بررسی سازوکار جوی حاکم بر رخداد گرد و خاک‌های شدید جنوب شرق ایران

نوع مقاله : مقاله پژوهشی

نویسندگان

1 استادیار گروه جغرافیا دانشگاه پیام نور، ایران

2 دانشجوی دکتری گروه علوم جغرافیای دانشگاه خوارزمی تهران. ایران

10.22034/grd.2025.22104.1632

چکیده

به منظور بررسی شرایط جوی حاکم بر رخداد گردوخاک‌های شدید جنوب شرق ایران از داده‌های 12 ایستگاه همدیدی واقع در منطقه طی بازه زمانی 2000 تا 2020 میلادی استفاده شد. برای شناسایی دوره‌های همراه با گردوخاک شدید دید افقی زیر 200 و 100 متر برای هر یک از ایستگاه‌ها انتخاب شد. پس از شناسایی دوره‌های غبارآلود منطقه، برای تحلیل شرایط جوی با مراجعه به مرکز میان مدت پیش‌بینی‌های جو اروپا (ECMWF) بخشERA5 با تفکیک افقی 0.25×0.25 درجه جغرافیایی مقادیر مولفه‌های مداری و نصف النهاری باد، ارتفاع ژئوپتانسیل و فشار تراز دریا اخذ گردید. برای شناسایی مراکز و مسیر انتقال گردوخاک نیز از مقادیر AOD سنجنده MODIS و مدل لاگرانژی پسگرد ذرات معلق (HYSPLIT) بهره‌گیری شد. نتایج نشان داد 3 الگوی هواشناختی غالب کنترل کننده وضعیت جوی در زمان رخداد این پدیده در منطقه می‌باشد. به‌صورتی که با حاکمیت جریان شمالی در منطقه و افزایش سرعت باد در قسمت‌هایی از ایران مرکزی و شرق و شمال شرق ایران و با تقویت پرارتفاع تراز میانی ایران و تشکیل هسته تاوایی منفی و از طرفی تشکیل سلول کم ارتفاع در قسمت‌های جنوبی افغانستان و شمال پاکستان شرایط برای برداشت و انتقال ذرات به منطقه فراهم می گردد. وجود یک جریان زوجی که حاصل برهکنش جریان چرخندی و واچرخندی در منطقه بوده سبب رخداد گردوغبار در منطقه شده است که با حاکمیت جریانی جنوبی همراه می‌شود، ذرات گردوخاک را از روی تنگه هرمز به منطقه انتقال می‌دهد.

کلیدواژه‌ها

موضوعات

عنوان مقاله [English]

Investigating the atmospheric mechanism of severe dust events in southeast Iran

نویسندگان [English]

  • Tahmine chehreara ziabari 1
  • somayeh hajivand paydari 2
1 Assistant Professor, Department of Geography, Payam Noor University, Iran.
2 Ph.D student of Department of Geography, Kharazmi University, Tehran. Iran.
چکیده [English]

1. Introduction



Dust is one of the common phenomena in arid and semi-arid regions. This phenomenon annually introduces several million tons of soil into the atmosphere (Broumandi and Bakhtiarpour, 2015).

which has an important role in the climate system, atmospheric radiation, and hydrological cycle Alizadeh (Choobari et al., 2014; Shao et al., 2011).

A dust storm is a complex process that is under the interaction of atmospheric systems and is caused by conditions such as high wind speed, bare soil, and dry air (Broghani et al., 2016).

In recent years, pollution caused by dust particles has become an environmental problem, especially in developing countries.

Investigations of the meteorological statistics of Zabul, Zahedan, Mirjaveh, and Khash stations, which are located in the northern half of Sistan and Baluchistan province, showed that whenever there is a thermal low-pressure system in the Sistan plain region, it leads to the occurrence of dust storms and Sand has increased rapidly and dust particles from the dry and clay soils of Sistan region remain suspended for hours in the skies of Zahedan, Mirjaveh and Khash cities (Shahriari and Mohammadi, 2014).









2. Research Methodology



To investigate dusty days in the southeast of Iran, the data from 12 synoptic stations located in the region from 2000 to 2020 were used. The World Meteorological Organization definition was used to determine dusty days.

According to the definition of this organization, the occurrence of dust in terms of horizontal visibility is divided into four categories: weak dust with visibility less than 10 km, moderate dust with visibility between 1 and 10 km, severe storm with visibility between 200 and 1000 meters and very severe storm with less visibility. It is divided into 200 meters (Kaskautis, 2007).

Since the data collected in the mentioned stations are monitored for 3 hours and 8 times a day, first, in general, in all hours in the mentioned period, the frequency of all the dust particles reported by the meteorological stations is recorded and then the storm Those whose horizontal visibility was below 200 and 100 meters and were reported in more than 70% of the stations were classified.

3. Results and discussion

The obtained results have shown that, in the first pattern, a deep trough with a northeast-southwest axis has been established over central Iran, and at the same time, a strong positive eddy current has covered the east and center of Iran.

The existence of such a strong instability in the region has caused a strong pressure gradient to occur in the lower levels of the atmosphere, and as a result, it has led to the rise of dust from the dry areas and its flow into the hole of central Iran.

In the second model, a ridge with a height of 5,760 geopotential meters is located in central Iran, which caused the negative flow to occur from the southern slopes of Alborz to the southern Oman Sea.

The support of this eddy current in the region is associated with the eddy current located in the eastern half of the country, which continues from the east of Razavi Khorasan to the northeast of Sistan and Baluchistan. On the western side of the mentioned ridge, a 15-degree geographical trough has been created, which covers western Iran with a north-south axis.

This situation plays an important role in intensifying the counterclockwise flow over central Iran. The third pattern can also be recognized by the high ridge formed in the country.

In this system, the dominance of negative convection flow has caused the transfer of dust particles from areas with maximum negative convection.

In this way, with the increase of negative convection, which is associated with a small core over the northeast of Kerman, the currents entering the Jazmurian hole have become northeast, and this has played a key role in the transfer of particles from desert areas to the region.

Also, by examining the wind vector, it was observed that most of the currents are from north to south, which affects most of the western areas of Pakistan.

On the west side of Khorasan, a core of maximum velocity has been formed, which is determined by checking the direction of the airflow, which is associated with the intensity of this wind and its convergence in the central Iran region, the Jazmorian crater with periodic dust clouds with low horizontal visibility.

4. Conclusion

Dust centers can be divided into four areas based on AOD values and air mass tracking.

Thus, in the first pattern, the main dust transferred to the region can be referred to as the deserts of central Iran the southern regions of Khorasan, and the desert plain.

In the second pattern, most of the dust enters the region from the north and northwest of Afghanistan.

The third pattern is a pair, so that two northerly currents originate from Afghanistan and its northern regions, and the other enters the region from the Arabian Peninsula, in the southeastern parts of Iran, these two air masses converge, and dust flows and accumulates. accept

Based on the research of Lotfi Nesab et al. (1400) and Soleimani Sardo et al. (1400), the dust in the southeast of Iran has a different atmospheric structure such as northern currents. It has a border and cross-border origin, which was well mentioned in the present research.

کلیدواژه‌ها [English]

  • Severe dust
  • weather patterns
  • northerly flow
  • southeast Iran

مراجع

Alijan , B; raispoor, K. (2011). Statistical, Synoptical analysis of Sand Storms in SE Iran (Study Case: Region of Sistan). Arid Regions Geographic Studies; 2 (5):107-130. (In persian)
AlizadehChoobari, O., Zawar-Reza, P., Sturman, A., (2014). The global distribution of mineral dust and its impacts on the climate system: A review. Atmospheric Research 138(1), 152-165.
Bagherabadi, R., & Moeinaddini, M. (2021). Dust storms directional source identification of Karaj. Journal of Climate Research1400(47), 141-155. (In persian)
Boroghani, M., pourhashemi, S., zanganeh Asadi, M., & Moradi, H. (2017). Dust Source Identification in the Middle East by Using Remote Sensing. Journal of Natural Environmental Hazards6(11), 101-118. doi: 10.22111/jneh.2017.2959.(in persian)
Boroughani M, Mirchooli F, Mohammadi M. (2022) Dust source mapping using satellite imagery and machine learning models. Arid Regions Geographic Studies; 12 (47):1-13. (In persian)
Boroughani, M, Pourhashemi, S, Hashemi, H, Salehi, M, Amirahmadi, A, Asadi, M. A. Z, & Berndtsson, (2020). Application of remote sensing techniques and machine learning algorithms in dust source detection and dust source susceptibility mapping. Ecological Informatics, 56, 101059
Broomandi P, Bakhtiar Pour A. Dust Source Identification Using Physical- Chemical Characterization and Numerical Modeling in Masjed Soleyman. ijhe 2017; 9 (4) :517-526.(in persian)
Dayan, Koch.J, (1986),A Synoptic analysis of the meteorological conditions affecting dispersion of pollutants emitted from tallstacksin the coastal plain of Israel, pp : 537 – 543.
Draxler, R. Gillette, A. Kirkpatrick, Heller, J. 2001. Estimating PM10 air concentrations from dust storms in Iraq, Kuwait and Saudi Arabia. Atmospheric Environment Vol. 35. Pp: 4315-4330.
Draxler, R. Hess, G. D. An overview of the HYSPLIT_4 modeling system for trajectories, dispersion and 1998. Australian Meteorological Magazine. Vol. 47. Pp: 295-308.
Draxler, R. Stunder, B. Rolph, G. Stein, A. Taylor, A. 2009. Hybrid single-particle Lagrangian integrated trajectories 4 user's guide. NOAA Tech. Memo, ERL-ARL.
Draxler, R.R., G.D.Hess. (1997). Description of the HYSPLIT_4 Modeling System. NOAA Technical Memorandum.ERL ARL. 224: 1-25.
Garofalide, S., Postolachi, C., Cocean, A., Cocean, G., Motrescu, I., Cocean, I., ... & Leontie, L. (2022). Saharan Dust Storm Aerosol Characterization of the Event (9 to 13 May 2020) over European AERONET Sites. Atmosphere, 13(3), 493.
Gholami, H, Mohamadifar, A, Rahimi, S, Kaskaoutis, D. G, & Collins, A. L. (2021). Predicting land susceptibility to atmospheric dust emissions in central Iran by combining integrated data mining and a regional climate model. Atmospheric Pollution Research, 12 (4), 172-187.
Goudie and Middleton, (2002), Saharan dust storms, nature and consequences, Earth science review, pp : 56.
A, Grant.M, tanish A, (2001), Inter-regional transport of Australian dust storms Soil erosion reSearch for the 21th century , pp : 28.
Jalali, N., Iranmanesh, F., & Davoodi, M. (2017). Identification on dust storm sources and their affecting areas in south-west provinces of Iran, using MODIS image. Watershed Engineering and Management9(3), 318-331. doi: 10.22092/ijwmse.2017.112374.(in persian)
Jin, Q., Yang, Z. L., & Wei, J. (2016). Seasonal responses of Indian summer monsoon to dust aerosols in the Middle East, India, and China. Journal of Climate, 29(17), 6329-6349.
Kang, L.; Huang, J.; Chen, S.; & Wang, X. ; ”Long-term trends of dust events over Tibetan Plateau during 1961–2010”. Atmospheric Environment, 125, 188-198,2016.
karegar M E, Bodagh Jamali J, Ranjbar Saadat Abadi A, Moeenoddini M, Goshtasb H. (2017). Simulation and Numerical Analysis of severe dust storms Iran East. Journal of Spatial Analysis Environmental hazarts; 3 (4) :101-119. (In persian)
Kaskaoutis, D.G., Kosmopoulos, P., Kambezidis, H.D., Nastos, P.T., 2007. Aerosol climatology and discrimination of different types over Athens, Greece based on MODIS data. Atmos. Environ. 41, 7315–7329.
Khosravi, M. (2005). Research project: ecological and environmental effects of 120-day winds in Sistan. Research Institute of Earth Sciences and Geography. (In persian)
Khosravi, M. (2010). Investigating the vertical distribution of dust caused by storms in the Middle East using the NAAPS model, case: Sistan, Iran.  4th International Congress of The Islamic World Geographers. (in persian)
H, Alpert.p, (2005), Synoptic of dust transportation days from Africa toward Italy and central Europe, pp : 1 – 14.
Lotfinasabasl, S., Gohardoust, A., Dargahian, F., & Khosroshahi, M. (2022). Analysis of dusty and erosive winds in Kerman province in order to provide a calendar for forecasting and managing dust control. Iranian Journal of Forest and Range Protection Research19(2), 179-211. doi: 10.22092/ijfrpr.2021.352899.1458. (In persian)
Mallia, D. V., Kochanski, A., Wu, D., Pennell, C., Oswald, W., & Lin, J. C. (2017). Wind-blown dust modeling using a backward-Lagrangian particle dispersion model. Journal of Applied Meteorology and Climatology, 56(10), 2845-2867.
Mofidi, A; Kamali, S; Zarrin, A. (2013). Evaluation of the RegCM4 model coupled with Dust module on identification of dust storm features over the Sistan region. Quarterly of Geography (Regional Planning) Vol 3, No 3, Summer 2013. (In persian)
Namdari, S; hajibeiglo, A; abazari, gh. (2021). Analysis of changes in Iran's internal dust centers in the last twenty years. Scientific Journal of Geography and Planning. Volume 25, Number 78, February 2021, page 345-361. (In persian)
Shahriary, A. (2016). Trend Analysis the Number of Dusty Days in The Sistan and Baluchistan Province (IRAN) Using Non-Parametric Statistics. Journal of Water and Soil Conservation, 22(4), 253-260. (In persian)
Shao, Y., Wyrwoll, K.H., Chappell, A., Huang, J., Lin, Z., McTainsh, G.H., (2011). Dust cycle: an emerging core theme in Earth system science. Aeolian Research 2(4), 181–204.
Soleimani Sardoo, F., Hosein Hamzeh, N., Karami, S., Nateghi, S., & Hashemi nezhad, M. (2022). Emission and transport of dust particles in Jazmourian basin (Case study: Dust storm 24 to 26 November 2016). Journal of Climate Research1400(48), 41-54. (In persian)
Tan, S., Chen, B., Wang, H., Che, H., Yu, H., & Shi, G. (2022). Variations in Aerosol Optical Properties over East Asian Dust Storm Source Regions and Their Climatic Factors during 2000–2021. Atmosphere, 13(6), 992.
Wang W, (2005), A synoptic model on east Asian dust emission and transport , Atmospheric science and air quality conferences china , pp : 13.
Q. and Shaoyinshi, (2001), Variations of the dust storm in china and its climate control, journal of climate , pp : 15 .
کاوش های جغرافیایی مناطق بیابانی
دوره 12، شماره 2
اسفند 1403
صفحه 77-94

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