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Tree surface temperature in an urban environment

Leuzinger, Sebastian and Vogt, Roland and Körner, Christian. (2010) Tree surface temperature in an urban environment. Agricultural and forest meteorology, Vol. 150, Nr. 1. pp. 52-62.

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Official URL: http://edoc.unibas.ch/dok/A5252668

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Abstract

Trees are essential in a dense urban environment not only because of their aesthetic value, but also for their cooling effect during hot periods, which impacts directly on the local microclimate. However, certain trees cope better with high urban temperatures than others. Here, we report tree crown temperatures of 10 common tree species frequently planted in Central European cities (in part, supplemented with stomatal conductance data, gs). Parts of the city of Basel, Switzerland (7°410E/47°340N) were scanned from a helicopter using a high-resolution thermal camera. A histogram of the composite image shows peaks at 18 °C (water), 26 °C (vegetation), 37 °C (streets) and a less obvious one at 45 °C (roofs). At an ambient temperature of c. 25 °C, tree crown temperatures ranged from c. 24 °C (Aesculus hippocastanum trees located in a park) to 29 °C in Acer platanoides trees, located in a street. Trees in parks were significantly cooler (c. 26 °C) than trees surrounded by sealed ground (c. 27 °C). The only coniferous species, Pinus sylvestris did not vary in temperaturewith location (park or street) and exhibited foliage temperature close to air temperature. Generally, small-leaved trees remained cooler than large-leaved trees. Stomatal conductance data collected during similar weather conditions suggest that there was no bias in crown temperatures due to locally different water supply between trees. Although the highest leaf temperatures of individuals of A. platanoides reached over 5 K leaf-to-air temperature difference (dT(L-A)), we do not expect temperature stress to occur in these conditions. In order to estimate possible effects of future temperature extremeson dT(L-A),we evaluated the leaf energy balance fora range of stomatal responses and air temperatures, using leaf size, wind speed and the measured species-specific leaf boundary layer resistance. At an ambient temperature of 40 °C, View the MathML source ranged from 2 to 5 K when gs was assumed to drop linearly to 50% of its maximum value. When gs was compromised further (20% of species-specific maxima), the difference in View the MathML source between species became larger with rising ambient temperature (range 4–10 K). Those species with the lowest leaf temperatures at 25 °C were not necessarily coolest at 40 °C. Species-specific differences in View the MathML source under extreme temperatures as shown here may be useful for urban tree planning in order to optimise management cost and human comfort. Untersuchungsgebiet Basel
Faculties and Departments:05 Faculty of Science > Departement Umweltwissenschaften > Ehemalige Einheiten Umweltwissenschaften > Pflanzenökologie (Körner)
05 Faculty of Science > Departement Umweltwissenschaften > Ehemalige Einheiten Umweltwissenschaften > Meteorologie (Parlow)
UniBasel Contributors:Körner, Christian and Vogt, Roland
Item Type:Article, refereed
Article Subtype:Research Article
Publisher:Elsevier
ISSN:0168-1923
Note:Publication type according to Uni Basel Research Database: Journal article
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Last Modified:22 Mar 2012 14:26
Deposited On:22 Mar 2012 13:55

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