Study of the Seasonal Effect of Building Shadows on Urban Land Surface Temperatures Based on Remote Sensing Data

Building shadows (BSs) frequently occur in urban areas, and their area and distribution display strong seasonal variations that significantly influence the urban land surface temperature (LST). However, it remains unclear how BSs affect the LST at the city scale because it is difficult to extract th...

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Bibliographic Details
Published inRemote sensing (Basel, Switzerland) Vol. 11; no. 5; p. 497
Main Authors Yu, Ke, Chen, Yunhao, Wang, Dandan, Chen, Zixuan, Gong, Adu, Li, Jing
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.03.2019
Subjects
building shadows
Buildings
Cooling
cooling effect
Cooling effects
Environmental impact
Heterogeneity
Kriging interpolation
Laboratories
Land cover
Land surface temperature
Land use
Landsat
Landsat satellites
Noise reduction
Pixels
Remote sensing
Satellites
seasonal variation
Shadows
Spatial discrimination
Spatial resolution
Statistical analysis
Studies
Temperature
Temperature gradients
Thermal environments
Urban areas
Vegetation
Volatility
Beijing China
China
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Summary:Building shadows (BSs) frequently occur in urban areas, and their area and distribution display strong seasonal variations that significantly influence the urban land surface temperature (LST). However, it remains unclear how BSs affect the LST at the city scale because it is difficult to extract the shaded area at the subpixel scale and to connect such areas with the LST at the pixel scale. In this study, we combined the sun angle, building height, building footprint and building occlusion to extract the seasonal spatial distribution of BSs in the central area of Beijing. The effect of BSs on the LST was analyzed using LST retrieved from Landsat-8 thermal infrared sensor data. First, the relationship between the LST patch fragmentation and proportion of BSs in the sample areas was modeled without vegetation. Then, we quantitatively studied the mitigated intensity of the LST in pure impervious surfaces (IS) and vegetation pixels covered by BSs; next, we analyzed the LST sensitivity of these pixels to BSs. The results showed that the existence of BSs influences the fragmentation of the low LST patches strongly from summer to winter. On the other hand, pure IS pixels totally covered by BSs experienced a greater cooling effect, with 3.16 K on 10 July, and the lowest cooling occurred between 14 and 25 December, with a mean of 1.24 K. Without considering the relationship in winter, the LST is nonlinearly correlated to the building shadows ratio (BSR) in pixels, and an approximate 10% increase in the BSR resulted in decreases in the LST of approximately 0.33 K (mean of 16 April and 10 May), 0.37 K (10 July) and 0.24 K (28 September) for pure IS pixels, and 0.18 K, 0.20 K and 0.15 K, respectively, for pure vegetation pixels. Further analysis indicates that the LST of pure IS pixels is more sensitive to BSs than that of vegetation because the self-regulation mechanism of vegetation reduces the cooling effect of BSs. These findings can help urban planners understand the cooling characteristics of BSs and design suitable urban forms to resist urban heat islands (UHIs).
ISSN:2072-4292
2072-4292
DOI:10.3390/rs11050497