The Influence of Typhoon Events on the Design Storm for the Shanghai Metropolitan Area in the Yangtze River Delta, China

Given the fact that the high frequency of extreme weather events globally, in particular typhoons, has more of an influence on flood forecasting, there is a great need to further understand the impact of typhoon events on design storms. The main objectives of this paper are to examine the magnitude,...

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Bibliographic Details
Published inWater (Basel) Vol. 16; no. 3; p. 508
Main Authors Jin, Yuting, Liu, Shuguang, Zhou, Zhengzheng, Zhuang, Qi, Liu, Min
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.02.2024
Subjects
Analysis
China
Climate change
design storm
Extreme weather
Flood forecasting
Floods
Landslides & mudslides
metropolitan region
Precipitation
Rain
Rain and rainfall
Rivers
South China Sea
stochastic storm transposition
Storms
the Yangtze River Delta
typhoon
Typhoons
Urban areas
South China Sea
China
Yangtze River Delta
Yangtze River
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Summary:Given the fact that the high frequency of extreme weather events globally, in particular typhoons, has more of an influence on flood forecasting, there is a great need to further understand the impact of typhoon events on design storms. The main objectives of this paper are to examine the magnitude, occurrence, and mechanism of typhoon events in southeast coastal China and their contribution to the design storm study. We take Shanghai, which is a typical metropolitan region in the Yangtze River Delta, China, as an example. The impact of typhoons on the rainfall frequency analysis is quantitatively evaluated using stochastic storm transposition (SST)-based intensity–duration–frequency (IDF) estimates with various temporal and spatial structures under different return periods. The results show that there is significant variability in the storm magnitude within the transposition domain across different durations, highlighting the spatiotemporal heterogeneity over the coastal area. Moreover, the probability of random storm transposition exhibits an uneven distribution. The frequency of typhoon rainfall events within the transposition domain is notably high, and there is considerable variability in the structure of rainfall. Typhoon rainfall amplifies the intensity of design storms, and its contribution increases with return periods. The variability in design storms increases accordingly. Based on the advantages of SST, which retains the spatiotemporal structure of the rainfall in the generated scenarios, the overall framework provides an effective way to examine the impact of diverse characteristics of typhoon rainfall on frequency analysis and facilitate a deeper exploration of the direct impact of various types of extreme storms on the intensity, spatial, and temporal distributions of design storms amidst evolving environmental conditions over this metropolitan region.
ISSN:2073-4441
2073-4441
DOI:10.3390/w16030508