Spatio-Temporal Relationship between Land Cover and Land Surface Temperature in Urban Areas: A Case Study in Geneva and Paris

Xu Ge,Dasaraden Mauree,Jean-Louis Scartezzini,Roberto Castello

doi:10.3390/ijgi9100593

Xu Ge, Dasaraden Mauree + Show 2 more

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https://doi.org/10.3390/ijgi9100593

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Abstract

Currently, more than half of the world’s population lives in cities, which leads to major changes in land use and land surface temperature (LST). The associated urban heat island (UHI) effects have multiple impacts on energy consumption and human health. A better understanding of how different land covers affect LST is necessary for mitigating adverse impacts, and supporting urban planning and public health management. This study explores a distance-based, a grid-based and a point-based analysis to investigate the influence of impervious surfaces, green area and waterbodies on LST, from large (distance and grid based analysis with 400 m grids) to smaller (point based analysis with 30 m grids) scale in the two mid-latitude cities of Paris and Geneva. The results at large scale confirm that the highest LST was observed in the city centers. A significantly positive correlation was observed between LST and impervious surface density. An anticorrelation between LST and green area density was observed in Paris. The spatial lag model was used to explore the spatial correlation among LST, NDBI, NDVI and MNDWI on a smaller scale. Inverse correlations between LST and NDVI and MNDWI, respectively, were observed. We conclude that waterbodies display the greatest mitigation on LST and UHI effects both on the large and smaller scale. Green areas play an important role in cooling effects on the smaller scale. An increase of evenly distributed green area and waterbodies in urban areas is suggested to lower LST and mitigate UHI effects.

Highlights

The global urban population will increase from 4.2 billion in 2018 to 5 billion by 2030
Two scales have been explored: large (400 m × 400 m) and smaller (30 m × 30 m). Both in Paris and Geneva, the results confirm that the highest Land Surface Temperature (LST) was observed in the city center for all seasons
With different spatial distributions of impervious surface, a significantly positive correlation was observed between the mean LST and the impervious surface density in the two cities

Summary

Introduction

The global urban population will increase from 4.2 billion in 2018 to 5 billion by 2030. The ratio of urban-to-rural population is expected to increase to two-thirds (66.4%) by 2050, according to United Nations agencies [1]. The global urban land cover is expected to increase by 1,527,000 km by 2030 [2]. This will significantly impact the Land Surface Temperature (LST). LSTs are generally higher in urban areas compared to rural green area. This is due to the urban heat island effect, during the summer time, leading to an impact on energy consumption, air quality and human health [3]. A better understanding of the effects of the impervious surfaces and of green infrastructure on LST is necessary for mitigating adverse impacts and for supporting urban planning and public health management [4,5]

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Discussion

Conclusion