Climate regulation provided by urban greening - examples from a high latitude city
Abstract
Cities exert a strong influence on urban climate, and consequently on human health and wellbeing. This
increases the importance of considering climate issues in urban planning, particularly in the context of global
climate change. One of the key adaptation strategies in climate-sensitive planning is urban greenery. The
purpose of this thesis is to increase understanding of how urban greenery influences the air temperature and
outdoor thermal comfort in a high latitude city. The thesis consists of three main parts. In the first part the aim
is to describe the urban greenery at various scales in terms of the amount of foliage. In the second part
different aspects of the cooling effect of urban vegetation and the resulting intra-urban thermal variations are
discussed. Finally, the last part deals with the modelling of mean radiant temperature (Tmrt), an important
parameter governing human thermal comfort, in vegetated urban areas.
The thesis is based on extensive meteorological and plant physiological measurements conducted in
Gothenburg, Sweden. Study sites ranged from single street trees to parks and woodlands. Moreover, a LiDAR
dataset and high resolution digital surface models (DSMs) of ground, buildings and vegetation were used to
analyse spatial characteristics of the study sites, including effective leaf area index (Le) describing tree foliage,
and sky view factor (SVF), a measure of obstruction of sky commonly used in urban climate studies.
The results show substantial variations in Le between different types of urban greenery, with the highest
Le observed in an urban woodland and the lowest in residential green yards. These variations were accurately
modelled using LiDAR data. However, when averaged over large areas only partly covered by trees, variations
in Le were found to result mostly from tree fraction rather than structural characteristics of tree canopies.
Single urban trees of five common species were shown to provide a strong shading effect throughout the year,
with a potentially positive effect on thermal comfort in summer and negative in winter in high latitude cities.
Parameterisation of transmissivity of solar radiation through tree crowns significantly improved the modelling
of Tmrt in SOLWEIG, a model simulating radiation fluxes in complex urban environments.
While tree transpiration in temperate climates is often assumed negligible in darkness, night-time transpiration
was observed in all of seven common tree species, and data analyses indicated its contribution to the evening
cooling on clear, calm nights of the warm season.
The cooling effect of trees due to both shading and transpiration was found to be influenced by tree growing
conditions and access to sunlight. Trees growing on wide grass lawns had denser crowns and higher stomatal
conductance than those surrounded by impervious surfaces. When provided with good growing conditions,
sun-exposed trees can strongly influence microclimate by providing additional shade and by intensive
transpiration.
Parks exhibited a cooler microclimate than built-up sites throughout the day and year, and in different weather
conditions, with the strongest cooling effect on clear, calm days of the warm season. While the evening
cooling in a high latitude city is best correlated with SVF, spatial characteristics describing buildings and
vegetation proved useful in the analysis of intra-urban thermal variations. When high resolution DSMs are not
available, near-infrared hemispherical photography can be used to calculate SVFs accounting for the
obstruction of sky by buildings and trees separately.
The findings presented in this thesis can be used in climate-sensitive planning, in urban climate modelling as
well as in valuation of ecosystem services provided by urban greenery.
Parts of work
I. Klingberg J, Konarska J, Lindberg F, Johansson E, Thorsson S (2015) Mapping leaf area
of urban greenery in a high latitude city using aerial LiDAR and ground-based
measurements. Submitted to Urban Forestry and Urban Greening II. Konarska J, Lindberg F, Larsson A, Thorsson S, Holmer B (2014) Transmissivity of
solar radiation through crowns of single urban trees—application for outdoor thermal
comfort modelling. Theoretical and Applied Climatology 117:363-376. ::doi::10.1007/s00704-013-1000-3 III. Konarska J, Uddling J, Holmer B, Lutz M, Lindberg F, Pleijel H, Thorsson S (2015)
Transpiration of urban trees and its cooling effect in a high latitude city. International
Journal of Biometeorology. In press. ::doi::10.1007/s00484-015-1014-x IV. Konarska J, Holmer B, Lindberg F, Thorsson S (2015) Influence of vegetation and
building geometry on the spatial variations of air temperature and cooling rates in a high
latitude city. International Journal of Climatology. In press. ::doi::10.1002/joc.4502 V. Konarska J, Klingberg J, Lindberg F (2015) Identifying vegetation in near-infrared
hemispherical photographs – potential applications in urban climatology and urban
forestry. Manuscript
Degree
Doctor of Philosophy
University
Göteborgs universitet. Naturvetenskapliga fakulteten
Institution
Department of Earth Sciences ; Institutionen för geovetenskaper
Disputation
27 November 2015, 10:00, Stora Hörsalen, Geovetarcentrum, Guldhedsgatan 5c
Date of defence
2015-11-27
janina.konarska@gvc.gu.se
Date
2015-11-06Author
Konarska, Janina
Keywords
Gothenburg
Sweden
high latitude city
urban greenery
urban trees
leaf area index
tree transpiration
sky view factor
mean radiant temperature
hemispherical photography
climate-sensitive planning
Publication type
Doctoral thesis
ISBN
978-91-628-9646-1
ISSN
1400-3813
Series/Report no.
A
156 2015
Language
eng