Abstract
Globally, the urban heat island (UHI) effect is a major problem which leads to urban residents suffering from adverse urban ecological environments and serious health risks. Understanding the impacts of urban landscape features on the thermal environment has been an important focus across various fields of research. The purpose of this study is to analyze the impacts of urban heat source–sink landscape patterns on urban heat islands, using the fast-growing Zhengzhou City in central China as the case study. Landsat data (captured in 1996, 2006, and 2014), various geospatial approaches, and correlation analysis were applied to facilitate the analysis. Based on the contributions of the urban landscape to land surface temperature (LST), we empirically identified the heat sources and heat sinks. Then, the composition and configurations of heat source and sink landscapes were estimated by a series of spatial metrics at the landscape and class levels. The results showed that the overall mean land surface temperature (LST) in the study area increased by 2.72 °C from 1996 to 2014. This observed increasing trend in overall mean LST is consistent with the process of rapid urbanization in the study area, which was evidenced by the dramatic increase in impervious surfaces and the substantial loss in vegetation cover. Generally, as observed, landscape composition has a stronger influence on LST than does landscape configuration. For heat sources, the proportion, size, aggregation, and density of patches have positive effects on LST, while adjusting the spatial distribution and abundance of urban landscape are effective ways to control the UHI effects. In contrast, the percentage, size, density, and aggregation of heat sink patches have negative effects on LST. Additionally, the effects of increasing total patch edges and shape complexity should be considered when mitigating the UHI effect. These findings are beneficial for furthering our understanding of how urban landscape patterns affect UHI, and they can help optimize urban landscape patterns to alleviate the UHI effect and enhance sustainable development in the study area.
Highlights
Rapid urbanization changes the features of natural land surfaces into impervious surfaces [1,2], and these landscape changes are a direct consequence of sharp urban development [3,4]
There are still few surface urban heat island (UHI) studies that have investigated the impacts of landscape composition and configuration on land surface temperature (LST); the previous literature based on conventional land use/land cover (LULC) classification methods failed to consider the effects of other factors of the landscape pattern, such as patch density, patch shape, and patch configuration, which increase the uncertainties in exploring the relationship between landscape pattern and UHI [5]
This study investigated the spatiotemporal variation of LST in Zhengzhou City, China between 1996 and 2014 using thermal remote sensing and geospatial approaches
Summary
Rapid urbanization changes the features of natural land surfaces into impervious surfaces [1,2], and these landscape changes are a direct consequence of sharp urban development [3,4]. The relationship between landscape pattern and LST has received considerable attention, and many previous studies have extensively presented and estimated the effects of land use/land cover (LULC) characteristics on LST [18,19,20,21,22], especially between LST and the abundance and spatial patterns of vegetation and impervious surfaces [23,24,25]. These studies have found that impervious surface has the largest contribution to LST; in contrast, vegetated landscapes are generally beneficial and decrease LST [2,26].
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