Volume 25, Issue 79 (12-2025)
jgs 2025, 25(79): 1-31 |
Back to browse issues page
Download citation:
BibTeX | RIS | EndNote | Medlars | ProCite | Reference Manager | RefWorks
Send citation to:
BibTeX | RIS | EndNote | Medlars | ProCite | Reference Manager | RefWorks
Send citation to:
sayadi F, hejazizadeh Z. (2025). Investigating the effect of Tehran city morphology on the formation of heat islands with emphasis on air performance. jgs. 25(79), 1-31. doi:10.61882/jgs.25.79.25
URL: http://jgs.khu.ac.ir/article-1-4450-en.html
URL: http://jgs.khu.ac.ir/article-1-4450-en.html
1- Professor of Climatology, Faculty of Geographical Sciences, Kharazmi University, Tehran, Iran. , sayadifariba@yahoo.com
2- Professor of Climatology, Department of Natural Geography, Faculty of Geographical Sciences, Kharazmi University, Tehran, Iran
2- Professor of Climatology, Department of Natural Geography, Faculty of Geographical Sciences, Kharazmi University, Tehran, Iran
Abstract: (328 Views)
Considering that urban land-use change in metropolises such as Tehran has been increasing in recent decades; Therefore, the formation of the thermal island phenomenon in the city can be studied as one of the environmental problems. Increasing construction, density, and building heights will change the complexes' geometry and shape, followed by changes in climatic conditions and micro-urban climates. Therefore, in this study, we tried to investigate urban geometry's effect on forming a thermal island in Tehran. The study region in this research includes regions one, two, and three of Tehran.
The methods used in this research included (1) Oak's numerical equation and algorithm design to simulate the intensity of the heat island. In the first stage, digital GIS data including building blocks (parcels) in polygon format and street widths, which were prepared and prepared by Tehran Municipality based on the 2016 detailed audit plan, were used. (2) Modeling was performed in Envi-met software to study the effect of city geometry on wind. The results of the studies showed that the two factors of building height and street width (ratio (H/W)) play an important role as two key factors in studying urban geometry; therefore, in studying the intensity of the heat island, the factor of building height and high-rise construction can play an important role in the formation of the heat island. However, the higher the height of the building compared to the width of the streets, the more it acts as a barrier against the heat island. The intensity of the heat island adjusted with the Oak equation showed that the factor of building roughness coefficient can be an important factor in adjusting the intensity of the heat island. Spatial analysis of images and outputs of the Envi.met model showed that the two main factors of construction density And the height of the building has a greater impact on wind speed transmission than the slope and topography of the area. Therefore, in the study of urban design for future studies, appropriate planning and proper management of resources are needed for the climatic comfort of residents, which can be designed to be beautiful and safe cities by considering the principles of architectural safety.
The methods used in this research included (1) Oak's numerical equation and algorithm design to simulate the intensity of the heat island. In the first stage, digital GIS data including building blocks (parcels) in polygon format and street widths, which were prepared and prepared by Tehran Municipality based on the 2016 detailed audit plan, were used. (2) Modeling was performed in Envi-met software to study the effect of city geometry on wind. The results of the studies showed that the two factors of building height and street width (ratio (H/W)) play an important role as two key factors in studying urban geometry; therefore, in studying the intensity of the heat island, the factor of building height and high-rise construction can play an important role in the formation of the heat island. However, the higher the height of the building compared to the width of the streets, the more it acts as a barrier against the heat island. The intensity of the heat island adjusted with the Oak equation showed that the factor of building roughness coefficient can be an important factor in adjusting the intensity of the heat island. Spatial analysis of images and outputs of the Envi.met model showed that the two main factors of construction density And the height of the building has a greater impact on wind speed transmission than the slope and topography of the area. Therefore, in the study of urban design for future studies, appropriate planning and proper management of resources are needed for the climatic comfort of residents, which can be designed to be beautiful and safe cities by considering the principles of architectural safety.
Type of Study: Research |
Subject:
climatology
References
1. افشارمنش، حمیده؛ حجازیزاده، زهرا؛ علیجانی، بهلول.1400، آیندهپژوهی بحران افزایش دمای سطح زمین و کاهش آسایش اقلیمی شهروندان در کلانشهر تهران، تحقیقات کاربردی علوم جغرافیایی، (61)21، صص 16-1.
2. خالدی، شهریار؛ متولی، صدرالدین؛ خالدی، شاهین. 1396، میکروکلیماتولوژی: شناخت آب و هوا در جهت توسعه پایدار، انتشارات پیشگام.
3. صلاحی، برومند؛ فروتن، مهدی؛ پاسبان، امیرحسام (1403). واکاوی ارتباط آلودگیهای مناطق شهری با جزایر حرارتی شهرستان اردبیل، جغرافیا و روابط انسانی، شماره 24. صص940 تا 954.
4. صیادی، فریبا (1399). تاثیر هندسه شهر تهران بر تشدید جزیره حرارتی و آلودگی هوا، رساله دکتری جغرافیای طبیعی گرایش اقلیم شهری، دانشگاه خوارزمی تهران.
5. 5ی صیادی، فریبا؛ حجازی زاده، زهرا؛ سلیقه، محمد (1401). بررسی تأثیر هندسه شهری بر چگونگی شکلگیری جزیره حرارتی شهر تهران(مطالعه موردی: ناحیه دو و شش منطقه 3)، مجله جغرافیا، دورۀ20، شمارۀ72.صص 18-1. http://dor.net/dor/20.1001.1.27833739.1401.20.72.1.7
6. علیجانی،بهلول؛ طولابی نژاد، میثم؛ صیادی، فریبا.1396، محاسبه شدت جزیره حرارتی بر اساس هندسه شهری (مطالعه موردی: محله کوچه باغ شهر تبریز)، تحلیل فضایی مخاطرات محیطی، 3،ص112-99.
7. مزیدی، احمد؛ امیدوار،کمال؛ مظفری، غلامعلی؛ تقی زاده، زهرا.1398، آشکارسازی تغییرات جزیره گرمایی شهر اصفهان با تاکید بر توسعه شهری، کاوشهای جغرافیایی مناطق بیابانی،(1) 7،صص39-21.
8. ملکی، سعید ، عبیات، محمود ، عبیات ماجده. (1402) «ارزیابی اثر تغییرات کاربری بر الگوی مکانی-زمانی دمای سطح زمین و جزایر حرارتی در شهر اهواز با استفاده از تصاویر ماهوارهای.» پژوهش های جغرافیای انسانی، دوره پنجاه و پنجم - شماره 2، صص 39 - 61 .
9. منصوری، سحر؛ خالدی، شهریار؛ برنا، رضا؛ اسدیان، فریده.1398، اثر تغییرات کاربری و کاهش فضای سبز شهری بر تشدید جزیره گرمایی و آلودگی هوای شهر تهران(منطقه یک)، مجله جغرافیا، سال هفدهم، شماره 63، 114-129.
10. منصوری، میلاد؛رورده، همت اله؛ صفرراد، طاهر (1403). واکاوی تأثیر گسترش شهری بر تغییرات مکانی جزیرهی حرارتی شهر ساری، مجله مطالعات ساختار و کارکرد شهری، شماره 38 ، صص 218 تا 240.
11. Abramopoulos, F., Rosenzweig, C., & Choudhury, B. (1988). Improved ground hydrology calculations for global cli mate models (GCMs): Soil water movement and evapo transpiration. Journal of Climate. [DOI:10. 1175/1520-0442(1988)001/3c0921:IGHCFG/3e2.0.CO;2.]
12. Al-Kodmany, K. (2018). The sustainability of tall building developments: A conceptual framework. Buildings, 8(1), 7. [DOI:10.3390/buildings8010007]
13. Atash, F. (2007). The deterioration of urban environments in developing countries: Mitigating the air pollution crisis in Tehran Iran. Cities,24(6), 399-409. [DOI:10.1016/j.cities.2007.04.001]
14. Bady, M., Kato, Sh., Takahashi, T. and Huang, H., 2011.An experimental investigation of the wind environment and air quality with in densely populated urban street canyon: Journal of Wind engineering and industrial aerodynamics, Vol.99, p.857-867 [DOI:10.1016/j.jweia.2011.06.005]
15. Battisti, A. (2020). Bioclimatic architecture and urban mor-phology. Studies on intermediate urban open spaces. Energies, 13(21), Article Article 5819. [DOI:10.3390/en13215819]
16. Castro, S. L., Wick, G. A., Minnett, P. J., Jessup, A. T., & Emery, W. J. (2010). The impact of measurement uncertainty and spatial variability on the accuracy of skin and subsurface regression-based sea surface temperature algorithms. Remote Sensing of Environment,114(11), 2666-2678. [DOI:10.1016/j.rse.2010.06.003]
17. Charalampopoulos, I., et al. (2013). Analysis of thermal bioclimate in various urban configurations in Athens, Greece. Urban Ecosystems, 16(2), 217-233. [DOI:10.1007/s11252-012-0252-5]
18. Collier, G. (2006). The impact of urban areas on weather, Meteorological,132, pp. 1-25 doi: 10.1256/qj.05.199 [DOI:10.1256/qj.05.199]
19. Cortes, A., Rejuso, A. J., Santos, J. A., & Blanco, A. (2022). Evaluating mitigation strategies for urban heat island in Mandaue City using ENVI-met. Journal of Urban Man agement, 11(1), 97-106. [DOI:10.1016/j.jum.2022.01.002]
20. Crank, P. J., Sailor, D. J., Ban-Weiss, G., & Taleghani, M. (2018). Evaluating the ENVI-met microscale model for suitability in analysis of targeted urban heat mitigation strategies. Urban Climate, 26, 188-197. [DOI:10.1016/j.uclim.2018.09.002]
Send email to the article author
| Rights and permissions | |
 |
This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License. |
This work is licensed under a Creative Commons — Attribution-NonCommercial 4.0 International (CC BY-NC 4.0)