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Trends in Air Quality Index (AQI) in Tehran, Iran: A Comprehensive Analysis Before, During, and After COVID-19 Pandemic (2018–2024)

Koorosh Kamali¹

, Fatemeh Masaebi²

, Zohre Farahmandkia ^*³

1- Department of Public Health, School of Public Health, Zanjan University of Medical Sciences, Zanjan, Iran.
2- Department of Statistics, Faculty of Health, Zanjan University of Medical Sciences, Zanjan, Iran.
3- Department of Environmental Health Engineering, Faculty of Health, Zanjan University of Medical Sciences, Zanjan, Iran; Social Determinants of Health Research Center, Institute of Health and Metabolic Diseases, Zanjan University of Medical Sciences, Zanjan, Iran.

Abstract: (17 Views)

Background: The largest capital of the Middle East, with 8000 Km² and a population of 13 million people, has about 40% of Iran's industrial units in its suburbs. The purpose of this study was to investigate the trend of air quality in Tehran between 2018 and 2024.
Methods: Daily air quality index (AQI) data were collected from 16 monitoring stations in Tehran province over three time periods: 2 years before, 2 years during, and 2 years after the COVID-19 pandemic. Descriptive statistics were calculated for each pollutant during these periods, and box plots were used to visualize AQI distributions. The Kruskal-Wallis test was applied to assess significant differences in AQI across the three time periods.
Results: PM_2.5was the dominant pollutant across all seasons, peaking at 99.4% in autumn and remaining above 90% in winter. The AQI for PM_2.5increased from 109 pre-pandemic to 143 post-pandemic. Seasonal trends revealed significant increases in pollutants such as O₃ and PM_2.5in spring, summer, and autumn, while NO₂ levels fluctuated. The Kruskal-Wallis test indicated significant seasonal variations, with PM_2.5showing the most substantial increase (H = 262.43, p < 0.001). O₃ and PM₁₀ also showed significant post-pandemic growth, whereas SO₂ and NO₂ had smaller but significant fluctuations (p < 0.05).
Conclusion: The results show that reducing traffic and preventing the use of Mazut fuel in power plants have had significant effects on reducing air pollutants, and the sharp decrease in precipitation in recent years has increased the dispersion and emission of particles.

Keywords: Air Pollution, O3, PM2.5, Tehran, Iran

Type of Study: Original Article | Subject: Environmental Health, Sciences, and Engineering
Received: 2025/10/18 | Accepted: 2025/12/17

References

1. Amar. (2018). Statistics and information of Tehran province. Statistical yearbook of Tehran. https://amar.thmporg.ir/year-book/1397

2. Bekbulat, B., Apte, J. S., Millet, D. B., Robinson, A. L., Wells, K. C., Presto, A. A., & Marshall, J. D. (2021). Changes in criteria air pollution levels in the US before, during, and after COVID-19 stay-at-home orders: Evidence from regulatory monitors. Science of the Total Environment, 769, 144693. [Crossref]

3. Dantas, G., Siciliano, B., França, B. B., da Silva, C. M., & Arbilla, G. (2020). The impact of COVID-19 partial lockdown on the air quality of the city of Rio de Janeiro, Brazil. Science of the Total Environment, 729, 139085. [Crossref]

4. Delfanazari, S., Saligheh, M., & Akbari, M. (2017). Changes in wind fields affected by urban development case study: Saadat Abad neighborhood of Tehran. Researches in Earth Sciences, 8(3), 1-14.

5. Doost Mohammadi, F., Rahmani, A., & Rezaeian, M. (2021). Epidemiology and strategies for coping with novel coronavirus disease (COVID-19): A narrative review. Journal of Rafsanjan University of Medical Sciences, 20(5), 571-596. [Crossref]

6. Farahmandkia, Z., Moattar, F., Zayeri, F., Sadegh Sekhavatjou, M., & Mansouri, N. (2017). Contribution of point and small-scaled sources to the PM10 emission using positive matrix factorization model. Journal of Environmental Health Science and Engineering, 15(2), 1-11. [Crossref]

7. Farahmandkia, Z., Moattar, F., Zayeri, F., Sadegh Sekhavatjou, M., & Mansouri, N. (2017). Assessment of the risk of non-cancerous diseases under the exposure of heavy element in urban areas and troubleshooting pollutant sources (The case of Zanjan). Journal of Human Environment and Health Promotion, 2(3), 177-185. [Crossref]

8. Fu, F., Purvis-Roberts, K. L., & Williams, B. (2020). Impact of the COVID-19 pandemic lockdown on air pollution in 20 major cities around the world. Atmosphere, 11(11), 1189. [Crossref]

9. Hasnain, A., Hashmi, M. Z., Bhatti, U. A., Nadeem, B., Wei, G., Zha, Y., & Sheng, Y. (2021). Assessment of air pollution before, during and after the COVID-19 pandemic lockdown in Nanjing, China. Atmosphere, 12(6), 743. [Crossref]

10. International Agency for Research on Cancer. (2013). IARC: Outdoor air pollution a leading environmental cause of cancer deaths. https://www.iarc.who.int/news-events/iarc-outdoor-air-pollution-a-leading-environmental-cause-of-cancer-deaths/

11. Iran News Paper. (2021). It was forbidden to burn diesel fuel. http://old.irannewspaper.ir/newspaper/item/592785

12. Jafari Hombari, F., & Pazhoh, F. (2022). Synoptic analysis of the most durable pollution and clean waves during 2009-2019 in Tehran city (capital of Iran). Natural Hazards, 110(2), 1247-1272. [Crossref]

13. Jaffe, L. S. (1968). Ambient carbon monoxide and its fate in the atmosphere. Journal of the Air Pollution Control Association, 18(8), 534-540. [Crossref]

14. Ju, M. J., Oh, J., & Choi, Y. H. (2021). Changes in air pollution levels after COVID-19 outbreak in Korea. Science of the Total Environment, 750, 141521. [Crossref]

15. Krzyzanowski, M., Apte, J. S., Bonjour, S. P., Brauer, M., Cohen, A. J., & Prüss-Ustun, A. M. (2014). Air pollution in the mega-cities. Current Environmental Health Reports, 1(3), 185-191. [Crossref]

16. Li, Y., Tang, Y., Fan, Z., Zhou, H., & Yang, Z. (2018). Assessment and comparison of three different air quality indices in China. Environmental Engineering Research, 23(1), 21-27. [Crossref]

17. Magazzino, C., Mele, M., & Schneider, N. (2020). The relationship between air pollution and COVID-19-related deaths: An application to three French cities. Appl Energy, 279, 115835. [Crossref]

18. Naddafi, K., Hassanvand, M. S., Yunesian, M., Momeniha, F., Nabizadeh, R., Faridi, S., & Gholampour, A. (2012). Health impact assessment of air pollution in megacity of Tehran, Iran. Iranian Journal of Environmental Health Science & Engineering, 9(1), 28. [Crossref]

19. Rahimi, R., Ghahroudi Tali, M., & Sadough, S. H. (2021). The patterns and internal sources of dust in Tehran. Researches in Earth Sciences, 12(4), 86-107.

20. Son, J. Y., Fong, K. C., Heo, S., Kim, H., Lim, C. C., & Bell, M. L. (2020). Reductions in mortality resulting from reduced air pollution levels due to COVID-19 mitigation measures. Science of The Total Environment, 744, 141012. [Crossref]

21. Taghizadeh, F., Jafari, A. J., & Kermani, M. (2019). The trend of air quality index (AQI) in Tehran during (2011-2016). Journal of Air pollution and Health, 4(3), 187-192. [Crossref]

22. Tobías, A., Carnerero, C., Reche, C., Massagué, J., Via, M., Minguillón, M. C., . . . & Querol, X. (2020). Changes in air quality during the lockdown in Barcelona (Spain) one month into the SARS-CoV-2 epidemic. Science of the Total Environment, 726, 138540. [Crossref]

23. World Health Organization. (2023). Air pollution: The invisible health threat. http://www.who.int/news-room/feature-stories/detail/air-pollution--the-invisible-health-threat

24. Yousefi, S., Shahsavani, A., & Hadei, M. (2019). Applying EPA’s instruction to calculate air quality index (AQI) in Tehran. Journal of Air pollution and Health, 4(2), 81-86. [Crossref]

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