Unveiling the Urban Impact on Mesoscale Convective System Rainfall in the Pearl River Delta Urban Agglomeration Under Typical Synoptic Backgrounds

Mesoscale convective systems (MCSs), the primary drivers of extreme rainfall over the Pearl River Delta (PRD) urban agglomeration, are strongly influenced by synoptic circulations and local geographical environments, including water bodies and topography. However, the urban impact on MCS rainfall un...

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Bibliographic Details
Published in:Journal of geophysical research. Atmospheres 2024-11, Vol.129 (21), p.n/a
Main Authors: Du, Xinguan, Chen, Haishan, Luo, Yali, Li, Qingqing, Feng, Zhe, Leung, L. Ruby
Format: Article
Language:English
Subjects:
Agglomeration
Breezes
Cities
Clustering
Coastal structures
Coastal zone
Convergence
Deltas
Extreme weather
Geographical distribution
Hazard identification
Heavy rainfall
mesoscale convective system
Mesoscale convective systems
Mesoscale phenomena
Monsoon circulation
Monsoons
Offshore
Precipitation
Rain
Rainfall
Rainfall anomalies
Rainfall distribution
Rivers
Rural areas
Sea breezes
Structural stability
Synergistic effect
synoptic background
Temporal variations
Thermal structure
Topographic effects
Topography
Tracking
urban agglomeration
Urban areas
urban heat island
Urban heat islands
Weather
Weather patterns
Wind
Wind effects
Winds
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Summary:Mesoscale convective systems (MCSs), the primary drivers of extreme rainfall over the Pearl River Delta (PRD) urban agglomeration, are strongly influenced by synoptic circulations and local geographical environments, including water bodies and topography. However, the urban impact on MCS rainfall under various synoptic backgrounds remain inadequately understood. Using a 20‐year high‐resolution MCS tracking database and self‐organizing map clustering, three typical backgrounds for MCSs, namely weak monsoon‐like, strong monsoon‐like, and low‐pressure system (Types‐1 to 3), impacting the PRD are identified. These backgrounds exhibit pronounced disparities in MCS tracks and temporal variations as well as rainfall distributions. Urban heat island (UHI) significantly alters the spatial patterns under Types‐1 and 2. Specifically, under weak UHI condition, MCS rainfall typically occurs offshore in the morning and shifts inland in the afternoon driven by the land‐sea breeze. However, UHI modifies the low‐level thermal structure, leading to anomalous convergence and instability, which causes morning rainfall to concentrate near coastal cities, while afternoon rainfall expands further inland to the northern rural region. Additionally, the strong southwesterly winds associated with Type‐2 enhance the interaction between topography and urban impact, resulting in even higher rainfall anomalies (+28.9%) over the northeastern region. The findings highlight the crucial role of urban impact and their synergistic effect with synoptic backgrounds and other land surface processes on MCSs. Plain Language Summary Mesoscale convective systems (MCSs) can bring heavy rainfall and pose great hazards to cities. This study aims to understand how large‐scale weather patterns and local urban processes influence MCSs. By analyzing a 20‐year MCS tracking database, we identify three typical weather backgrounds for MCSs impacting the Pearl River Delta urban agglomeration in south China. Each background shows distinct features regarding MCS behavior and rainfall spatial patterns. Furthermore, we find that the urban heat island (UHI) effect, where cities are warmer than the surrounding rural areas, can alter rainfall spatial patterns, particularly under backgrounds with monsoon‐like circulations. Results show that MCSs with weak UHI exhibit morning rainfall concentrated over coastal areas upwind of cities while afternoon rainfall shifts inland over downwind side, primarily driven by land‐sea
ISSN:2169-897X
2169-8996
DOI:10.1029/2024JD042409