Abstract
The extreme rainfall on 21 July 2012 is the heaviest rainfall that has occurred in Beijing since 1961. Observations and WRF (Weather Research and Forecasting) model are used to study the effect of MCS (mesoscale convective system) and topography on the rainfall. In this high-impact event, a quasi-stationary MCS developed in a favorable moist environment. The numerical simulation successfully reproduced the amount, location, and time evolution of the rainfall despite 4–6 h delay. In particular, the model reproduced the repeat passage of convective cells at the leading convergence line region along Taihang Mountains and the trailing stratiform region, producing the rainfall at nearly the right position. Results indicate the important roles of mesolow and low-level jet in maintaining the conditional instability that lifted the moist air to trigger deep convection and the repeated initiation and movement of the line shaped convective cells that produced the rainfall. The sensitive experiment was then further carried out to examine the effect of topography on this heavy rainfall. The reduction in model elevation field significantly influenced the above mesoscale systems, which lead to convective cells becoming less organized, and the peak rainfall amount in Beijing decreased by roughly 50%.
Highlights
Extreme rainfall is responsible for a variety of societal impacts, including flash flooding that can lead to damage, injury, and death [1]
The extreme rainfall occurring during 21 July 2012 is the heaviest rainfall event ever hitting Beijing since 1961
The WRF model is utilized in this study to simulate the development of this recorded torrential rainfall
Summary
Extreme rainfall is responsible for a variety of societal impacts, including flash flooding that can lead to damage, injury, and death [1]. If multiple convective cells repeatedly pass over the same area in rapid succession, extreme rainfall totals can occur [6]. This MCS organization that was commonly responsible for extreme rainfall was termed “back-building/quasi-stationary convection” (BB) by Schumacher and Johnson [5]. The modelpredicted rainfall results mainly from topographical lifting and the passage of a cold front, whereas the observed rainfall was mostly generated by convective cells Their results indicated that high resolution convection permitting models was required in order to predict the timing, distribution, and intensity of such an extreme event more accurately.
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