بررسی خصوصیات کانی‌شناسی ریزگردهای حاصل از فرسایش بادی خاکهای ساحل شرقی دریاچه ارومیه با استفاده از تونل باد مدار بسته

نویسندگان

1 دانشجوی دکتری مدیریت منابع خاک، دانشکده کشاورزی، دانشگاه تبریز

2 استاد گروه علوم و مهندسی خاک، دانشکده کشاورزی، دانشگاه تبریز

3 دانشیار گروه علوم و مهندسی خاک، دانشکده کشاورزی، دانشگاه تبریز

چکیده

امروزه عوامل مختلفی دریاچه ارومیه (بزرگترین دریاچه‌ آب شور خاورمیانه) در شمالغرب ایران را در معرض خشکی و فرسایش‌ بادی قرار داده که نتیجه آن بروز طوفان‌های ریزگرد است. شناسایی ماهیت این ریزگردها در ارائه راهکارهای مقابله با بحران حائز اهمیت بوده و بدین منظور، سه بخش مستعد برای تولید ریزگرد از ساحل شرقی دریاچه ارومیه انتخاب و هر بخش براساس ارتفاع از سطح آزاد آبها به دو سطح تقسیم گردید. نمونه‌های خاک به سینی‌های تونل باد مدار بسته، منتقل و شبیه‌سازی فرسایش بادی با اعمال حداکثر سرعت باد 45 متر بر ثانیه به مدت 15 دقیقه بطور یکنواخت در تمام ارتفاعات انجام گردید. با به تله انداختن ریزگردها و بررسی خصوصیات کانی‌شناسی آنها به روش آنالیز XRD و با استفاده از نرم افزار High Score، کوارتز، کلسیت، هالیت و ژیپس بعنوان کانی‌های غالب شناسایی شدند. از میان این کانی‌ها، کوارتز بالاترین درصد را داشته و با توجه به فاصله کم برای انتقال در تونل باد دور از انتظار نمی باشد. نتایج تجزیه واریانس نیز نشان داد که اثر لایه بر کانی کوارتز (p≤0.99) و اثر بخش بر کانی کلسیت (p≤0.95) معنی‌دار است. حضور کلسیت بعنوان کانی غالب در نمونه‌ها بویژه بخش 2 می‌تواند اعلام خطری برای آلودگی جوی از طریق حمل آلاینده‌ها و انتقال آنها باشد.در این تحقیق با بررسی عمل انتخابی فرسایش بادی بر خاکهای منطقه و مطالعه کانی‌شناسی خاکهای منشاء ریزگردها، می‌توان نوع کانی‌های موجود در ارتفاعات مختلف جوی را پیش-بینی نمود زیرا، نوع کانی‌‌ غالب در ارتفاعات مختلف جوی با خاکهای منشاء متفاوت نیستند.

کلیدواژه‌ها

موضوعات

عنوان مقاله [English]

Investigating the Mineralogical characteristics of Dusts Resulted from Wind Erosion of Urmia Lake East Shore Soils using a closed circuit Wind Tunnel

نویسندگان [English]

  • elham ganbarie 1
  • aliasghar jafarzadeh 2
  • shahin oustan 2
  • Abbas Ahmadi 3
  • Farzin Shahbazi 2
1 agriculture department of tabriz university
2 University of Tabriz Academic Member
3 Associated Professor
چکیده [English]

Abstract
Background and Objectives:
Urmia Lake is the largest saltwater in the Middle East, which has been located in the northwest of Iran. Nowadays, various factors have exposed it to dryness and wind erosion, the result of which is the increase in soil salinity, the thinning of solute crystals, and the occurrence of dust storms. Identifying the nature of these dusts specially the mineralogy of them is important in providing solutions to deal with the crisis. Investigating the characteristics and mineralogy of dusts in the region are useful in predicting and controlling ways to reduce their damages, and dust mineralogy is a practical method to determine their origin. In other words, the deposition of dust in different areas can affect the nearby ecosystems by making changes in the texture, composition of elements and even the acidity of the soils of the affected areas. The source of dust is very important in the mineralogy of sedimentary particles and depends on various factors such as geology and soil characteristics as well as climatic conditions. Also, the height of atmosphere which the dusts are there can be useful in studying the affect of mineralogy in this height.
Methodology:
For this purpose, three flat sites without vegetation and prone to fine dust production were selected from the eastern shore of Urmia Lake, and each site was divided into 3 layers based on the height from sea level, but the first layer was omitted from the studying areas because of the high soil moisture due to low distance to lake, which results in decreasing dust production by this layer, and eventually 2 random samples (0-5 cm) were picked up from each layer. This research work carried out based on 12 selected soil samples from 3 sites and their layers. The soil samples from 0 to 5 cm depth as a surface soil of layers were transferred to trays with dimensions of 3 x 40 x 30 cm in the wind tunnel of agriculture faculty of Tabriz University, with 370cm length, 50cm width and 70cm height, and wind erosion was simulated by applying the maximum wind speed of 45 meters per second to it was done for 15 minutes at each height. Then, the dust particles released at 2 heights of the wind tunnel (10 and 30 cm from the floor of the device) and the control soil sample were subjected to XRD analysis and the obtained diffractions were interpreted using High Score software. Finally, statistical analysis was performed using a nested design to find the effect of factors such as the location, layer and height of the wind tunnel on the content of minerals in windblown dust.
Findings and Conclusion:
The obtained results showed that the dominant minerals in the most dust samples, were quartz, calcite, halite and gypsum with the highest average percent of quartz, because of the widespread occurrences of this mineral in the earth crust. The statistical analysis results revealed the significant effect of layer on quartz at the p<0.01 level, but the effect of site on calcite was significant at the p<0.05 level. But the maximum amount of quartz appeared in layer 2 of site 2, while its minimum amount has observed in layer 2 of site 1. The maximum and minimum amount of calcite was found in site 2 and 3 respectively, but predominance of quartz in the dust samples can be attributed to the wind blow within a short distance. This differences can be related to the nature of the parent materials of sites from which soils were derived. The presence of calcite as the main mineral in samples is due to study area temperature and precipitation increase and decrease respectively, which cause lake dryness, while gypsum and halite are produced in result of chemical equilibrium process and distribute in salty soils. Gypsum also can be produced during the reaction of calcite and sulfates of sea salts. The dryness of the lake also results in rising the gypsum minerals from dried floor of lake. Also, the presence of halite is affected by Urmia Lake salts that remain after water evaporation in dried land as a main mineral in soil and dust samples of affected lands.
Key Words: XRD analyze, Wind erosion, Mineralogy, Wind tunnel, Urmia Lake.

کلیدواژه‌ها [English]

  • XRD analyze
  • Wind erosion
  • Mineralogy
  • Wind tunnel
  • Urmia Lake

مراجع

Anonymous, 2004. Meteorological Organization of I.R. of IRAN.
Attiya AA and Jones BG, 2020. Climatology of Iraqi dust events during 1980–2015. SN Applied Sciences 2(845):1-16.
Baghi M, Rashki A and Mahmoudi Garaei MH, 2020. Investigation of chemical and mineralogical properties of dust entering northwest Iran and its pathogenic potential. Journal of Geography and Environmental Hazards 9(1): 139-153.
Bashiri R and Souri B, 2016.  Physical and chemical properties studying of suspended particles greater than 10 micrometer in Kordestan province, west of Iran. Environment Science and Technology 18(3): 70-79. (In Persian with English abstract).
Beitlefteh R, Landi A, Hojati S and Sayyad Gh, 2015. Deposition rate, mineralogy and size distribution pattern of dust particles collected around the Houralazim marshland. Journal of Water and Soil 29:695-707. (In Persian with English abstract)
Buck BJ, King J and Etyemezian V, 2011. Effects of salt mineralogy on dust emissions, Salton Sea, California. Soil Science Society of America Journal 75:1971-1985.
Chakherlou S, 2020. Evaluating soil wind erodibility using satellite images and digital mapping in the east Shore of Urmia Lake. PhD Thesis, University of Tabriz. (In Persian with English abstract)
Díaz-Hernández JL, Martín-Ramos JD and López-Galindo A, 2011. Quantitative analysis of mineral phases in atmospheric dust deposited in the south-eastern Iberian Peninsula. Atmospheric Environment 45: 3015-3024.
Eswaran H and Gong ZT, 1991. Properties, genesis, classifcation and distribution of soils with gypsum. Pp. 89-119. In: Nettleton WD (Ed.) Occurrence, Characteristics, and Genesis of Carbonate, Gypsum, and Silica Accumulations in Soils. Vol.26, Soil Science Society of America, Inc.
Feng Q, Endo KN and Cheng GD, 2002. Soil carbon in desertified land in relation to site characteristics. Geoderma 106: 21–43.
Formento ML, Douglas TW and Burbank A, 2003. River response to an active fold-and-thrust belt in a convergent margin setting, North Island, New Zealand. Geomorphology 49:125-152.
Ganor E, Deutsch Y and Foner HA, 2000. Mineralogical composition and sources of airborne settling particles on Lake Kinneret (The Sea of Galilee), Israel. Water, Air and Soil Pollution 118:245-262.
Givi J and Abtahi A, 1985. Soil genesis as affected by topography and depth of soline and alkali groundwater under semiarid condition in southern Iran. Iran Agricultural Research 4: 11-27.
Glaccum RA and Prospero JM, 1980. Saharan aerosols over the tropical North Atlantic mineralogy. Marin Geology 37:295–321.
Grazulis S, Chateigner D, Downs R, Yokochi Y, Quiros M, Lutterotti L, Manakova E, Butkus J, Moeck P and LeBail A, 2009. Crystallography open database (COD) an open access collection of crystal structures. Applied Crystallography 42:726-729.
Jeong GY, 2020. Mineralogy and geochemistry of Asian dust: dependence on migration path, fractionation, and reactions with polluted air.Journal of Atmospheric Chemistry and Physics 20: 7411–7428.
Jiries A, El-Hasan T and Manasrah W, 2002. Qualitative evaluation of the mineralogical and chemical composition of dry deposition in the central and southern highlands of Jordan. Chemosphere 48:933-938.
Karimian B, Landi A, Hojati S and Ahadian J, 2009. Physicochemical and mineralogical characteristics of dust particles deposited in Ahvaz city. Iranian Journal of Soil and Water Research 47(1) 159-173. (In Persian with English abstract)
Karimian NA, 1992. Soil Chemistry, Tehran University Publication. (In Persian)
Lawrence CR and  Jason JC, 2009. The contemporary physical and chemical flux of aeolian dust: A synthesis of direct measurements of dust deposition. Chemical Geology 267: 46- 63.
Matthew DP, Eric PA, Micha JR and Richard P, 2015. Aerosol time-series measurements over the tropical Northeast Atlantic Ocean: Dust sources, elemental composition and mineralogy. Marine Chemistry 174:103–119.
Modaish AS, 1997. Characteristics and composition of the falling dust sediments on Riyadh city Saudi Arabia. Journal of Arid Environments 2(36):211-213.
Mojallali H, 1994. Mineralogical studying of salts in a chosen soil profile (Salorthids) as a function of seasonal balance of temprature in northwest of Texsas. Pp. 32-39. The forth Iranian Soil Science Congress. 18-20 September, Isfahan Industrial University, Iran. (In Persian with English abstract)
Moore D and Reynolds RC, 1989. X-ray Diffraction and Identification and Analysis of Clay Minerals. Pp. 387. Oxford University Press, New York.
Nickling W, 1978. Eolian sediment transport during dust storms: Slims River Valley, Yukon Territory. Canadian Journal of Earth Sciences 15:1069-1084.
Rashki A, Eriksson PG, Rautenbach CJ, Kaskaoutis DW, Grote DG and Dykstra J, 2013. Assessment of chemical and mineralogical characteristics of airborne dust in the Sistan region, Iran. Chemosphere 90(2): 227-236.
Satsangi PG and Yadav S, 2014. Characterization of PM2.5 by X-ray diffraction and scanning electron microscopy-energy dispersive spectrometer: Its relation with different pollution sources. International Journal of Environmental Science and Technology 11: 217–232.
Shahrabi M, 1994. The report of 1:250000 scale geological map of Urumia. Publication of Geological Survey and Mineral Expolaration Orginazation of Iran. (In Persian)
Singer A, Zobeck T, Poberezsky L and Argaman E, 2003. The PM10 and PM2.5 dust generation potential of soils/sediments in the southern Aral Sea basin, Uzbekistan. Journal of Arid Environments 54:705–728.
Soltani Sisi Gh, 2005. The report of 1:100000 scale geological map of Urmia. Publication of Geological Survey and Mineral Exploration Organization of Iran.(In Persian)
Tiangang Y, Siyu C, Jianping H, Xiaorui Z, Yuan L, Xiaojun M and Guolon Z, 2019. Sensitivity of simulating a dust storm over Central Asia to different dust schemes using the WRFChem model, Atmospheric Environment 15(207): 16-29.
Usher CR, Michel AE and Grassian VH, 2003. Reactions on mineral dust. Chemical Review 103(12):4883-4940.
Zarasvandi AR, 2009. Surveying the environmental effects of dusts phenomenon in Khuzestan province. Environment Protection Agency of Khuzestan Province. 3:277-279. (In Persian with English abstract).
Zhenxing Sh, Sandrine C, Junji C, Xiaoye Zh, Yuemei H, Annie G and Laurent G. 2009. Mineralogical characteristics of soil dust from source regions in northern China. Particuology 7: 507–512.
Zhiyuan H, Jianping H, Chun Z, Jiangrong B, Qinjian J, Yun Q, Ruby L, Taichen F, Siyu C and Jianmin M, 2019. Modeling the contributions of Northern Hemisphere dust sources to dust outflow from East Asia. Journal of Atmospheric Environment 6(14): 1352-2310.
دانش آب و خاک
دوره 33، شماره 4
دی 1402
صفحه 115-132

فایل ها

هم رسانی

ارجاع به این مقاله

آمار