Analyzing the role of thermal and dynamic cyclone in dust storms at western Iran

Document Type : Research Paper

Authors

1 PhD of synoptic climatology, Department of Physical Geography, University of Tehran, Tehran, Iran

2 Professor, Department of Physical Geography, University of Tehran, Tehran, Iran

3 Associate Professor, Institute of Geophysics, University of Tehran, Tehran, Iran.

Abstract

1. Introduction



The undeniable connection between interannual changes in atmospheric circulation patterns and the dust cycle is clear. One of the most important atmospheric patterns in the dust cycle, especially in the rise and early stages of dust storms, is the activity of cyclones. In the Middle East region and especially in the Mediterranean, studies indicate the effectiveness of climatic variables (such as wind, pressure, temperature, cloudiness, precipitation, thunderstorms, floods, waves, dust storms, avalanches) from Formation and passage of cyclone disturbances. The age of studies related to the discussion of cyclogenesis in the Mediterranean region dates back to the middle of the 20th century the affectability of Syria, Iraq, Iran and other countries in the region from the cyclones of Mediterranean is clear. In cases where there is not enough moisture to cause precipitation, the cyclone mechanism acts as a determining factor in collecting and transporting dust from susceptible areas. Sometimes they create big and historic storms that, depending on their path, can severely affect areas even far away from the dust sources.

2. Research Methodology

In order to identify dust storms, in this study, the data related to horizontal visibility and the code of phenomena in the current weather for the time period of 1987-2022 have been used in 33 synoptic stations in Iran. The above data was taken from Iran Meteorological Organization. An event of dust storm is considered a dusty day if at least once a day the horizontal visibility in a station becomes less than or equal to 1 km due to dust in suspension in the present weather phenomenon (the synoptic code 06 is considered which represents dust in suspension). Then Considering the above conditions in the last three decades (1987-2022), a total of 229 dust storm events (391 dust storm days) were identified and in order to achieve the circulation patterns of the identified days, the sea level pressure map at 00, 06, 12, and 18 hours of global coordination, as well as the geopotential height map at the level of 500 hpa, were drawn and analyzed.

3. Results and discussion



Among all the investigated events, 47 events were caused by dynamic cyclone that occurred in all seasons. 18 occurrences have been the result of the formation of thermal cyclone, in this case, occurrences have been observed in all seasons, although with a very low frequency in the autumn season. Analysis of dynamic cyclone indicated in terms of the time of occurrence in a year, only 7 cases occurred in the hot season, 6 cases in the cold season, and the rest in the spring and autumn seasons. So that about 70% of the events related to dynamic cyclone occurred in the months of March to June, of which half of this percentage is related to the month of April.

Out of the 47 cases of storms caused by dynamic cyclone, about 45% of the storms were one-day events, which covered less than 10 stations in the west and southwest of the Iran. Almost 40% of the incidents have lasted for 2 days, and 4 storms in 2010-2012 have reached a significant extent. In 10% of the cases, the duration of the dust storm was 3 days, and two three-day storm in 2009 and 2012 covered a larger area of the Iran. Storms with a longer time period including 4 and 5 days have been observed only once in the studied period. The most occurrences of dynamic whirlwinds occurred in 1994, 2007, 2008 and 2010.

In the thermal cyclone, the maximum frequency was related to 2008. In nearly 60% of cases, the thermal cyclone has formed in the southeast of Iraq, southwest of Iran, Kuwait, northeast of Arabia and the north of the Persian Gulf. In other cases, a thermal cyclone has appeared on the border between Iraq and Saudi Arabia. Storms caused by thermal cyclones in the region have lower intensity than storms caused by dynamic cyclones. The centers located in the southern half of Iraq, northern Saudi Arabia, Kuwait and southwestern Iran have been more effective in the occurrence of dust in these sources than other parts in the region.



4. Conclusion

The most occurrences of dynamic cyclone were in 1994, 2007, 2008 and 2010. In half of the cases, the cyclone created in the central areas of Iraq, especially the central lakes of Tharthar, Rezazah and Habaniyya, has caused dust storms in the region. In 25% of the storms caused by dynamic cyclone, the cyclone formed in northwestern Iraq-northeastern Syria was the main cause of dust rise. In about 17% of cases, the cyclone formed in the southeast of Iraq-southwest of Iran-Kuwait has caused a dust storm. In the remaining 7%, dynamic cyclone in northern Iraq or northern Arabia caused a dust storm. In the storms caused by the occurrence of dynamic cyclone in the region, the most dust rise was from the western and southwestern centers in the country of Iraq. Around the central lakes and especially Tharthar lake, 40% of the dust storms have had this type of effect. In addition to the importance of the role of the pattern of the upper levels on the strengthening of the surface cyclone, the mechanism of dust rising in the surface swirl facilitates the entry of dust to the upper surfaces and results in more dust transfer through these surfaces.

In the thermal cycle, the maximum frequency was in 2008. In nearly 60% of cases, the thermal cyclone has formed in the southeast of Iraq, southwest of Iran, Kuwait, northeast of Arabia and the north of the Persian Gulf. Storms caused by thermal cyclones in the region have lower intensity compared to storms caused by dynamic cyclones. The sources located in the southern half of Iraq, northern Arabia, Kuwait, and southwestern Iran have been more effective in raising dust in these sources than other regions.

Keywords

Main Subjects

References

Al-Abbasi, K. A., Labban, A. H., & Awad, A. M. (2023). Synoptic characteristics of the spatial variability of spring dust storms over Saudi Arabia. Atmósfera, 37.
Alijani, B.,( 2009). Synoptic Climatology, SAMT Publication. [In persian]
Alizadeh, T. and Rezai Banafsheh, M. and Sharifi, R. (1400). Tracking and simulating dust storms at different levels of Kermanshah atmosphere using HYSPLIT and WRF-chem model, case study: dust storm October 26-28, 2018. Environmental Science Studies, 6(4), 4266-4279. [In persian]
Alizadeh-Choobari O, Ghafarian P, Owlad E. (2016). Temporal variations in the frequency and concentration of dust events over Iran based on surface observations. International Journal of Climatology. 36, 2050-206.
Al-Khulaifawi, I.A., Ioshpa, A., (2024), Monitoring of monthly dynamics of thunderstorm activity in Iraq. Izvestiya of Saratov University. Earth Sciences, 24(1), 4-10.
Al-Mutairi, M., Abdulhaleem L., Abdeldym, A., Alkhouly, A., Abdel Basset, H., Morsy, M., (2023), Diagnostic Study of a Severe Dust Storm over North Africa and the Arabian Peninsula, Atmosphere 14(2): 196.
Al-Ourabi, H., & Sharba, H. (2019). Synoptic study of dust storm over Middle East during September 2015. Damascus University Journal for the Basic Sciences, 35(1), 111-132.
Azizi Gh., Shamsipour A.A., Miri M., Safarrad T. (2012). Synoptic and remote sensing analysis of dust events in southwestern Iran. Nat Hazards. 64, 1625–163.
Azizi, GH. and Shamsipour, A.A. and Miri, M. and Safarrad, T. (2011). Statistical –synopsis analysis of the dust phenomenon in the western half of Iran. Ecology, 38(63), 123-134. [In persian]
Beyranvand A., Azizi Gh., Alizadeh-Choobari O., Darvishi Boloorani A. ( 2019). Spatial and temporal variations in the incidence of dust events over Iran. Nat Hazards. 97, 229–241.
Beyranvand, A. (2021). The impact of land-use/land cover and synoptic patterns changes on the dust Sources in West Asia, Supervisor: Gh. Azizi, PhD Thesis, Department of Geograghy, University of Thenran. [In persian]
Beyranvand, A., Azizi, G., Alizadeh, O., Darvishi Boloorani A. (2023). Dust in Western Iran: the emergence of new sources in response to shrinking water bodies. Sci Rep 13, 16158. https://doi.org/10.1038/s41598-023-42173-3
Cao H., Amiraslani F., Liu J., Zhou N. (2015). Identification of dust storm source areas in West Asia using multiple environmental datasets. Science of the Total Environment. 502, 224–235.
Darvishi Boloorani A., Kazemi Y., Sadeghi , Nadizadeh Shorabeh  S., Argany M. (2020). Identification of dust sources using long term satellite and climatic data: A case study of Tigris and Euphrates basin. Atmospheric Environment, 224, 117299.
Darvishi Boloorani A., Nabavi S.O, Bahrami H.A., Mirzapour F., Kavosi M., Abasi E., Azizi R. ( 2014). Investigation of dust storms entering western Iran using remotely sensed data and synoptic analysis. Journal of Environmental Health Science & Engineering. 12, 1-12.
Fallah Ghalhori, GH. A., (2011), Essentials and fundamentals of meteorology, Climatology Research Institute Publication. [In persian]
Fiedler, S., Schepanski, K., Knippertz, P., Heinold, B., & Tegen, I. (2013). How important are cyclones for emitting mineral dust aerosol in North Africa? Atmospheric Chemistry & Physics Discussions, 13(12).
Fu, P., Huang, J., Li, C., Zhong, S., (2008). The properties of dust aerosol and reducing tendency of the dust storms in northwest China. Atmospheric Environment 42, 5896e5904.
Gómez, M., Álvarez, E., Carretero, J. C., Pérez, B., Rodríguez, I., Serrano, O., & Sotillo, M. G. (2002). Oceanographic and atmospheric analysis of the 10–16 November 2001 Storm in the Western Mediterranean. 4th EGS, 85, 5.
Jansa, A., Alpert, P., Buzzi, A., Arbogast, P., Doyle, J., Hoinka, K. P. & Speranza, A. (2001). Cyclones that Produce High Impact Weather In The Mediterranean, MEDEX (Phase 1).
Khoshakhlagh, F., Najafi, M. S., & Samadi, M. (2012). An Analysis on Synoptic Patterns of Springtime Dust Occurrence in West of Iran. Physical Geography Research Quarterly, 44(2), 99-124. [In persian]
Klein, W. H. (1957). Principal tracks and mean frequencies of cyclones and anticyclones in the Northern Hemisphere. US Weather Bureau Research Paper.
Kok, J. F., Adebiyi, A. A., Albani, S., Balkanski, Y., Checa-Garcia, R., Chin, M., ... & Wan, J. S. (2021). Contribution of the world's main dust source regions to the global cycle of desert dust. Atmospheric Chemistry and Physics, 21(10), 8169-8193.
Lashkari, H. (2014). Dynamic Climatology, Shahid Beheshti University Publications, first edition. [In persian]
Lashkari, H. and Saboui, M. (2012). Synoptic analysis of dust storm patterns in Khuzestan province. Scientific-Research Quarterly of Geographical Information "Sephar", 22 (87), 32-38. [In persian]
Lionello, P., Bhend, J., Buzzi, A., Della-Marta, P. M., Krichak, S. O., Jansa, A., ... & Trigo, R. (2006). Cyclones in the Mediterranean region: climatology and effects on the environment. In Developments in earth and environmental sciences (Vol. 4, pp. 325-372). Elsevier.
Mahowald, N., Albani, S., Kok, J.F., Engelstaeder, S., Scanza, R., Ward, D.S., Flanner, M.G., (2014). The size distribution of desert dust aerosols and its impact on the Earth system. Aeolian Res. 15, 53-71.
Mashat, A-W.S, Alamoudi, A. O., Awad, A. M., Assiri ME. (2017). Synoptic characteristics of dusty spring days over central and eastern Saudi Arabia, Air Qual. Atmos. Health.
Miller, R.L., Knippertz, P., Pérez García-Pando, C., Perlwitz, J.P., Tegen, I., (2014). Impact of Dust Radiative Forcing upon Climate, in: Knippertz, P., Stuut, J.-B.W. (Eds.), Mineral Dust: A Key Player in the Earth System. Springer Netherlands, Dordrecht, pp. 327-357.
Miri, M. and Azizi, Gh. and Shamsipour, A.A. (2013). Identification of summer and winter patterns of dust entering western Iran. Geography and environmental planning. 25(4). 203-220. [In persian]
Moridnejad, A., Karimi, N., Ariya, P.A. Newly desertified regions in Iraq and its surrounding areas: Significant novel sources of global dust particles. Journal of Arid Environments, 116, 1-10.
Nabavi, S.O., Haimberger, L., Samimi, C. (2016). Climatology of dust distribution over West Asia from homogenized remote sensing data. Aeolian Res. 21, 93–107.
Parolari, A. J., Li, D., Bou-Zeid, E., Katul, G. G., & Assouline, S. (2016). Climate, not conflict, explains extreme Middle East dust storm. Environmental Research Letters, 11(11), 114013.
Pettersen, S. (1956). Weather analysis and forecasting. Mac Graw Hill, New York.
Radinović, D. (1987). Mediterranean cyclones and their influence on the weather and climate. World Meteorological Organization.
Raispour, K. (2013). Synoptic, satellite climatology of dust storms in the west and southwest of Iran, doctoral dissertation in climatology, Supervisor: Mahmoud Khosravi, University of Sistan and Baluchistan. [In persian]
Raispour, K. and Khosravi, M. and Taosi, T. and SharifiKia, M. (2012). Investigating the role of cut off low pressure systems in the formation of widespread dusts in the southwest of Iran, the first national hydrometeorological conference, Kerman. [In persian]
Raispour, K., Khosravi, M., Tavosi, T., Sharifikiya, M., (2013). Studying the role of cut off low systems information of broad dusts in weastern south of Iran. The first national climatology conference of Iran. Kerman. Iran. [In persian]
Rasouli, A.A. and Sari Saraf, b. and Mohammadi, G.H. (1390). Trend Analysis of climatic phenomenon of dust in the west of the country in the last 55 years by using non-parametric statistical methods, Natural Geography, fourth year, number 11-16. [In persian]
Shao, Y.P., et al., (2011). Dust cycle: An emerging core theme in Earth system science. Aeolian Research 2, 181-204.
Solomos, S., Ansmann, A., Mamouri, R. E., Binietoglou, I., Patlakas, P., Marinou, E., & Amiridis, V. (2017). Remote sensing and modelling analysis of the extreme dust storm hitting the Middle East and eastern Mediterranean in September 2015. Atmospheric Chemistry and Physics, 17(6), 4063-4079.
Tavosi, T., Khosravi, M., Raispour, K., (2010). Synoptic analysis of dust storms at Khozestan. Geography and Development, 8(20), 98-117. doi: 10.22111/gdij.2010.600. [In persian]
Tavousi, T. and Khosravi, M. and Raispour, K. (1389). Synoptic analysis of dust systems in Khuzestan province. Geography and Development, 8(20), 97-118. [In persian]
Tavousi, T. and Zahrai A. (2012). Time series modeling of dust phenomenon in Ahvaz city. Geographical Research, 28(2): 159-170. [In persian]
Tegen, , Fung,  I.,  (1994). Modeling of   mineral dust   in the atmosphere:  sources, transport, and optical thickness. Journal of Geophysical Research 99, 897e914.
Yu, Y., Notaro, M., Liu, Z., Wang, F., Alkolibi, F., Fadda, E., Bakhrjy, F. (2015). Climatic controls on the interannual to decadal variability in Saudi Arabian dust activity: toward the development of a seasonal dust prediction model. Geophys. Res. 120, 1739–1758.
Zoljoodi M., Didevarasl A., Ranjbar Saadatabadi A. (2013). Dust Events in the Western Parts of Iran and the Relationship with Drought Expansion over the Dust-Source Areas in Iraq and Syria. Atmospheric and Climate Sciences. 3, 321-336.
Zulfighari, H. and Abedzadeh, H., (2004). Synoptic analysis of dust systems in western Iran, Geography and Development, No. 6, 173-187. [In persian]
Zulfighari, H. and Masumpour Samakosh, J. and Shaygan Mehr, sh. and Ahmadi, M. (2016). Synoptic analysis of dust storms in the western regions of Iran during the years 1384 to 1388 (case study: the widespread wave of July 1388). Geography and Environmental Planning, (3)22, 3-17. [In persian]
The Journal of Geographical Research on Desert Areas
Volume 11, Issue 2
May 2024
Pages 165-182

Files

Share

How to cite

Statistics