climatological mean of 160.5 mm in July) in the Beijing area and an amount of 24 h accumulated 460 mm (nearly equal to the local annual precipitation of 542 mm) and an hourly rainfall above 85 mm in the western mountain area of Beijing [ Zhang et al ., ; Zhou et al ., ]. Some studies showed that this rainstorm consisted of two different stages: the first prefrontal heavy rainfall stage with topographical lifting, easterly winds in the local early afternoon, and northwesterly winds in the local evening; and the second frontal but relatively weak rainfall stage at night, as a large‐scale cold front approached Beijing [ Sun et al ., ; Zhang et al ., ].…”

Section: Introductionmentioning

confidence: 99%

“…This rainstorm event had a regional average of 190.3 mm (far more than the climatological mean of 160.5 mm in July) in the Beijing area and an amount of 24 h accumulated 460 mm (nearly equal to the local annual precipitation of 542 mm) and an hourly rainfall above 85 mm in the western mountain area of Beijing [ Zhang et al ., ; Zhou et al ., ]. Some studies showed that this rainstorm consisted of two different stages: the first prefrontal heavy rainfall stage with topographical lifting, easterly winds in the local early afternoon, and northwesterly winds in the local evening; and the second frontal but relatively weak rainfall stage at night, as a large‐scale cold front approached Beijing [ Sun et al ., ; Zhang et al ., ]. Because of its high impact and extreme rainfall event, several studies of this Beijing rainstorm have been published [e.g., Chen et al ., ; Sun et al ., ; Zhang et al ., ; Zhao et al , ; Du et al ., ; Jiang et al ., ; Ran et al ., ; Xu et al ., ].…”

Section: Introductionmentioning

confidence: 99%

An observational analysis of warm‐sector rainfall characteristics associated with the 21 July 2012 Beijing extreme rainfall event

Zhong

Mu²,

Zhang

et al. 2015

JGR Atmospheres

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An observational analysis of the multiscale processes leading to the extreme rainfall event in Beijing on 21 July 2012 is performed using rain gauge records, Doppler radar, and satellite products, radiosondes, and atmospheric analysis. This rainstorm process included two heavy rainfall stages in the early afternoon [1300-1400 Beijing Standard time (BST) (0500-0600 UTC)] and the evening (1600-1900 BST), respectively. The first stage exhibited warm-sector rainfall characteristics as it occurred under low-level warm and moist southeasterly flows ahead of a synoptic-scale vortex and a cold front. When the southeasterly flows turned northeastward along a southwest-northeast oriented mountain range in western Beijing, mesoscale convergence centers formed on the windward side of the mountain range in the early afternoon, initiating moist convection. Radar echo showed a northeastward propagation as these flows extended northward. Despite the shallowness of moist convection in the warm sector, atmospheric liquid water content showed the rapid accumulation, and a large amount of supercooled water and/or ice particles was possibly accumulated above the melting level. These appeared to contribute to the occurrence of the largest rainfall rate. During the second stage, as the synoptic-scale vortex moved across Beijing, with southeastward intrusion of its northwesterly flows, the vortex-associated lifting caused the generation of strong updrafts aloft and formed deep convection. This facilitated the further accumulation of supercooled water and/or ice particles above the melting level. Radar echo propagated southeastward. Liquid water showed a decrease in the lower troposphere, and there were strong downdrafts due to evaporation of liquid water particles, which resulted in the relatively weak hourly rainfall rates.

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“…But to what extent is this phenomenon caused by Beijing's rapid urbanization and land use change? A few studies have examined the causes and predictability of Rainstorm 721 [e.g., Zhang et al, 2013;Zhou et al, 2013;Sun et al, 2013], which together suggest that the convective cells were triggered by local topography and propagated with the large-scale weather system [Zhang et al, 2013;Sun et al, 2013]. These studies, however, have paid little attention to the possible impact of urbanization on this rainfall event.…”

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confidence: 99%

The possible impact of urbanization on a heavy rainfall event in Beijing

Liu

2015

JGR Atmospheres

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The impact of urbanization on a heavy rainfall event that occurred in Beijing on 21 July 2012 was investigated using version 3.6.1 of the Weather Research and Forecasting Model coupled with a multilayer urban canopy model. High-resolution land use data for Beijing in 2010 with modified urban parameterization were introduced into the model. Evaluation showed that the simulation result generally agreed well with observations. Two sensitivity tests with different urban high-resolution land use scenarios were employed to analyze the impact of urban expansion on this rainfall event. The simulation results confirmed that urbanization expansion played an important role in the distribution and intensity of precipitation for this extreme event. Urbanization led to total precipitation increasing in upstream and downstream directions. The start time of the precipitation process was advanced by 1 h, and the duration became longer due to the influence of urbanization. Moreover, urbanization caused the spatial distribution of precipitation to become more concentrated. The total precipitation amount above 250 mm and the frequency of precipitation intensity above 40 h À1 mm are both increased. The results of this study show that urbanization plays a significant role in frontal-type rainfall.

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The Beijing extreme rainfall of 21 July 2012: “Right results” but for wrong reasons

Cited by 149 publications

References 18 publications

Spatiotemporal Variations of Extreme Precipitation under a Changing Climate in the Three Gorges Reservoir Area (TGRA)

Spatiotemporal Variations of Extreme Precipitation under a Changing Climate in the Three Gorges Reservoir Area (TGRA)

An observational analysis of warm‐sector rainfall characteristics associated with the 21 July 2012 Beijing extreme rainfall event

The possible impact of urbanization on a heavy rainfall event in Beijing

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