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Ghadam khair M S, Borna R, Morshedi J, Ghorbanian J. Revealing the effect of pervasive dust events on the net shortwave radiation flux values entering the earth's surface (case study of Khuzestan province). Journal of Spatial Analysis Environmental Hazards 2023; 10 (3) :15-30
URL: http://jsaeh.khu.ac.ir/article-1-3395-en.html
1- phd student of Meteorology, Department of Geography, Ahvaz Branch, Islamic Azad University, Ahvaz, Iran.
2- Associate Professor, Department of Geography, Science and Research Unit, Islamic Azad University, Tehran, Iran. , bornareza@yahoo.com
3- Assistant Professor of Urban Planning Department, Shushtar Branch, Islamic Azad University, Shushtar, Iran.
4- Assistant Professor, Department of Geography, Ahvaz Branch, Islamic Azad University, Ahvaz, Iran.
Abstract:   (2103 Views)
Introduction
Extensive and massive agriculture, along with other agricultural activities such as animal husbandry, industrial activities in the southern half of the province, has created and intensified extensive changes in the environmental resources and natural structure of the province. This extensive change can show its effects and consequences in the destruction of forest lands, the transformation of rich pastures into poor pastures and barren lands, severe soil erosion, and finally the creation and development of internal centers of dust. and intensify the severity of dust incidents in the province. Dust events have profound and significant effects on agriculture and soil fertility, health and hygiene, disruption and destruction of industries and power plants, and negative effects on the environment, including the deterioration of forests. Airborne particles, which are mainly driven to the region by dust storms, are one of the important components of the atmospheric system. They can not only change the albedo of the energy balance by acting as cloud particle nuclei, or ice nuclei.
Materials and Methods
The study location of this research is Khuzestan province, which is one of the most challenging provinces in the country in terms of environmental hazards. This province, with an area of about 6.5 million hectares, occupies about 4% of the country's area. Dust is one of the major and most important challenges of this province. Its destructive effects can be traced in various dimensions, such as the quality of water resources, the quality and performance of agricultural products, industries and energy transmission networks, and the air quality of cities. Three categories of data have been used in this research. The data of the first category is related to the data of widespread dust days in Khuzestan province. These data were obtained from the dust codes of the current air condition (ww parameter of synoptic stations of the province) during the statistical period of 2000, 2020. The second category of data was actually the remote sensing data of MODIS sensor, which included the Aerosol Optical Depth (AOD) product of MODIS sensor (MOD04 product) and Aerosol Exponential Index (AEA). These two indicators are dimensionless but with different directions. In the AOD index, higher numbers represent more aerosols in the atmosphere and in the AEA index, in addition to the presence of dust in the place, it also provides the size of the aerosol particles. Finally, the third category of data is the reanalysis data related to incoming net shortwave radiation (SNSR), which was taken from the reanalysis data of the European ECMWF database version ERA5 with a spatial resolution of 0.5 arc degrees.­



 Conclusion
In this research, it was tried to investigate the influence of the dust event in the context of fluctuations and daily changes in the amount of net shortwave radiation received on the earth's surface. The results of the investigation of three cases of widespread dust in the province showed that in these three cases of widespread dust, aerosol particles are generally in the central, southern and western parts of the province (plain and lowland areas of the province) from the type of medium to large particles (index angstrom between 0.5 and 1) and in the eastern and northeastern parts, it was of the type of coarse particles (angstrom index less than 0.5). In the context of the impact of dust events on the amount of shortwave radiation received by the earth's surface, it was seen that in the dust event of July 22, 2010, the Angstrom exponential index indicates the presence of coarse particles in the atmosphere near the earth's surface and the AOD index also indicates the presence of dense dust in the entire area of the province. The received net shortwave radiation (at 12 noon or 09 UTC) was about 194 watts per square meter (about 28 percent) lower than the average for the same month. This drop rate was less in the other two dust waves, whose AOD and Angstrom index values indicated finer and less concentrated dust. In the dust wave of June 19, 2012, the amount of net shortwave radiation received was only 5% (25 W/m2 at 12 noon or 09 UTC) less than the long-term average, and this drop in the dust event of May 12, 2018 was equal to 28 W/m square (about 4% drop compared to the average of the same month).
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Type of Study: Research | Subject: Special
Received: 2023/10/23 | Accepted: 2023/12/2 | Published: 2023/09/23

References
1. بارونیان، ایرج؛ رضا برنا، منیژه ظهوریان، جعفر مرشدی.1400. آشکار‌سازی تاثیرگذاری تغییرات کاربری زمین‌ها در توزیع فضایی غلظت گردوغبار استان خوزستان با استفاده از محصولات سنجنده MODIS . جغرافیا و پایداری محیط، 11(3): 97-114.
2. سلیمانی، آرزو؛ حسین محمد عسگری ، سهراب علی دادالهی، هیوا علمی زاده، سید حسین خزاعی. 1394. ارزیابی عمق اپتیکی حاصل از تصاویر ماهواره مادیس در خلیج فارس. مجله علوم و فنون دریایی، 14(4): 75-83
3. علی پور، ناهید؛ طیبه مصباح زاده، حسن احمدی، محمد جعفری، سارا کرمی، علی محمد. طهماسبی بیرگانی.1401. ارزیابی تاثیر طوفان گردوغبار بر روی شار گرمایی و بیلان تابش در حوزه هیرمند. مجله پژوهش‌های حفاظت آب و خاک، 29(1): 53-73
4. فرهمند، هاجر؛ سعید جهانبخش اصل، مجید رضائی بنفشه، علی محمد خورشیددوست. 1398. شبیه سازی واداشت های تابشی و اثر متقابل گردوغبار و اقلیم توسط مدل WRF_Chem در منطقه جنوب غربی آسیا. نشریه هواشناسی و علوم جوّ،2(1): 29-41
5. Ångström, A.1929. On the atmospheric transmission of sun radiation and on dust in the air. Geografis Annal, 2:156-166.
6. Fountoukis, C.; H. Harshvardhan, I. Gladich, L. Ackermann, and M.A. Ayoub .2020. Anatomy of a severe dust storm in the Middle East: Impacts on aerosol optical properties and radiation budget. Aerosol and Air Quality Research, 20: 1. 155-165
7. Huang, G.; Y. Zhou, Z. Guo, X. Liu, Y. Chen, Q. Liu, Z. Ta, P. Wang, Q. He, J. Gao, and Y. Zhang .2023. The influence of dust aerosols on solar radiation and near-surface temperature during a severe duststorm transport episode. Front. Environ. Sci, 11:1126302.
8. Kokhanovsky, A. A. 2008. Aerosol optics: Light absorption and scattering by particlesin the atmosphere. Springer-Praxis.
9. Lau, W. K. M.; K. M. Kim, J. J. Shi, T. Matsui, M .Chin, Q. Tan. 2017. Impacts of aerosol monsoon interaction on rainfall and circulation over Northern India and the Himalaya Foothills. Clim. Dyn, 49: 1945–1960.
10. Li, H.; H. Chen, H. Wang, and E. Yu. 2018. Future precipitation changes over China under 1.5 °C and 2.0 °C global warming targets by using CORDEX regional climate models. Sci. Total Environ, 640: 543–554.
11. Maghrabi, A.2017. The influence of dust storms on solar radiation data, aerosol properties and meteorological variables in Central Arabian Peninsula. Int. J. Environ. Sci Technol, 14: 1643–1650
12. Middleton, N. 2017. Desert dust hazards: A global review. Aeolian Res, 24: 53–63 .
13. Middleton, N.; and Kang. U.2017. Sand and dust storms: Impact mitigation. Sustainability, 9: 1053.
14. Nguyen, H. D.; M. Riley, J. Leys, and D. Salter. 2019. Dust storm event of February 2019 in central and East Coast of Australia and evidence of long-range transport to New Zealand and Antarctica. Atmosphere, 10: 653.
15. Samset, B. H.; M. Sand, C.J. Smith, S. E. Bauer, P.M.Forster, J.S.Fuglestvedt. 2018. Climate impacts from a removal of anthropogenic aerosol emissions. Geophys. Res. Lett, 45: 1020–1029
16. Smirnov, A.; N.O'Neill,A. Royer,A. Tarussov. 1996. Aerosol optical depth over Canada and the link with synoptic air mass types. Journal of Geophysical Research, 101: 19299.
17. Solgi, R.;M. Mazraeh Farahani, M. Gharaylou. 2023.The Effect of Dust Aerosols on Some Meteorological Parameters in Two Dry and Humid Areas. Journal of the Earth and Space Physics, 48(4): 183-195.
18. Tiantian Hu.; W. Di, L. Yaohui, and W. Chenghai. 2017. The Effects of Sandstorms on the Climate of Northwestern China. Advances in Meteorology, 2017:1-17.
19. Watson, J. G.; J. D. Bachmann, , S. S. Wierman, C. Mathai, W.C.Malm,W.H. White.2002. Visibility: Science and regulation. J. Air Waste Manage. Assoc. 52 view of the seasonal distribution of mineral dust and its correlation with atmospheric circulation. Dyn. Atmos. Oceans. 68:20–34.
20. Wilkerson Walter, D. 1991. Dust and sand forecasting in Iraq and adjoining countries. USAF Environmental Technical ,ApplicationsCenter, pp72.
21. Yan, H.; and T. Wang. 2020.Ten years of aerosol effects on single-layer overcast clouds over the US Southern Great Plains and the China Loess Plateau. Adv. Meteorol, 6719160: 1–15.
22. Zhao, J.; X. Ma, S. Wu, and T. Sha. 2020. Dust emission and transport in northwest China: WRF-chem simulation and comparisons with multi-sensor observations. Atmos. Res, 241: 104978.
23. Zhou, C.; Y. Liu, Q. He, X. Zhong, Q. Zhu, F. Yang, F. 2022a. Dustcharacteristics observed by unmanned aerial vehicle over the Taklimakan Desert. Remote Sens, 14 (4): 990.
24. Zhou, C.; Y. Liu, Q. He, X. Zhong, Q. Zhu, F. Yang, F. 2022b. In situ observation of warm atmospheric layer and the heat contribution of suspended dust over the Tarim Basin. Atmos. Chem. Phys, 22: 5195–5207.

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