Abstract
Trees play a vital role in urban cooling. The present study tested if key canopy characteristics related to tree shade could be used to predict the cooling potential across a range of urban surface materials. During the austral summer of 2018–2019, tree and canopy characteristics of 471 free-standing trees from 13 species were recorded across Greater Sydney, Australia. Stem girth and tree height, as well as leaf area index and ground-projected crown area was measured for every tree. Surface temperatures were recorded between noon (daylight saving time) and 3:00 p.m. under the canopy of each tree in the shade and in full sun to calculate the temperature differential between adjacent sunlit and shaded surfaces (∆Ts). The limited control over environmental parameters was addressed by using a large number of randomly selected trees and measurement points of surface temperatures. Analyses revealed that no systematic relationship existed among canopy characteristics and ∆Ts for any surface material. However, highly significant differences (p < 0.001) in ∆Ts existed among surface materials. The largest cooling potential of tree shade was found by shading bark mulch (∆Ts = −24.8 °C ± 7.1), followed by bare soil (∆Ts = −22.1 °C ± 5.5), bitumen (∆Ts = −20.9 °C ± 5.8), grass (∆Ts = −18.5 °C ± 4.8) and concrete pavers (∆Ts = −17.5 °C ± 6.0). The results indicate that surface material, but not the tree species, matters for shade cooling of common urban surfaces. Shading bark mulch, bare soil or bitumen will provide the largest reductions in surface temperature, which in turn results in effective mitigation of radiant heat. This refined understanding of the capacity of trees to reduce thermal loads in urban space can increase the effectiveness of urban cooling strategies.
Highlights
The Urban Heat Island Effect (UHIE) is one of the most prominent impacts of urbanisation and is accelerated by climate change [1,2]
There is no doubt that tree shade reduces the amount of heat absorbed by the surface underneath during the daytime; our study provided evidence that microclimate underneath the trees and the temperature of surface material greatly depends on the type of surface material
This study gave a novel insight into the relationship between surface temperature and canopy characteristics
Summary
The Urban Heat Island Effect (UHIE) is one of the most prominent impacts of urbanisation and is accelerated by climate change [1,2]. The UHIE can be defined as the discernible temperature difference between urban and adjacent rural areas caused by emission of excess heat and the solar energy trapped by infrastructure [3]. Mitigation of urban heat has become a pressing issue as more than half of the world’s population is currently living in cities [4], where they are exposed to increased levels of heat that, during heat wave conditions, adversely impact public health and accelerate rates of mortality [4]. Increased night-time temperatures in urban settings are mainly caused by buildings and paved areas with low albedo and high heat storage capacity [7]. Buildings and paved areas are made from concrete, asphalt, bricks and tiles, which absorb short-wave solar radiation during daytime and re-radiate long-wave radiation in the night, thereby increasing air temperatures at night
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