Urban heat island
The Urban Heat Island (UHI) effect is the term given to localised higher temperatures that are experienced in urban environments compared with the temperatures of surrounding green spaces (Akbari and Konopacki 2005).
The Urban Heat Island effect is primarily caused by the replacement of natural surfaces with hard impervious surfaces that are generally dark and absorb large amounts of solar radiation. Urban hard surfaces are significant in the built environment in the form of roads, paved areas, and roof tops (Getter, Rowe et al. 2007).
It is estimated that pavements and roofs account for 60% of urban surfaces, roofs 20-25% and pavements approximately 40% (Akbari, Menon et al. 2009). Presently these surfaces have relatively low albedo values (the fraction of incoming radiation reflected by a body) and high thermal conductivities, typically absorbing and re-radiating around 90% of the total incident solar radiation (Wolf and Lundholm 2008). This contributes to an Urban Heat Island effect that can result in a rise in summer temperatures of 4-7°C (CIBSE 2007; Wolf and Lundholm 2008) in comparison with adjacent vegetated areas.
This has a significant impact on thermal comfort in city environments. During a summer heatwave in the UK employers lost an estimated £168 million per day in productivity in one week (Roberts 2008).
In addition to this, heat islands are an energy efficiency concern due to increased air conditioning requirements which raise energy consumption, peak electricity demand and energy prices (Synnefa, Santamouris et al. 2007). Typically, electricity use in cities increases 2-4% for every temperature increase of one degree Celsius (Akbari, Pomerantz et al. 2001) . These costs are likely to increase further if global temperatures rise and increasing urbanisation makes the Urban Heat Island effect more significant.
Hotter urban environments will lead to an increase in the use of air conditioning. It follows that there will be a further increase in city temperatures from the dumping of heat from buildings heating ventilation and air conditioning (HVAC) systems and so more air cooling will be required (Takakura, Kitade et al. 2000). In other words, this process could be described as a vicious circle or negative reinforcing loop. There will also be an impact from increased emissions from cooling if this cooling is provided by fossil fuel based electricity. This will lead to an increased rate of global warming.
Successfully modelling the Urban Heat Island effect is an ongoing process. In the UK this research is looking at the effect in London and is been investigated by University College London (UCL). Their work under the LUCID project is looking at how to develop a Local Urban Climate Model and apply it to the Intelligent Design of Cities.
See also: Cool roofs.
NB The SuDS Manual (C753), published by CIRIA in 2015 refers to the reduction of the urban heat island effect as 'urban cooling'.
This article was originally created by --Buro Happold.
[edit] Related articles on Designing Buildings Wiki
- Albedo.
- Cool roofs.
- Emissivity.
- Green roofs.
- Green space.
- Overheating.
- Preventing overheating.
- Solar reflectance index.
- Smart cities.
- Solar shading.
- Sustainability.
- The benefits of urban trees.
- Thermal comfort.
- Thermal optical properties.
- Types of cool roofs.
[edit] External references
- The LUCID project.
- Akbari, H. and S. Konopacki (2005). "Calculating energy-saving potentials of heat-island reduction strategies." Energy Policy 33(6): 721-756.
- Akbari, H., S. Menon, et al. (2009). "Global cooling: increasing world-wide urban albedos to offset CO2." Climatic Change 94(3): 275-286.
- Akbari, H., M. Pomerantz, et al. (2001). "Cool surfaces and shade trees to reduce energy use and improve air quality in urban areas." Solar Energy 70(3): 295-310.
- CIBSE (2007). Green roofs. Plymouth.
- Erlandsson, M. and M. Borg (2003). Generic LCA-methodology applicable for buildings, constructions and operation services--today practice and development needs. 38: 919-938.
- Utilising green and bluespace to mitigate urban heat island intensity, Gunawardena et al., 2017.
- Getter, K. L., D. B. Rowe, et al. (2007). "Quantifying the effect of slope on extensive green roof stormwater retention." Ecological Engineering 31(4): 225-231.
- Roberts, S. (2008). "Effects of climate change on the built environment." Energy Policy.
- Synnefa, A., M. Santamouris, et al. (2007). "Estimating the effect of using cool coatings on energy loads and thermal comfort in residential buildings in various climatic conditions." Energy and Buildings 39(11): 1167-1174.
- Takakura, T., S. Kitade, et al. (2000). "Cooling effect of greenery cover over a building." Energy and Buildings 31(1): 1-6.
- Simulation pathway for estimating heat island influence on urban/suburban building space-conditioning loads and response to facade material changes. Gunawardena et al., 2019.
- Wolf, D. and J. T. Lundholm (2008). "Water uptake in green roof microcosms: Effects of plant species and water availability." Ecological Engineering 33(2): 179-186.
Featured articles and news
Private rental sector, living standards and fuel poverty
Report from the NRH in partnership with Impact on Urban Health.
.Cold chain condensing units market update
Tracking the evolution of commercial refrigeration unit markets.
Attending a conservation training course, personal account
The benefits of further learning for professsionals.
Restoring Alexander Pope's grotto
The only surviving part of his villa in Twickenham.
International Women's Day 8 March, 2025
Accelerating Action for For ALL Women and Girls: Rights. Equality. Empowerment.
Lack of construction careers advice threatens housing targets
CIOB warning on Government plans to accelerate housebuilding and development.
Shelter from the storm in Ukraine
Ukraine’s architects paving the path to recovery.
BSRIA market intelligence division key appointment
Lisa Wiltshire to lead rapidly growing Market Intelligence division.
A blueprint for construction’s sustainability efforts
Practical steps to achieve the United Nations Sustainable Development Goals.
Timber in Construction Roadmap
Ambitious plans from the Government to increase the use of timber in construction.
ECA digital series unveils road to net-zero.
Retrofit and Decarbonisation framework N9 launched
Aligned with LHCPG social value strategy and the Gold Standard.
Competence framework for sustainability
In the built environment launched by CIC and the Edge.
Institute of Roofing members welcomed into CIOB
IoR members transition to CIOB membership based on individual expertise and qualifications.
Join the Building Safety Linkedin group to stay up-to-date and join the debate.
Government responds to the final Grenfell Inquiry report
A with a brief summary with reactions to their response.
Comments
To start a discussion about this article, click 'Add a comment' above and add your thoughts to this discussion page.