Does urbanization increase diurnal land surface temperature variation? Evidence and implications

The diurnal land surface temperature (LST) variation is a primary characteristic of the effects of urbanization. However, no study to date has focused on changes in diurnal LST variation in urban environments. This paper investigates the effects of urbanization on landscape pattern and diurnal LST v...

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Bibliographic Details
Published in:Landscape and urban planning 2016
Main Authors: Chen, Yen-Ching, Hao-Wei Chiu, Yuan-Fong Su, Yii-Chen Wu, Ke-Sheng Cheng
Format: Article
Language:English
Subjects:
absorption
adverse effects
Diurnal land surface temperature variation
diurnal variation
green roofs
heat
land cover
Landscape changes
landscapes
moderate resolution imaging spectroradiometer
parks
Remote sensing
surface temperature
urban areas
urbanization
Urbanization index
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Summary:The diurnal land surface temperature (LST) variation is a primary characteristic of the effects of urbanization. However, no study to date has focused on changes in diurnal LST variation in urban environments. This paper investigates the effects of urbanization on landscape pattern and diurnal LST variation of Taipei City, using MODIS thermal images and SPOT multispectral remote sensing images over the 1994–2010 period. Supervised land-cover classifications were conducted to investigate decadal land-cover changes within the study area. A remote-sensing-based urbanization index was adopted as a quantitative measure of urbanization-induced changes in landscape patterns. Diurnal LST variations were assessed using MODIS Aqua satellite images. We found that the diurnal LST variation increases with the urbanization index, with the adverse effects of urbanization on the diurnal LST variation being more substantial in the earlier stages of urbanization. Increasing diurnal LST variation due to urbanization implies that urbanization is likely to result in a greater increase in urban heat absorption than in thermal inertia. This research provides insightful supporting evidence that measures that can reduce urban heat absorption such as urban parks, community green spaces, green roofs and cool (or permeable) pavements should be given higher priority in mitigating UHI effects.
ISSN:0169-2046
1872-6062