Abstract
Land use/land cover (LULC) pattern change due to human activity is one of the key components of regional and global climate change drivers. Urban green space plays a critical role in regulating urban thermal environment, and its cooling effect has received widespread attention in urban heat island (UHI) related studies. To fully understand the effects of the landscape pattern of an urban green space in regulating the urban thermal environment, it is necessary to further study the thermal effects of the landscape pattern of the urban green space and its characteristics under varied spatial–temporal scales. In this paper, we took the urban core area of Hangzhou City as the study area and analyzed the relationships between the landscape metrics of the urban green space and land surface temperature (LST) under varied spatial scales by using correlation analysis and redundancy analysis (RDA) methods. Multi-temporal Landsat 8 thermal infrared sensor data were used to retrieve the spatial and temporal dynamics of LSTs in four consecutive seasons, and the land use classification was interpreted using SPOT (Systeme Probatoire d’Observation de la Terre) satellite imagery. The results showed that landscape dominance metrics—e.g., percentage of landscape (PLAND) and largest patch index (LPI)—were the most influential factors on urban LST. The spatial configuration of urban landscape, as represented by the fragmentation and aggregation and connectedness, also showed significant effects on LST. Furthermore, landscape pattern metrics had varied spatial scale effects on LST. Specifically, the landscape dominance metrics of urban forest showed an increased influence on LST as the spatial scale increased, while for urban water, the trend was opposite. These findings might have some practical significance for urban planning about how to spatially arrange urban green space to alleviate UHI at local and regional scales.
Highlights
The land use/land cover (LULC) pattern change due to human activity is one of the key forces of regional and global climate change [1,2,3,4], and large-scale urbanization causing changes in land surface composition and structure during the past decades has been a main factor in LULC [5,6]
The largest land surface temperature (LST) variation was found in summer (July) when the impervious surface and urban forest had the largest temperature difference compared with the other seasons
The mean LSTs of all the land uses were much closer in winter (December)
Summary
The land use/land cover (LULC) pattern change due to human activity is one of the key forces of regional and global climate change [1,2,3,4], and large-scale urbanization causing changes in land surface composition and structure during the past decades has been a main factor in LULC [5,6]. The changed evapotranspiration and thermal inertia [7,8,9] of the land surface unit, together with the heat produced by human activities during energy consumption [10,11], will increase the surface temperature of the urban area, and this is the so-called urban heat island (UHI) effect [12,13,14]. Urban green space is critical in regulating the urban thermal environment and improving the local microclimate of the urban area, and its cooling effect has received widespread attention in UHI-related studies [19,20,21]. The spatial layout of urban green patches and non-green patches is of great significance for the regulation of microclimate at urban or regional scales [35,36]
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