تأثیر ویژگی‌های شهری بر غلظت دی‌اکسید نیتروژن و شدت جزیره گرمایی شهری مطالعه موردی: کلان‌شهر تهران

نوع مقاله : مقاله کامل

نویسندگان

گروه جغرافیا، دانشکده علوم انسانی و اجتماعی، دانشگاه مازندران، بابلسر، ایران

10.22059/jphgr.2025.394256.1007882

چکیده

آلودگی هوا و جزیره گرمایی شهری (UHI) متأثر از رشد سریع جمعیت و گسترش شهرها در شهرهایی مانند تهران تشدید شده است. این مطالعه رابطه بین ویژگی‌های شهریِ مناطق ساخته‌شده، ارتفاع ساختمان و پوشش گیاهی و شدت UHI و غلظت دی‌اکسید نیتروژن (NO2) را به‌عنوان یک آلاینده کلیدی شهری بررسی می‌کند. مناطق ساخته‌شده و ارتفاع ساختمان از داده‌های GHSL و پوشش گیاهی با استفاده از شاخص NDVI از طریق تصاویر Sentinel-2 استخراج شدند. محصول MOD11A2 برای شب (22:30) باقدرت تفکیک 1000 متر به‌منظور اندازه‌گیری اثر UHI در سال‌های 2018 تا 2022 استفاده شد و غلظت NO₂ از سنجنده TROPOMI در ماهواره Sentinel-5 برای سال‌های 2019 تا 2024 به دست آمد. پردازش و تجزیه‌وتحلیل داده‌ها از طریق سامانه Google Earth Engine همچنین با بهره‌گیری از ضریب همبستگی پیرسون انجام شد. نتایج نشان داد هر یک از ویژگی‌های مناطق ساخته‌شده و ارتفاع ساختمان‌ها با ضریب (45/0 و 18/0)R² رابطه‌ای مستقیم و معناداری با غلظت NO₂ دارند و توسعه شهری، افزایش قابل‌توجهی در انتشار NO₂ خواهد داشت. همبستگی مستقیمی بین پوشش گیاهی و NO₂ با ضریب (097/0)R² مشاهده شد که به توپوگرافی تهران و تجمع آلاینده در مناطق با پوشش گیاهی زیاد نسبت داده شد. همچنین نتایج این پژوهش آشکار کرد که، ارتباط مستقیم و معناداری بین مناطق ساخته‌شده و ارتفاع ساختمان‌ها با UHI با ضریب (45/0 و 18/0)R² در تهران وجود دارد که نقش این ویژگی‌ها را در شکل‌گیری و تشدید پدیده جزیره گرمایی برجسته می‌کند. همچنین، این مطالعه نشان داد که رابطه معکوس (اگرچه از نظر آماری معنادار نیست) بین تراکم پوشش گیاهی و اثر جزیره گرمایی وجود دارد که نشان می‌دهد پوشش گیاهی می‌تواند نقش تعدیل‌کننده‌ای در کاهش شدت جزیره گرمایی ایفا کند..

کلیدواژه‌ها

موضوعات

عنوان مقاله [English]

Impact of Urban Characteristics on Nitrogen Dioxide Concentration and Urban Heat Island Intensity: A case study of Tehran

نویسندگان [English]

  • Taher Safarrad
  • Mohammadreza Miandej
Department of Geography, Faculty Humanities and Social Sciences, University of Mazandaran, Babolsar, Iran
چکیده [English]

ABSTRACT
Air pollution and the Urban Heat Island (UHI) effect have become critical challenges in megacities such as Tehran, particularly as a result of rapid population growth and ongoing urban expansion. This study investigates the relationship between key urban characteristics, including built-up areas, building height, and vegetation cover, and UHI intensity as well as nitrogen dioxide (NO₂) concentration, which represents a major urban air pollutant. Data on built-up areas and building height were obtained from the Global Human Settlement Layer (GHSL), while vegetation cover was mapped using the Normalized Difference Vegetation Index (NDVI) derived from Sentinel-2 imagery. UHI intensity was assessed using nighttime MOD11A2 land surface temperature products acquired at 22:30 with a spatial resolution of 1000 m for the period 2018 to 2022, while NO₂ concentrations were retrieved from the TROPOMI sensor onboard Sentinel-5 for the period 2019 to 2024. All data processing and analysis were conducted using the Google Earth Engine platform, with Pearson correlation analysis applied to examine the relationships among variables. The findings reveal significant positive correlations between both built-up areas and building height and NO₂ concentration (R² = 0.45 and 0.18, respectively), indicating that urban growth substantially contributes to increased NO₂ levels. A weaker positive correlation was observed between vegetation cover and NO₂ concentration (R² = 0.097), which is attributed to Tehran’s topographic conditions and the accumulation of pollutants in certain densely vegetated areas. The results also indicate strong positive associations between built-up areas and building height and UHI intensity (R² = 0.45 and 0.18), highlighting their significant role in intensifying urban heat island effects. Although the relationship was not statistically significant, an inverse association was observed between vegetation density and UHI intensity, suggesting that vegetation may play a mitigating role in reducing urban heat intensity. Overall, this study underscores the strong influence of urban morphology on both air quality and thermal dynamics, while highlighting vegetation as a potential strategy for moderating UHI intensity in rapidly growing cities such as Tehran.
Extended Abstract
Introduction
Urbanization exerts increasing pressure on environmental resources and has adverse effects on air and water quality, land availability, and local climatic conditions. Urban areas play a substantial role in the emission of greenhouse gases and, at the same time, are highly vulnerable to the impacts of climate change, including global warming and sea-level rise. Urban development alters surface radiation balance and moisture regimes, leading to changes in land use patterns and biogeochemical cycles. The present study examines the relationship between urban structural characteristics, including built-up areas, building height, and vegetation cover, and their effects on the Urban Heat Island (UHI) phenomenon and nitrogen dioxide (NO₂) emissions in Tehran. By employing multiple remote sensing datasets, this research seeks to provide an integrated assessment of urban structure, air quality, and urban heat island intensity.
 
Methodology
This study employs datasets from the Global Human Settlement Layer (GHSL) to assess the physical characteristics of the urban environment, with particular emphasis on the Global Built-up Surface dataset for quantifying built-up areas and the building height dataset for estimating building heights. These datasets are readily accessible through the Google Earth Engine (GEE) platform. Vegetation cover characteristics were extracted using the Normalized Difference Vegetation Index (NDVI) derived from Sentinel-2 satellite imagery. To address differences in spatial resolution and sample size, the study area, namely the city of Tehran, was divided into a uniform grid with a spatial resolution of 1000 × 1000 m. Within each grid cell, key variables were calculated, including Urban Heat Island (UHI) intensity, nitrogen dioxide (NO₂) concentration, mean building height, total built-up area, and vegetation cover. Subsequently, the relationships between urban physical characteristics and both UHI intensity and NO₂ concentration were analyzed using Pearson correlation coefficients. This methodological framework enables a systematic assessment of the interactions between urban structure, urban heat island characteristics, and air pollution at a consistent spatial scale.
 
Result and Discussion
Urban Heat Island in Tehran
During the study period from 2018 to 2022, the highest mean annual temperature in Tehran was recorded in 2022 at 17.7 °C, while the lowest mean annual temperature was observed in 2020 at 15.3 °C. In the suburban areas of Tehran, the highest average temperature reached 12.8 °C in 2022, whereas the lowest value of 10.7 °C was recorded in 2019. Seasonal analysis indicates that temperatures within the urban core of Tehran consistently exceed those of the surrounding suburban areas throughout the year, confirming the persistent presence of the Urban Heat Island (UHI) phenomenon.
UHI intensity in Tehran exhibits clear seasonal variability, reaching its maximum value of 5.2 °C during the winter months and decreasing to approximately 4.3 °C during the summer. Notably, the UHI effect intensifies during colder seasons, a pattern that can largely be attributed to increased anthropogenic activities, particularly the extensive use of heating systems in urban areas. In 2021, when the mean urban temperature declined to 14.9 °C, central districts, especially Districts 10 and 11, exhibited elevated temperature levels, with an average UHI intensity of 4.4 °C. This spatial concentration of higher temperatures highlights the influence of dense urban morphology and intensified human activities on local climatic conditions in Tehran.
Nitrogen Dioxide (NO₂) Concentration in Tehran
Analysis of nitrogen dioxide (NO₂) concentrations in Tehran from 2018 to 2024 indicates that Districts 7 and 8 consistently experienced the highest average NO₂ levels, whereas Districts 19 and 20 recorded the lowest concentrations. The highest overall NO₂ concentration was observed in 2021, while the lowest levels occurred during 2018 and 2019. The peak in NO₂ concentration in 2021 may be associated with post–COVID-19 pandemic conditions. Although reductions in vehicular traffic and industrial activities during lockdown periods in 2019 and 2020 likely contributed to lower emission levels, the subsequent resumption of economic activities in 2021 appears to have led to a renewed increase in pollutant emissions.
Seasonal analysis further reveals that NO₂ concentrations peak during December and January, coinciding with winter temperature inversion events that trap pollutants near the ground surface. In contrast, NO₂ levels reach their minimum between April and September, a period characterized by enhanced atmospheric dispersion and reduced emission intensity. In particular, April shows a marked decrease in NO₂ concentrations compared to March, which may reflect reduced urban and industrial activities during the Nowruz holiday period.
 
Conclusion
The results of this study indicate that the Urban Heat Island (UHI) in Tehran exhibits a distinct seasonal pattern, intensifying during the winter months as a result of increased fossil fuel consumption and weakening during the summer. In addition, UHI intensity decreases markedly during weekends and official holidays, such as Thursdays and Fridays, coinciding with reduced industrial activity, a pattern that is consistent with findings reported in previous studies. Further analysis reveals a statistically significant relationship between UHI intensity and urban physical characteristics, particularly built-up areas and building height. These urban forms contribute to heat accumulation, whereas increased vegetation cover is associated with a moderating effect on urban temperatures.
Similarly, nitrogen dioxide (NO₂) emissions follow a seasonal pattern comparable to that of the UHI, reaching peak levels in winter due to intensified urban and industrial activities and declining during periods of reduced activity. Correlation analysis indicates strong associations between NO₂ concentration and built-up density, building height, and vegetation cover. Specifically, areas characterized by higher building density and taller structures exhibit elevated NO₂ levels, while areas with greater vegetation cover are associated with lower concentrations. These findings underscore the critical role of urban morphology in shaping thermal and atmospheric conditions in urban environments and highlight the importance of vegetation in mitigating urban heat and air pollution.
 
Funding
There is no funding support.
 
Authors’ Contribution
All of the authors approved thecontent of the manuscript and agreed on all aspects of the work.
 
Conflict of Interest
Authors declared no conflict of interest.
 
Acknowledgments
We are grateful to all the scientific consultants of this paper.

کلیدواژه‌ها [English]

  • Nitrogen Dioxide
  • Urban Heat Island
  • Remote Sensing
  • Tehran

مراجع

  1. آروین، عباسعلی. (1397). بررسی جزیره گرمایی در ارتباط با آلودگی هوا در شهر اصفهان. جغرافیا و مخاطرات محیطی، 7(1)، 129-115. https://doi.org/10.22067/geo.v7i1.64590
  2. شمسی‌پور، علی‌اکبر؛ مهدیان ماه فروزی، مجتبی؛ اخوان، هانیه و حسین پور، زینب. (1391). واکاوی رفتار روزانه جزیرة گرمایی شهر تهران. محیط‌شناسی، 38(63)، 56-45.    doi: 10.22059/jes.2013.298
  3. صفرراد, طاهر. (1400). تحلیل تغییرات زمانی شدت جزیره گرمایی شبانه شهر تهران. پژوهش‌های تغییرات اقلیمی،2 (8)، 55-65 doi: 10.30488/ccr.2021.319317.106,
  4. صلاحی، برومند؛ فروتن، مهدی و پاسبان، امیر حسام .(1403). واکاوی ارتباط آلودگی‌های مناطق شهری با جزایر حرارتی شهرستان اردبیل. جغرافیا و روابط انسانی، 6(4)، 954-940. doi: 10.22034/gahr.2024.445528.2058
  5. عزیزی، قاسم؛ شمسی‌پور، علی‌اکبر؛ مهدیان ماه فروزی، مجتبی و میری، مرتضی. (1392). تأثیرپذیری شدت جزیرة گرمایی شهری تهران از الگوهای همدیدی جو. محیط‌شناسی، 39 (4)، 65-55.  doi: 10.22059/jes.2014.36462.
  6. فلاحتی, فرشاد؛ حیدری سورشجانی، رسول و گنجی، محمد. (1402). تأثیر کالبد شهری بر فرهنگ شهروندی با رویکرد توسعه پایدار شهری در شهرهای کاشان و یاسوج. جغرافیای اجتماعی شهری، 10(1)، 124-103. doi: 10.22103/JUSG.2023.2091
  7. فیض‌اله پور، مهدی. (1402). برآورد دمای سطح زمین (LST) و مقایسه آن با شاخص‌های NDMI، NDWI و NDVI به‌منظور بررسی تنش آبی با تأکید بر تغییرات کاربری اراضی (LULC) در سیستم ماشین بردار پشتیبانی (SVM) (منطقه موردمطالعه: تالاب انزلی. تحلیل فضایی مخاطرات محیطی، 10 (2)، 148-131. http://dx.doi.org/10.61186/jsaeh.10.2.131
  8. مرکز آمار ایران، 1395
  9. مسعودیان، سید ابوالفضل و منتظری، مجید. (1399). رفتار زمانی - مکانی جزیره گرمایی کلان‌شهر اصفهان. مخاطرات محیط طبیعی، 9 (24)، 46-35. https://doi.org/10.22111/jneh.2019.28437.1493
  10. نوربخش، مهرداد و نظری‌نژاد، امیر. (1401). بررسی ارتباط شاخص‌های پوشش گیاهی NDVI و EVI با دمای سطح زمین در شهر تهران. جغرافیا و روابط انسانی، 1 (5)، 236-225. https://dor.isc.ac/dor/20.1001.1.26453851.1401.5.1.12.1
  11. Arvin, A. (2018). Investigation of the urban heat island in relation to air pollution in Isfahan city. Geography and Environmental Hazards, 7(1), 115–129. https://doi.org/10.22067/geo.v7i1.64590 [In Persian]
  12. Azizi, Q., Shamsipour, A. A., Mahdian Mahfrozi, M., & Miri, M. (2013). The influence of synoptic atmospheric patterns on the intensity of the urban heat island in Tehran. Journal of Environmental Studies, 39(4), 55–66. https://doi.org/10.22059/jes.2014.36462 [In Persian]
  13. Bechle, M. J., Millet, D. B., & Marshall, J. D. (2011). Effects of income and urban form on urban NO₂: Global evidence from satellites. Environmental Science & Technology, 45(11), 4914–4919. https://doi.org/10.1021/es103866b
  14. Budzik, G., Sylla, M., & Kowalczyk, T. (2025). Understanding urban cooling of blue–green infrastructure: A review of spatial data and sustainable planning optimization methods for mitigating urban heat islands. Sustainability, 17(1), 142. https://doi.org/10.3390/su17010142
  15. Das, M., & Das, A. (2020). Assessing the relationship between local climatic zones (LCZs) and land surface temperature (LST): A case study of Sriniketan–Santiniketan Planning Area (SSPA), West Bengal, India. Urban Climate, 32, 100591. https://doi.org/10.1016/j.uclim.2020.100591
  16. Fallahati, F., Heydari Sureshjani, R., & Ganji, M. (2023). The impact of urban form on civic culture with a sustainable urban development approach in Kashan and Yasuj. Urban Social Geography, 10(1), 103–124. https://doi.org/10.22103/JUSG.2023.2091 [In Persian]
  17. Fayzollahpour, M. (2023). Estimation of land surface temperature (LST) and its comparison with NDMI, NDWI, and NDVI indices to assess water stress using support vector machine (SVM) with emphasis on land use/land cover changes (Case study: Anzali Wetland). Spatial Analysis of Environmental Hazards, 10(2), 131–148. http://dx.doi.org/10.61186/jsaeh.10.2.131 [In Persian]
  18. Grover, A., & Singh, R. B. (2015). Analysis of urban heat island (UHI) in relation to normalized difference vegetation index (NDVI): A comparative study of Delhi and Mumbai. Environments, 2(2), 125–138. https://doi.org/10.3390/environments2020125
  19. IPCC. (2022). Climate change 2022: Impacts, adaptation, and vulnerability. Cambridge University Press.
  20. Iran Statistical Center. (2016). National population and housing census. (In Persian)
  21. Kim, J., Yeom, S., & Hong, T. (2025). Analyzing the cooling effect, thermal comfort, and energy consumption of integrated arrangement of high-rise buildings and green spaces on urban heat island. Sustainable Cities and Society, 119, 106105. https://doi.org/10.1016/j.scs.2024.106105
  22. Li, S., Xu, L., Jing, Y., Yin, H., Li, X., & Guan, X. (2021). High-quality vegetation index product generation: A review of NDVI time series reconstruction techniques. International Journal of Applied Earth Observation and Geoinformation, 105, 102640. https://doi.org/10.1016/j.jag.2021.102640
  23. Lowry, W. P., & Lowry, P. P. II. (2001). Fundamentals of biometeorology: Interactions of organisms and the atmosphere (Vol. 2). Peavine.
  24. Masoudian, S. A., & Montazeri, M. (2020). Spatio-temporal behavior of the urban heat island in the metropolitan area of Isfahan. Natural Environment Hazards, 9(24), 35–46. https://doi.org/10.22111/jneh.2019.28437.1493 [In Persian]
  25. Ma, X., & Peng, S. (2021). Assessing the quantitative relationships between impervious surface area and surface heat island effect during urban expansion. PeerJ, 9, e11854. https://doi.org/10.7717/peerj.11854
  26. National Center for Biotechnology Information. (n.d.). Exposure to nitrogen dioxide: Assessment and health consequences. National Library of Medicine.
  27. Ngarambe, J., Joen, S. J., Han, C.-H., & Yun, G. Y. (2021). Exploring the relationship between particulate matter, CO, SO₂, NO₂, O₃ and urban heat island in Seoul, Korea. Journal of Hazardous Materials, 403, 123615. https://doi.org/10.1016/j.jhazmat.2020.123615
  28. Norbakhsh, M., & Nazari-Nejad, A. (2022). Investigating the relationship between NDVI and EVI vegetation indices and land surface temperature in Tehran. Geography and Human Relations, 5(1), 225–236. https://dor.isc.ac/dor/20.1001.1.26453851.1401.5.1.12.1 [In Persian]
  29. Ogashawara, I., & Bastos, V. D. S. B. (2012). A quantitative approach for analyzing the relationship between urban heat islands and land cover. Remote Sensing, 4(11), 3596–3618. https://doi.org/10.3390/rs4113596
  30. Oke, T. R. (1982). The energetic basis of the urban heat island. Quarterly Journal of the Royal Meteorological Society, 108(455), 1–24. https://doi.org/10.1002/qj.49710845502
  31. Pesaresi, M., Schiavina, M., Politis, P., Freire, S., Krasnodębska, K., Uhl, J. H., et al. (2024). Advances on the global human settlement layer by joint assessment of Earth observation and population survey data. International Journal of Digital Earth, 17(1). https://doi.org/10.1080/17538947.2024.2390454
  32. Rad, H. R., Khodaee, Z., & Ghiai, M. M. (2023). The impact of building height on microclimate characteristics of urban open spaces (Case study: Narmak neighborhood). International Journal of Architectural Engineering & Urban Planning, 33(4). https://doi.org/10.22068/ijaup.779
  33. Rahmani, N., & Sharifi, A. (2025). Urban heat dynamics in local climate zones (LCZs): A systematic review. Building and Environment, 267(Part B), 112225. https://doi.org/10.1016/j.buildenv.2024.112225
  34. Safarrad, T. (2021). Temporal analysis of nocturnal urban heat island intensity in Tehran. Climate Change Research, 2(8), 55–65. https://doi.org/10.30488/ccr.2021.319317.106 [In Persian]
  35. Safarrad, T., Ghadami, M., & Dittmann, A. (2022). Effects of COVID-19 restriction policies on urban heat islands in some European cities. International Journal of Environmental Research and Public Health, 19(11), 6579. https://doi.org/10.3390/ijerph19116579
  36. Salahi, B., Foroutan, M., & Pasban, A. H. (2024). Investigating the relationship between urban air pollution and heat islands in Ardabil County. Geography and Human Relations, 6(4), 940–954. https://doi.org/10.22034/gahr.2024.445528.2058 [In Persian]
  37. Setälä, H., Viippola, V., Rantalainen, A. L., Pennanen, A., & Yli-Pelkonen, V. (2013). Does urban vegetation mitigate air pollution in northern conditions?. Environmental Pollution, 183, 104–112. https://doi.org/10.1016/j.envpol.2012.11.010
  38. Shamsipour, A. A., Mahdian Mahfrozi, M., Akhavan, H., & Hosseinpour, Z. (2013). Analysis of the daily behavior of Tehran’s urban heat island. Journal of Environmental Studies, 38. https://doi.org/10.22059/jes.2013.29862 [In Persian]
  39. Shi, Z., Li, X., Hu, T., Yuan, B., Yin, P., & Jiang, D. (2023). Modeling the intensity of surface urban heat island based on impervious surface area. Urban Climate, 49, 101529. https://doi.org/10.1016/j.uclim.2023.101529
  40. Shikwambana, L., Mhangara, P., & Mbatha, N. (2020). Trend analysis and first-time observations of sulphur dioxide and nitrogen dioxide in South Africa using TROPOMI/Sentinel-5P data. International Journal of Applied Earth Observation and Geoinformation, 91, 102130. https://doi.org/10.1016/j.jag.2020.102130
  41. Vujovic, S., Haddad, B., Karaky, H., Sebaibi, N., & Boutouil, M. (2021). Urban heat island: Causes, consequences, and mitigation measures with emphasis on reflective and permeable pavements. CivilEng, 2(2), 459–484. https://doi.org/10.3390/civileng2020026
  42. Wang, M., & Xu, H. (2021). The impact of building height on urban thermal environment in summer. PLOS ONE, 16(4), e0247786. https://doi.org/10.1371/journal.pone.0247786
  43. Wei, Y., Lemoy, R., & Caruso, G. (2024). The effect of population size on urban heat island and NO₂ air pollution. City and Environment Interactions, 24, 100161. https://doi.org/10.1016/j.cacint.2024.100161
  44. Xi, C., Ren, C., Wang, J., Feng, Z., & Cao, S.-J. (2021). Impacts of urban-scale building height diversity on urban climates. Energy and Buildings, 251, 111350. https://doi.org/10.1016/j.enbuild.2021.111350
  45. Xi, Z., Li, C., Zhou, L., Yang, H., & Burghardt, R. (2023). Built environment influences on urban climate resilience. Science of the Total Environment, 859(Part 2), 160270. https://doi.org/10.1016/j.scitotenv.2022.160270
  46. Zargari, M., Mofidi, A., & Entezari, A., (2024). Climatic comparison of surface urban heat island using satellite remote sensing in Tehran and suburbs. Scientific Reports, 14, 643. https://doi.org/10.1038/s41598-023-50757-2
  47. Zhang, J., & Wang, Y. (2008). Relationships between the spatial extent of surface urban heat islands and urban characteristics. Sensors, 8(11), 7453–7468. https://doi.org/10.3390/s8117453
  48. Zhao, J., Chen, G., Yu, L., Ren, C., Xie, J., Chung, L., et al. (2023). Mapping urban morphology changes based on the local climate zone scheme. Urban Climate, 47, 101391. https://doi.org/10.1016/j.uclim.2022.101391
  49. Zheng, S., Chen, X., & Liu, Y. (2023). Impact of urban renewal on urban heat island: Study of renewal processes and thermal effects. Sustainable Cities and Society, 99, 104995. https://doi.org/10.1016/j.scs.2023.104995.
  50.  
پژوهش های جغرافیای طبیعی
دوره 57، شماره 4
دی 1404
صفحه 23-41

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  • تاریخ دریافت: 15 تیر 1404
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