Abstract
The urban heat island effect (UHI) for inner land regions was investigated using satellite data, ground observations, and simulations with an Single-Layer Urban Canopy Parameterization (SLUCP) coupled into the regional Weather Research Forecasting model (WRF, http://wrf-model.org/index.php). Specifically, using the satellite-observed surface skin temperatures (Tskin), the intensity of the UHI was first compared for two inland cities (Xi’an City, China, and Oklahoma City (OKC)), which have different city populations and building densities. The larger population density and larger building density in Xi’an lead to a stronger skin-level UHI by 2 °C. However, the ground observed 2 m surface air temperature (Tair) observations showed an urban cooling island effect (UCI) over the downtown region in OKC during the daytime of 19 July 2003, from a DOE field campaign (Joint Urban 2003). To understand this contrast between satellite-based Tskin and ground-based Tair, a sensitivity study using WRF/SLUCP was analyzed. The model reproduced a UCI in OKC. Furthermore, WRF/Noah/SLUCM simulations were also compared with the Joint Urban 2003 ground observations, including wind speeds, wind directions, and energy fluxes. Although the WRF/SLUCM model failed to simulate these variables accurately, it reproduced the diurnal variations of surface temperatures, wind speeds, wind directions, and energy fluxes reasonably well.
Highlights
Earth, as a physical system, is balanced by incoming energy and outgoing energy
Weather Research and Forecasting (WRF)/Noah/Single-Layer Urban Canopy Model (SLUCM) simulations were compared with the Joint Urban 2003 ground observations, including wind speeds, wind directions, and energy fluxes
This study aimed to analyze the physical process of the urban heat island effect (UHI)/urban cooling island effect (UCI) as well as determine whether the WRF/Single-Layer Urban Canopy Model (SLUCM) simulation can successfully reproduce the UHI/UCI
Summary
As a physical system, is balanced by incoming energy and outgoing energy. For an equilibrium climate, the mean global absorbed solar shortwave radiation is balanced by the outgoing long-wave radiation. In the Earth system, 19% of the incoming solar radiation is absorbed in the atmosphere, 30% is lost to space, and 51% is absorbed at the surface. This last component of the incoming radiation, along with the outgoing sensible and latent heat fluxes, is the main contributor to the surface skin temperature [1,2]. Surface temperatures retrieved from satellite observations are called “surface skin temperature (Tskin )” [3]. Tskin represents the ground temperature when the underlying surface below the satellite is bare soil, or represents the canopy top temperature when the underlying surface is forest. Tskin is the mixed signal of building tops, building walls, streets, Climate 2017, 5, 72; doi:10.3390/cli5030072 www.mdpi.com/journal/climate
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