Abstract
Urbanization has been both a cause of global warming and a victim of it through the urban heat island effect. The main reason for global warming is enhanced greenhouse emissions in the atmosphere. At the same time, Iran, as one of main global producers of greenhouse gasses, has witnessed rapid urbanization and a dramatic increase in energy use. There may be a link here that needs further investigation to see whether urban design can be used to prevent cities being major producer of greenhouse gasses. Cities are a source of this growth in greenhouse gases mainly because of transportation and energy use in the building sector. In the past, urbanization did not produce this increase in energy use, suggesting modern urbanization is in complete contrast with traditional urban and architectural design principles. Climatic design has always been one of the most important principles of traditional architecture in Iran. Different climate zones have inspired traditional architecture, creating design solutions that made cities and buildings livable for people. This paper sets out how a passion for modernization and the subsequent rapid urbanization have changed the structure of Iranian cities and made them producers of greenhouse gasses and energy consumers. The paper discusses how adaptation and mitigation strategies are crucial countermeasures against urban warming, and how currently these remain completely neglected in urban planning and urban design processes in Iran. Finally, the paper concludes by describing how urban designers could intervene to achieve realistic improvements in Iranian urbanization.
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Bokaie, M., et al.: Assessment of urban heat island based on the relationship between land surface temperature and land use/land cover in Tehran. Sustain. Cities Soc. 23, 94–104 (2016)
Canadell, J., et al.: The human perturbation of the carbon cycle. The Global Carbon Cycle-2 (2009)
Watkins, R., Palmer, J., Kolokotroni, M.: Increased temperature and intensification of the urban heat island: implications for human comfort and urban design. Built Environ. 33(1), 85–96 (2007)
Dessai, S.: Heat stress and mortality in Lisbon Part II. An assessment of the potential impacts of climate change. Int. J. Biometeorol. 48(1), 37–44 (2003)
Grasso, M.: An ethical approach to climate adaptation finance. Glob. Environ. Change 20(1), 74–81 (2010)
Thomas, D.S., Twyman, C.: Equity and justice in climate change adaptation amongst natural-resource-dependent societies. Glob. Environ. Change 15(2), 115–124 (2005)
Cooper, J.: Fail to Prepare, then Prepare To Fail: Rethinking Threat, Vulnerability, and Mitigation in the Precolumbian Caribbean. Surviving Sudden Environmental Change. Answers from Archaeology, pp. 91–114. University Press of Colorado, Boulder (2012)
Prospectus, W.U. (2003). http://www.un.org/esa/population/publications/wup2003/2003WUPHighlights.pdf. Accessed 2008
Yumino, S., et al.: Total assessment for various environmentally conscious techniques from three perspectives: mitigation of global warming, mitigation of UHIs, and adaptation to urban warming. Sustain. Cities Soc. 19, 236–249 (2015)
Alcoforado, M.J., Andrade, H.: Global warming and the urban heat island. In: Urban Ecology, pp. 249–262 (2008)
Iran, S.C.o. (2014). https://www.amar.org.ir/english/Databases-Systems/ICPD. Accessed 2017
Mollahosseini, A., et al.: Renewable energy management and market in Iran: a holistic review on current state and future demands. Renew. Sustain. Energy Rev. 80(Suppl. C), 774–788 (2017)
Fanni, Z.: Cities and urbanization in Iran after the Islamic revolution. Cities 23(6), 407–411 (2006)
Kousari, M.R., Asadi Zarch, M.A.: Minimum, maximum, and mean annual temperatures, relative humidity, and precipitation trends in arid and semi-arid regions of Iran. Arab. J. Geosci. 4(5), 907–914 (2011)
Modarres, R., Sarhadi, A.: Rainfall trends analysis of Iran in the last half of the twentieth century. J. Geophys. Res. Atmos. 114(D3), n/a (2009)
Hafeznia, H., Pourfayaz, F., Maleki, A.: An assessment of Iran’s natural gas potential for transition toward low-carbon economy. Renew. Sustain. Energy Rev. 79(Suppl. C), 71–81 (2017)
Nejat, P., et al.: A global review of energy consumption, CO2 emissions and policy in the residential sector (with an overview of the top ten CO2 emitting countries). Renew. Sustain. Energy Rev. 43(Suppl. C), 843–862 (2015)
Soflaei, F., Shokouhian, M., Zhu, W.: Socio-environmental sustainability in traditional courtyard houses of Iran and China. Renew. Sustain. Energy Rev. 69(Suppl. C), 1147–1169 (2017)
Keyhani, A., et al.: An assessment of wind energy potential as a power generation source in the capital of Iran, Tehran. Energy 35(1), 188–201 (2010)
Stocker, T., et al.: IPCC, 2013: summary for policymakers in climate change 2013: the physical science basis, contribution of working group I to the fifth assessment report of the intergovernmental panel on climate change. Cambridge University Press, Cambridge (2013)
Varzaneh, E.H., Amini, M., Bemanian, M.R.: Impact of hot and arid climate on architecture (case study: Varzaneh Jame Mosque). Procedia Eng. 94, 25–32 (2014)
Roaf, S.: Wind Catchers, Living with the Desert. Airs & Philips, London (1982)
Eiraji, J., Namdar, S.A.: Sustainable systems in Iranian traditional architecture. Procedia Eng. 21(Suppl. C), 553–559 (2011)
Motealleh, P., Zolfaghari, M., Parsaee, M.: Investigating climate responsive solutions in vernacular architecture of Bushehr city. HBRC J. (2016)
Keshtkaran, P.: Harmonization between climate and architecture in vernacular heritage: a case study in Yazd, Iran. Procedia Eng. 21, 428–438 (2011)
Soleymanpour, R., Parsaee, N., Banaei, M.: Climate comfort comparison of vernacular and contemporary houses of Iran. Procedia Soc. Behav. Sci. 201, 49–61 (2015)
Kamal, M.A., Al Shehab, T.: Sustainability through natural cooling: bioclimatic design and traditional architecture. Stud. Civ. Eng. Archit. (2014)
FORM, E.I.T.B., Climatic responsiveness in traditional built form of Lucknow. New Architecture and Urbanism: Development of Indian Traditions, p. 201 (2010)
Abrahamian, E.: A History of Modern Iran. Cambridge University Press, Cambridge (2008)
Habibi, R., De Meulder, B.: Architects and ‘architecture without architects’: modernization of Iranian housing and the birth of a new urban form Narmak (Tehran, 1952). Cities 45, 29–40 (2015)
Marefat, M.: Building to power: architecture of Tehran 1921–1941. Massachusetts Institute of Technology (1988)
Hamin, E.M., Gurran, N.: Urban form and climate change: balancing adaptation and mitigation in the US and Australia. Habitat Int. 33(3), 238–245 (2009)
Ewing, R., et al.: Growing Cooler: The Evidence on Urban Development and Climate Change, p. 814. Urban Land Institute (2007)
Habitat, U.: Cities and climate change: Global report on human settlements 2011. Earthscan, London (2011)
Madanipour, A.: Tehran: The Making of a Metropolis. Academy Press, London (1998)
Zamani, B., Arefi, M.: Iranian new towns and their urban management issues: a critical review of influential actors and factors. Cities 30, 105–112 (2013)
Environment, D.o. (2018). www.doe.ir. Accessed 2018
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Shabahang, S., Vale, B., Gjerde, M. (2019). The Problem of the Modern Built Environment and Enhanced Urban Warming in Iran. In: Kaparaju, P., Howlett, R., Littlewood, J., Ekanyake, C., Vlacic, L. (eds) Sustainability in Energy and Buildings 2018. KES-SEB 2018. Smart Innovation, Systems and Technologies, vol 131. Springer, Cham. https://doi.org/10.1007/978-3-030-04293-6_33
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