Using green infrastructure for urban climate-proofing : An evaluation of heat mitigation measures at the micro-scale
(2016) In Urban Forestry and Urban Greening 20. p.305-316- Abstract
Urban green infrastructure (UGI) has been increasingly promoted as a key measure to mitigate heat stress in cities caused by the urban heat island effect and climate change impacts, including climate variability and extremes. However, comparable information concerning the performance of different UGI types to moderate such impacts is mostly lacking. This creates serious challenges for urban planners who need to decide on the most effective measures while considering spatial and administrative constraints. This study investigates how different types and quantities of UGI, i.e. trees, green roofs, and green facades, affect pedestrian thermal comfort. The study was applied to high-density residential areas under current and future climatic... (More)
Urban green infrastructure (UGI) has been increasingly promoted as a key measure to mitigate heat stress in cities caused by the urban heat island effect and climate change impacts, including climate variability and extremes. However, comparable information concerning the performance of different UGI types to moderate such impacts is mostly lacking. This creates serious challenges for urban planners who need to decide on the most effective measures while considering spatial and administrative constraints. This study investigates how different types and quantities of UGI, i.e. trees, green roofs, and green facades, affect pedestrian thermal comfort. The study was applied to high-density residential areas under current and future climatic conditions. Climate change will on average increase afternoon Physiological Equivalent Temperature (PET) values by 2.4 K; however, this could be vastly reduced by different UGI scenarios. Planting trees had the strongest impact with an average PET reduction of 13% compared with existing vegetation. Trees shade open spaces and provide evapotranspirative cooling. Another valuable adaptation option is green facades, which have mitigating effects of 5%–10%. In contrast, the effects of green roofs were negligible. Our results indicate that increasing the share of green cover did not directly correspond to the magnitude of the PET reduction. Placing vegetation strategically in heat-exposed areas is more effective than just aiming at a high percentage of green cover. We conclude that our extensive comparative analysis provides empirical evidence to support UGI on the micro-scale and assists planners and decision-makers to effectively select and prioritise concrete measures to adapt to climate change.
(Less)
- author
- Zölch, Teresa ; Maderspacher, Johannes ; Wamsler, Christine LU and Pauleit, Stephan
- organization
- publishing date
- 2016-12-01
- type
- Contribution to journal
- publication status
- published
- subject
- keywords
- Climate change adaptation, Ecosystem services, ENVI-met modelling, Naturebased solutions, Thermal comfort
- in
- Urban Forestry and Urban Greening
- volume
- 20
- pages
- 12 pages
- publisher
- Elsevier
- external identifiers
-
- wos:000391471000034
- scopus:84991491187
- ISSN
- 1618-8667
- DOI
- 10.1016/j.ufug.2016.09.011
- language
- English
- LU publication?
- yes
- id
- 89a21186-a84e-4b7b-b1bb-5446e2483102
- date added to LUP
- 2016-10-28 08:29:15
- date last changed
- 2024-09-07 23:27:33
@article{89a21186-a84e-4b7b-b1bb-5446e2483102, abstract = {{<p>Urban green infrastructure (UGI) has been increasingly promoted as a key measure to mitigate heat stress in cities caused by the urban heat island effect and climate change impacts, including climate variability and extremes. However, comparable information concerning the performance of different UGI types to moderate such impacts is mostly lacking. This creates serious challenges for urban planners who need to decide on the most effective measures while considering spatial and administrative constraints. This study investigates how different types and quantities of UGI, i.e. trees, green roofs, and green facades, affect pedestrian thermal comfort. The study was applied to high-density residential areas under current and future climatic conditions. Climate change will on average increase afternoon Physiological Equivalent Temperature (PET) values by 2.4 K; however, this could be vastly reduced by different UGI scenarios. Planting trees had the strongest impact with an average PET reduction of 13% compared with existing vegetation. Trees shade open spaces and provide evapotranspirative cooling. Another valuable adaptation option is green facades, which have mitigating effects of 5%–10%. In contrast, the effects of green roofs were negligible. Our results indicate that increasing the share of green cover did not directly correspond to the magnitude of the PET reduction. Placing vegetation strategically in heat-exposed areas is more effective than just aiming at a high percentage of green cover. We conclude that our extensive comparative analysis provides empirical evidence to support UGI on the micro-scale and assists planners and decision-makers to effectively select and prioritise concrete measures to adapt to climate change.</p>}}, author = {{Zölch, Teresa and Maderspacher, Johannes and Wamsler, Christine and Pauleit, Stephan}}, issn = {{1618-8667}}, keywords = {{Climate change adaptation; Ecosystem services; ENVI-met modelling; Naturebased solutions; Thermal comfort}}, language = {{eng}}, month = {{12}}, pages = {{305--316}}, publisher = {{Elsevier}}, series = {{Urban Forestry and Urban Greening}}, title = {{Using green infrastructure for urban climate-proofing : An evaluation of heat mitigation measures at the micro-scale}}, url = {{http://dx.doi.org/10.1016/j.ufug.2016.09.011}}, doi = {{10.1016/j.ufug.2016.09.011}}, volume = {{20}}, year = {{2016}}, }