Study and Investigating the Effect of Meteorological Quantities on the Pollution Potential of Arak City

Document Type : Original Article

Authors

1 Markazi Province Meteorology Office, Arak, Iran

2 Research Institute of Meteorology and Atmospheric Science (RIMAS), Tehran, Iran

Abstract

Introduction: Urbanization and air pollution, especially in megacities, are major issues today. Understanding the factors contributing to this problem is crucial, and reducing the associated risks is a top priority for city and country officials. Arak City in Iran is one of the most polluted cities in the country, with industrial activities being the main cause of pollution. This research aims to investigate the meteorological factors that contribute to the pollution potential of Arak City, including wind speed, temperature, pressure, precipitation, boundary layer height, vertical velocity of the atmosphere at the levels of 825, 700, and 500 mb, and air conditioning coefficient. The study ultimately confirms Arak City's reputation as one of the most polluted cities in Iran.
Material and Methods: In this article, from the 20-year statistics of the Arak observation station (1380-1399) for the quantities of the earth's surface, including wind speed, temperature, pressure, and precipitation, as well as the 20-year data from 2001 to 2020, the reanalyzed data of Era5 from the database ECMWF has been used for upper-level quantities. To check other atmospheric quantities, including boundary layer height, wind speed in the upper atmosphere, and vertical wind at 825, 700, and 500 mb levels, Era5 reanalyzed data with a resolution of 0.25 degrees extracted from the ECMWF database were used.
Results and Discussion: The results indicated that low temperatures in the cold period of the year, as well as low night and morning temperatures in the cold months of the year, can cause temperature inversion and increase the retention potential of atmospheric pollutants. The average wind speed indicates the low and insignificant effect of the wind, especially in the cold days of the year and in the morning and night hours. Daily per capita rainfall of less than 1 mm did not have a significant effect in reducing pollutants. The investigation of meteorological quantities in the upper levels of the atmosphere showed that the height of the boundary layer fluctuates between 200 and 1400 m daily, which was less than 400 m from late November to January. Analysis of the vertical velocity at altitudes of 825 and 700 hPa revealed a downward movement during winter, autumn, and spring, while an upward trend was noted during daytime hours in the summer season. Furthermore, a descent was observed at the 500 hPa level throughout all seasons during nighttime hours, which is not as effective as the other two altitude levels. Examining the daily air ventilation coefficient also indicated its high fluctuations throughout the year from 800 to 7500 m2s-1. The number of hourly changes also indicated fluctuation in the range of 22000 to around zero. The maximum ventilation coefficient at 12 UTC was between 3000 and 20000 m2s-1. At 00:00, 03:00, and 21:00 UTC, the ventilation coefficient was less than 1500 m2s-1 on all days of the year. Also, according to the location of Arak and Shazand, there is a possibility of the transfer of atmospheric pollutants from Shazand to Arak, especially in spring, autumn, and winter.
Conclusion: Overall, the study of weather patterns at both ground level and in higher parts of the atmosphere highlights the risk of pollution buildup and low ventilation in Arak City, particularly during the colder months and during nighttime and early morning hours. As a result, it is important for policies to prioritize the establishment of low-pollution industries and the management of sources of pollution, especially during the aforementioned times.

Keywords

References

Allahabadi, A. and Ahmadi Asoor, A., 2011. Measuring the air pollutants in Sabzevar, Iran. Journal of Sabzevar University of Medical Sciences. 18(2), 140-147. (In Persian with English abstract)
Badamfirooz, J., Rahmati, A., Daneshpajooh, N., Mousazadeh, R. and Mirzaei, R., 2022. Investigating the impact of existing and under construction industries on the air quality of Arak City using ADMS model. Environmental Sciences20(1), 21-40. doi: 10.52547/ENVS.2021.1022
Bodor, Z., Bodor, K., Keresztesi, Á. and Szép, R., 2020. Major air pollutants seasonal variation analysis and long-range transport of PM10 in an urban environment with specific climate condition in Transylvania (Romania). Environmental Science and Pollution Research. 27, 38181-38199. https://doi.org/10.1007/s11356-020-09838-2
Borhani, F., Ehsani, A.H., McGuirk, S.L., Shafepour Motlagh, M., Mousavi, S.M., Rashidi, Y. and  Mirmazloumi, S.M., 2023. Examining and predicting the influence of climatic and terrestrial factors on the seasonal distribution of ozone column depth over Tehran Province using satellite observations. Acta Geophys. 72, 1191-1226. https://doi.org/10.1007/s11600-023-01179-1.
Borhani, F., Shafepour Motlagh, M., Ehsani, A.H., Rashidi, Y., Maddah, S. and Mousavi, S.M., 2023. On the predictability of short‑lived particulate matter around cement plant in Kerman, Iran: machine learning analysis. International Journal of Environmental Science and Technology. 20, 1513–1526. https://doi.org/10.1007/s13762-022-04645-3
Chan, L., Qi­hong, D., Wei­wei, L., Bo­liang, H., Ling­zhi, S., 2012. Characteristics of ventilation coefficient and its impact on urban air pollution. Journal of Central South University Technology. 19, 615-622. https://doi.org/10.1007/s11771-012-1047-9
Choudhary, M. P., Vaibhav, G., 2013. Causes, Consequences and Control of Air Pollution. Conference: All India Seminar on Methodologies for Air Pollution Control at: Malviya National Institute of Technology, Jaipur, Rajasthan, India.
Copernicus Climate Change Service (C3S), 2017. ERA5: Fifth generation of ECMWF atmospheric reanalyses of the global climate. Copernicus Climate Change Service Climate Data Store (CDS), date of access. https://cds.climate.copernicus.eu/cdsapp#!/home.
Gassmann, M., Mazzeo, N.A., 2000. Air pollution potential: Regional study in Argentina. Environmental Management. 25, 375-382. https://doi.org/10.1007/s002679910029
Ghahroudi Tali, M., 2016. Physical development of Arak city applying natural indicators. European Journal of Geography. 7(3), 99-110. https://eurogeojournal.eu/index.php/egj/article/view/392.
Holton, J.R., 2004. An Introduction to Dynamic Meteorology, Elsevier Academic Press, Fourth Edition.
Hosseinibalam. F. and Hejazi, A., 2012. Influence of meteorological parameters on air pollution in Isfahan. Environment and Chemistry, IPCBEE. 46.
Javan Bakht Amiri, S., Khatami, S.H., 2018. Investigating the relationship between air quality index pollutants and meteorological parameters in Tehran with regression analysis approach. Human and Environment Quarterly. 10 (1), 15-28. (In Persian with English abstract).
Karam, A., Ranjbar Barouq, Z., Mohammadian, E., 2013. Study of the effect of topography on the air pollution of Arak city. the first conference of geographical sciences of Iran. ICGS01_194(In Persian with English abstract).
Kayes, I., Shahriar, S., Hasan, K., Akhter, M., Kabir, M. and Salam, M., 2019, The relationships between meteorological parameters and air pollutants in an urban environment. Global Journal of Environmental Science and Management. 5(3), 265-278. doi: 10.22034/GJESM.2019.03.01
Kermani, M., Davalit, M., Fallah Jokandan, S., Aghaei, M., Bahrami Asl, F. and Karimzadeh, S., 2016. Investigation of health index of air quality and its applications in seven cities of Iran in 2011. J Arak Uni. Med. Sci. 19 (12), 78-88. . (In Persian with English abstract).
Liu, Y., Zhou Y. & Lu, J., 2020. Exploring the relationship between air pollution and meteorological conditions in China under environmental governance. Scientific reports. 3, 14518. https://doi.org/10.1038/s41598-020-71338-7
Liu, Z., Shen, L., Yan, C., Du, J., Li, Y. and Zhao, H., 2020. Analysis of the Influence of Precipitation and Wind on PM2.5 and PM10 in the Atmosphere. Advances in Meteorology. 2020, 1-13. https://doi.org/10.1155/2020/5039613
Nowrozi, F. and Shamsipour, A.A., 2014. The effect of climatic factors in controlling or intensifying air pollution in Arak. International Conference on Environmental Sciences, Engineering and Technologies, Tehran. (In Persian with English abstract).
Oji, S. and Adamu, H., 2020. Correlation between air pollutants concentration and meteorological factors on seasonal air quality variation. Journal of Air Pollution and Health; 5(1), 11-32. https://doi.org/10.18502/japh.v5i1.2856
Panahi, Ali, 2015. Investigation of the relationship between air quality index pollutants and meteorological parameters in severe storms of Tabriz city. Geographical Space Quarterly. 62, 63-76. (In Persian with English abstract).
Salehi, M., Mirhoseini, H., Karimi, B. and Hashiani, A.A., 2021. Association between airborne particles and meteorological parameters in Arak industrial city. Journal of Air Pollution and Health. 6(1). 42-53. https://japh.tums.ac.ir/index.php/japh/article/view/276
Skoro, G., 2001. Transportation, Weather Disasters and Air Pollution. translated by Dr. Shahriar Khalidi, Shahid Beheshti University Press. Tehran, pp. 181.
Vari, H. and Hamami, M., 2022. The effect of meteorological parameters on the air pollution in Tehran and determining its status using geostatistics and geographic information system, the 8th international conference on interdisciplinary research in civil engineering, architecture and urban management of the 21st century Tehran, https://civilica.com/doc/1533262
Voiculescu, M., Constantin, D.E., Condurache-Bota, S., Călmuc, V., Ros, A. and Mariana, C., 2020. Role of Meteorological Parameters in the Diurnal and Seasonal Variation of NO2 in a Romanian Urban Environment. International Journal of Environmental Research and Public Health. 17 (17), 6228. https://doi.org/10.3390/ijerph17176228
Xu, H.H., Pu, J.J., He, J., Liu, J., Qi, B. and Du, R.G., 2016. Characteristics of Atmospheric Compositions in the Background Area of Yangtze River Delta during Heavy Air Pollution Episode. Advances in Meteorology. 2016, 1-13. https://doi.org/10.1155/2016/7240486
 
Environmental Sciences
Volume 22, Issue 3
2024
Pages 447-468

Files

Share

How to cite

Statistics