The relationships between urban-rural temperature difference and vegetation in eight cities of the Great Plains

Interpreting the relationship between urban heat island (UHI) and urban vegetation is a basis for understanding the impacts of underlying surfaces on UHI. The calculation of UHI intensity (UHII) requires observations from paired stations in both urban and rural areas. Due to the limited number of pa...

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Veröffentlicht in:	Frontiers of earth science 2019-06, Vol.13 (2), p.290-302
Hauptverfasser:	CUI, Yaoping, XIAO, Xiangming, DOUGHTY, Russell B, QIN, Yaochen, LIU, Sujie, LI, Nan, ZHAO, Guosong, DONG, Jinwei
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Sprache:	eng
Schlagworte:	air temperature background climate Cities Cloud cover Earth and Environmental Science Earth Sciences Evapotranspiration Land surface temperature Research Article Rural areas Urban areas urban cold island Urban heat islands urbanization Vegetation
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creator	CUI, Yaoping XIAO, Xiangming DOUGHTY, Russell B QIN, Yaochen LIU, Sujie LI, Nan ZHAO, Guosong DONG, Jinwei
description	Interpreting the relationship between urban heat island (UHI) and urban vegetation is a basis for understanding the impacts of underlying surfaces on UHI. The calculation of UHI intensity (UHII) requires observations from paired stations in both urban and rural areas. Due to the limited number of paired meteorological stations, many studies have used remotely sensed land surface temperature, but these time-series land surface temperature data are often heavily affected by cloud cover and other factors. These factors, together with the algorithm for inversion of land surface temperature, lead to accuracy problems in detecting the UHII, especially in cities with weak UHII. Based on meteorological observations from the Oklahoma Mesonet, a world-class network, we quantified the UHII and trends in eight cities of the Great Plains, USA, where data from at least one pair of urban and rural meteorological stations were available. We examined the changes and variability in urban temperature, UHII, vegetation condition (as measured by enhanced vegetation index, EVI), and evapotranspiration (ET). We found that both UHI and urban cold islands (UCI) occurred among the eight cities during 2000-2014 (as measured by impervious surface area). Unlike what is generally considered, UHII in only three cities significantly decreased as EVI and ET increased ( p
doi_str_mv	10.1007/s11707-018-0729-5
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We found that both UHI and urban cold islands (UCI) occurred among the eight cities during 2000-2014 (as measured by impervious surface area). Unlike what is generally considered, UHII in only three cities significantly decreased as EVI and ET increased ( p<0.1), indicating that the UHI or UCI cannot be completely explained simply from the perspective of the underlying surface. Increased vegetative cover (signaled by EVI) can increase ET, and thereby effectively mitigate the UHI. 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Earth Sci</addtitle><description>Interpreting the relationship between urban heat island (UHI) and urban vegetation is a basis for understanding the impacts of underlying surfaces on UHI. The calculation of UHI intensity (UHII) requires observations from paired stations in both urban and rural areas. Due to the limited number of paired meteorological stations, many studies have used remotely sensed land surface temperature, but these time-series land surface temperature data are often heavily affected by cloud cover and other factors. These factors, together with the algorithm for inversion of land surface temperature, lead to accuracy problems in detecting the UHII, especially in cities with weak UHII. Based on meteorological observations from the Oklahoma Mesonet, a world-class network, we quantified the UHII and trends in eight cities of the Great Plains, USA, where data from at least one pair of urban and rural meteorological stations were available. 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subjects	air temperature background climate Cities Cloud cover Earth and Environmental Science Earth Sciences Evapotranspiration Land surface temperature Research Article Rural areas Urban areas urban cold island Urban heat islands urbanization Vegetation
title	The relationships between urban-rural temperature difference and vegetation in eight cities of the Great Plains
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