Abstract
In this study, an extreme rainstorm that occurred in the Beijing–Tianjin–Hebei (BTH) region in China on 19–20 July 2016 is simulated and analyzed using the Weather Research and Forecasting model, coupled with a multilayer urban canopy scheme, to reveal the impact of urbanization on the extreme precipitation process in the region. The results show that the urban heat island effect (that is, surface warming and an increased near-ground sensible heat flux, which leads to increased vertical motion and atmospheric instability layer strengthening) plays a dominant role in the urban modification of rainfall during the early stages of urbanization, resulting in an increase of 6–10 mm in average hourly precipitation in urban and downwind areas. With the further development of urbanization in the BTH region, particularly in the big cities of Beijing and Tianjin, the large-scale expansion of the urban surface reduces the surface moisture, the evaporation of surface water from the ground, and the height of the atmospheric boundary layer, leading to an urban dry island effect brought about by the lack of near-surface water vapor, which inhibits an increase in precipitation. The positive effect of the urban heat island on precipitation was offset by the urban dry island effect, so the increase in precipitation in the urban areas was not obvious, but an increased range of 8–10 mm was noted. The existence of large cities changes the position of the strong upward movement of air, and convective upward movement is more likely to occur between the suburbs. With the further expansion of the underlying surface of the adjacent cities of Beijing and Tianjin, the upward movement between the two cities coincides, leading to an obvious increase in precipitation between the two cities.
Highlights
In recent decades, with the development of urbanization in China, especially the formation of urban clusters, the energy balance and dynamic–thermodynamic characteristics of urban areas have changed, and these changes have corresponding effects on the regional atmospheric planetary boundary layer, atmospheric circulation, and climate
With the rapid development of urbanization, extreme precipitation in the BTH region has become more frequent, and heavy rainfall continues to have an important impact on the formation of urban flooding [1]
This study used the Weather Research and Forecasting (WRF)/BEP model with three different land-use maps to simulate a heavy precipitation event that occurred in the BTH region on 19‒20 July 2016
Summary
With the development of urbanization in China, especially the formation of urban clusters, the energy balance and dynamic–thermodynamic characteristics of urban areas have changed, and these changes have corresponding effects on the regional atmospheric planetary boundary layer, atmospheric circulation, and climate. With the rapid development of urbanization, extreme precipitation in the BTH region has become more frequent, and heavy rainfall continues to have an important impact on the formation of urban flooding [1]. Studying the development mechanism of rainstorm systems in the BTH region under the influence of urbanization is of great scientific significance and has practical application value for improving the forecasting of heavy rainfall in the rapidly urbanizing BTH region, especially heavy rain that causes urban flooding. Urban areas absorb more solar radiation during the day, some of which is stored as geothermal energy. The increase in temperature produces a thermal disturbance in the pressure and wind fields, which enhances the instability of the atmosphere
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