Temporal upscaling of surface urban heat island by incorporating an annual temperature cycle model: A tale of two cities

Satellite thermal remote sensing potentially provides a new way to monitor local climate change due to urbanization, especially changes in surface temperatures that result in the surface urban heat island (SUHI). However, this technique is restricted to clear-sky conditions. Because of this limitati...

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Veröffentlicht in:	Remote sensing of environment 2016-12, Vol.186, p.1-12
Hauptverfasser:	Huang, Fan, Zhan, Wenfeng, Voogt, James, Hu, Leiqiu, Wang, Zhihua, Quan, Jinling, Ju, Weimin, Guo, Zheng
Format:	Artikel
Sprache:	eng
Schlagworte:	Agglomeration Annual temperature cycle (ATC) Annual temperatures Case studies Cities Clear-sky SUHI climatology Climate Climate change Climate monitoring Climatology Daytime Diurnal Diurnal temperature range Environmental impact Land surface temperature Local climates Megacities Remote monitoring Remote sensing Satellites Spatiotemporal patterns Strategy Surface temperature Surface urban heat island (SUHI) Temperature Temperature effects Thermal environments Thermal remote sensing Urban heat islands Urbanization
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creator	Huang, Fan Zhan, Wenfeng Voogt, James Hu, Leiqiu Wang, Zhihua Quan, Jinling Ju, Weimin Guo, Zheng
description	Satellite thermal remote sensing potentially provides a new way to monitor local climate change due to urbanization, especially changes in surface temperatures that result in the surface urban heat island (SUHI). However, this technique is restricted to clear-sky conditions. Because of this limitation, satellite-derived land surface temperature (LST) records are frequently interrupted, sometimes even becoming temporally sparse and, accordingly, climatically less representative. Given this challenge, we propose a strategy that incorporates an annual temperature cycle (ATC) model to perform temporal upscaling of the SUHI from a climatic perspective. Using two megacities (Beijing and Shanghai) as case studies, our major findings include: (1) urbanization tends to enlarge the amplitude of annual daytime LST series for both cities; (2) urbanization in Beijing narrows the diurnal LST range on annual average but broadens it in Shanghai; (3) within an annual cycle, the daytime SUHI intensity (SUHII) reaches its maximum one month later than the daytime LST maximum for Beijing, whereas this time difference is negligible for Shanghai; and (4) compared with the observation-based and moving-window-based temporal aggregations, the ATC-based temporal aggregation allows to produce a clear-sky SUHI climatology that is more representative and becomes potentially valuable for prediction or application purposes. From a climatic perspective, the temporal upscaling of the SUHI, therefore, provides insights into the impacts on local thermal environments that are induced by urbanization. •A temporal upscaling concept is proposed to study SUHI.•A more representative climatology of clear sky SUHI is derived.•Urbanization tends to enlarge the amplitude of annual daytime LST series.•Urbanization-induced variation in diurnal LST range is city- and climate-related.
doi_str_mv	10.1016/j.rse.2016.08.009
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However, this technique is restricted to clear-sky conditions. Because of this limitation, satellite-derived land surface temperature (LST) records are frequently interrupted, sometimes even becoming temporally sparse and, accordingly, climatically less representative. Given this challenge, we propose a strategy that incorporates an annual temperature cycle (ATC) model to perform temporal upscaling of the SUHI from a climatic perspective. Using two megacities (Beijing and Shanghai) as case studies, our major findings include: (1) urbanization tends to enlarge the amplitude of annual daytime LST series for both cities; (2) urbanization in Beijing narrows the diurnal LST range on annual average but broadens it in Shanghai; (3) within an annual cycle, the daytime SUHI intensity (SUHII) reaches its maximum one month later than the daytime LST maximum for Beijing, whereas this time difference is negligible for Shanghai; and (4) compared with the observation-based and moving-window-based temporal aggregations, the ATC-based temporal aggregation allows to produce a clear-sky SUHI climatology that is more representative and becomes potentially valuable for prediction or application purposes. 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subjects	Agglomeration Annual temperature cycle (ATC) Annual temperatures Case studies Cities Clear-sky SUHI climatology Climate Climate change Climate monitoring Climatology Daytime Diurnal Diurnal temperature range Environmental impact Land surface temperature Local climates Megacities Remote monitoring Remote sensing Satellites Spatiotemporal patterns Strategy Surface temperature Surface urban heat island (SUHI) Temperature Temperature effects Thermal environments Thermal remote sensing Urban heat islands Urbanization
title	Temporal upscaling of surface urban heat island by incorporating an annual temperature cycle model: A tale of two cities
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