Quaternary Journal of Iran

Geochemical Analysis of the Qarasu River Basin Rocks: Investigating Their Role in Heavy Metal Pollution of the Gorgan bedrock

Document Type : Original Article

Authors

Sara razavi 1
mohamad hashememamie 2
Homayoum khoshravan 3
Parvin Farshchic 4
Sayd Jamal sheikhzakariaee 5

1 PhD Student, Department of Earth Sciences, SR.C., Islamic Azad University, Tehran, Iran

2 Department of Earth Sciences, SR.C., Islamic Azad University, Tehran, Iran

3 Caspian Sea National Research Center, Water Research Institute, Ministry of Energy, Tehran,Iran

4 Assistant Professor, Faculty of Natural Resources and Environment, Islamic Azad University, Science and Research Branch, Tehran, Iran.

5 Faculty of Natural Resources and Environment, SR.C., Islamic Azad University, Tehran, Iran

10.22034/irqua.2025.2058584.1044
Abstract
Introduction:
The geochemical study of sediments in water basins such as rivers, estuaries, and seabeds can be an effective step in identifying the source and assessing the distribution model of environmental pollutants in the region. This research focuses on the geochemistry of rock units in the Qarasu River watershed and their contribution to the potential pollution of heavy metals in the sediments of Gorgan Bay. The schists in the area have a fine to medium grain size, and the original rock nature is preserved in most of them. The carbonate-clastic formations of Khush Yilagh and the carbonate of Lar are the most important sedimentary sequences in the studied area.
Method and Result:
 Thin section characteristics and field observations also indicate that most samples related to the Khush Yilagh formation consist of a carbonate matrix and clastic grains such as quartz and feldspar. The Lar formation is primarily composed of pure carbonate, including calcite and dolomite mineralogy. In the studied samples from this formation, rhombohedral dolomite crystals are well observed. 
Ultimately, the results of the geochemical data analysis showed that there is a significant similarity between sediment and rock samples, as well as between heavy metals in all three types of samples (rock, sediment, and water), indicating a common source for these metals. The concentrations of heavy metals in the studied samples are approximately: cobalt 1-27 (average 13), chromium 134-7 (average 88), copper 6-59 (average 32), nickel 1-76 (average 42), lead 1-49 (average 23), vanadium 8-185 (average 100), and zinc 9-157 (average 99) in ppm. 
Discussion:
The concentration of heavy metals gradually increases as one moves away from the river source towards the shores of Gorgan Bay. Overall, the main source of heavy metals is primarily the Gorgan schist and the Shamsak formation. Human involvement in the concentration of heavy metals in the Qarasu River and the shores of Gorgan Bay is very low and rare.
The geological units that are the most important study area with the greatest extent in the Qara Su watershed include the Gorgan schists, Khush Yalaq, Shamshek, and Lar. These units, due to their varying extents, are located at different distances from the riverbed. The Qara Su River and its various branches pass through these units and are often influenced by these substrates. This affects the sedimentary components of the riverbed and its geochemistry. In most cases, there is a positive correlation coefficient between the concentrations of heavy metals and the distance of the river from the geological units, with values above 0.5, indicating that a significant amount of heavy metals is controlled by the geological units of the region. Based on the data and evidence from this study, it can be stated that the main sources of cobalt and copper are from the Shamshek and Gorgan schist units, while the main sources of lead, chromium, nickel, vanadium, and zinc are supplied by the Shamshek, Lar, Gorgan schist units, and alluvial sediments. Although the primary cause of heavy metal accumulation in all samples is the geological units, for some heavy metals like chromium, vanadium, and zinc, anthropogenic factors are also significantly relevant.
Conclusion:
The chemical characteristics of water were examined, emphasizing elements and heavy metals, and the role of lithostratigraphic units in the pollution of elements and heavy metals in the Qara Su river (which subsequently leads to the pollution of the Gorgan Bay) was addressed. In Figure 7, a dendritic diagram has been drawn for rock samples. According to the diagram, except for calcium, elements can be divided into three groups. Magnesium and sodium each form a single-member group. However, in the most important and largest group, the heavy elements are observed together. This fact clearly indicates a common source for most of these elements (Olatunde et al., 2014; Zhang et al., 2016). In Figure 8, this diagram has also been drawn for the sediments of the Qara Su River. This diagram and the grouping relationships of the elements in it bear a strong resemblance to the clustering diagram of elements related to rock samples. As seen in the figure, in these samples, except for calcium, three distinct groups of elements can also be observed. Just like the rock samples, the two elements magnesium and sodium each form a group on their own. The largest and most important group in the clustering of elements in the rock samples, which is very similar to the rock sample, encompasses most elements, especially heavy elements."

Keywords

Pollutants
environment
geochemical heavy metals
Qarahsu
Iran

Subjects

باقری حسین، درویش بسطامی کاظم، شارمد ترانه، باقری زهرا، (1391). ارزیابی پراکنش آلودگی فلزات سنگین در خلیج گرگان . نشریه علمی - پژوهشی اقیانوس شناسی، شماره ۳ (۱۱) ، صص۶۵-۷۲
نجفی، ح، محمدپور، ط، (1391). مدل سازی کیفی رودخانه قرهسو با استفاده از مدل QUAL2K. اولین همایش ملی جریان و آلودگی آب، تهران، دانشگاه تهران، موسسه آب.
رزاقیان، ف، سبزی پور، ب، سارنگ، ا، (1394). مدل سازی کیفی رودخانه قره سو محدوده شهرستان با مدل QUAL2KW، دهمین کنگره بین المللی مهندسی عمران، تبریز، دانشگاه تبریز دانشکده مهندسی عمران.
میر محمد حسینی، ف، (1390). تدوین شاخص کیفیت آب برای رودخانه گرگان رود. پایان نامه کارشناسی ارشد، دانشگاه تهران، تهران.
عرفانی منش، م، افیونی، م، (1380). آلودگی محیط زیست آب و خاک. اتنشارات دانشگاه صنعتی اصفهان، 318 صفحه.
رجایی ق،حسن پورم، مهدی نژادم. ه، (1391). بررسی غلظت فلزات سنگین روی، سرب، کروم و کادمیوم در آب و رسوب خلیج گرگان و مصب رودخانه گرگانرود. تحقیقات نظام سلامت، شماره 8(5), صص. 748-756.
لالوئی، ف، روشن طبری، م، روحی، ق، تکمیلیان، ک، مخلوق، آ، گنجیان، ع، رستمیان، م.ت، فلاحی، م، محمدجانی، ط، سبک آرا، ج، تهامی، ف.، مکارمی، ع، میرزاجانی، ع.ر، کیهان ثانی، ع.ر. و واحدی، ف، (1383). هیدرولوژی و هیدروبیولوژی و آلودگی های زیست محیطی اعماق کمتر از 10 متر حوضه جنوبی دریای خزر. موسسه تحقیقات شیلات ایران، پژوهشکده اکولوژی دریای خزر. ساری. 420 ص.
قاسمی, حبیب اله, گراوند, مجتبی, حافظی مقدس, ناصر. (1391). ارزیابی ژئوشیمیایی و زیست محیطی فلزات سنگین در خاک های حاصل از شیست های گرگان. فصلنامه علمی-پژوهشی علوم زمین. شماره 22(86)، صص. 35-46.
 
Anazawa, K. et al., 2004, Heavy metal distribution in river waters and sediments around a "Fire Fly Village''. Shikoku, Japan: Application of Multivariate Analysis. Journal of. Analytical Science, 20, 79-84.
Baptista Neto JA, Smith BJ, McAllister JJ., 2000, Heavy metal concentrations in surface sediments in a nearshore environment, Jurujuba Sound, Southeast Brazil. Environ Pollut; 109(1), PP. 1-9.
Babaee H, Khodaparast H, Abedini A., 2007, Heavy metals measurements (Cd, Cu, Pb) in Anzali wetland surface sediments sigments. Iranian Scientific Fisheries Journal, NO. 16(1), PP. 9-17. [In Persian].
Bermejo.J.C.S., Beltran. R., Ariza. J.L.G., 2003, Spatial variations of heavy metals contamination in sediments from Odiel river (Southwest Spain),Environ Int,Vol:29, No:1, PP.69-77.
Baeyens,W. et al., 2005, Correlations, partitioning and bioaccumulation of heavy metals Between zone on the tropical southwest coast of India. Bulletin of the Geological Survey of Japan, NO.52(8), PP. 371-382.
Barandovski, L., Stafilov, T., Šajn, R., Frontasyeva, M. Andonovska, K.B., 2020. Atmospheric heavy metal deposition in North Macedonia from 2002 to 2010 studied by moss biomonitoring technique. Atmosphere (basel)., 1,1-23, 10.3390/atmos11090929.
Brusilovskii, S.A.; and Turchkina, N.M., 1976, Microelemnts in ground water and in sediments at the west coast of middle Caspian. In: Leontiev, O.K. and Maev. E.G. (EDs.). Comprehensive Investigation of the Caspian Sea, Moscow State University Publication, Moscow. NO.4, PP. 126-134.
Berkowitz B, Dror I, Yaron B., 2008, Contaminant Geochemistry: Interactions and Transport in the Subsurface Environment. Springer-Verlag Berlin Heidelberg, 412 p.
Cevik.F., Goksu.M.Z.L., Derici.O.B., Findik.O., 2009, An assessment of metal pollution in surface sediments of Seyhan dam by using enrichment factor, geoaccumulation index and statistical analyses,Environ. Monit. Assess, Vol:152,No.1-4, PP. 309-317.
Chester, R. and Hughes, M., 1967, A Chemical Technique for the Separation of Ferromanganese Minerals, Carbonate Minerals and Adsorbed Trace Elements from Pelagic Sediments. Journal of Chemical Geology. NO.2, PP. 242-262.
Davis, J.C., 1986. Statistics and data analysis in geology. Wiley International, New York. distribution and contamination in Beijing, China, Environment International,NO. 31(6), PP. 805-812.
Förstner, U.; Salomons, W., 1980, Trace metal analysis on polluted sediments. Part 1: assessment of sources and intensities, Environmental Technology Letters, NO. 1, PP. 494- 505.
Gaberšek, M. Gosar, M., 2021.Towards a holistic approach to the geochemistry of solid inorganic particles in the urban environment. Sci. Total Environ., 763, Article 144214, 10.1016/j.scitotenv.2020.144214
Gardiner, J., Mance, G., 1984, Water quality standards arising from European community directives. Water research center, No: 204.
Gerbersmann C, Heisterkamp M, Adams FC, Broekaert J., 1997,Two methods for the speciation analysis of mercury in fish involving microwave-assisted digestion and gas chromatography-atomic emission spectrometry. Analytica Chimica Acta NO. 350(3), PP. 273-85.
He, L.; Chen, G.; Wang, X.; Shen, J.; Zhang, H.; Lin, Y.; Shen, Y.; Lang, F.; Gong, C. 2024. Pollution Characteristics and Risk Assessment of Heavy Metals in the Sediments of the Inflow Rivers of Dianchi Lake, China. Toxics, 12, 322.
Huang, L., Rad, S., Xu, L., Gui, L., Song, X., Li, Y., ... & Chen, Z., 2020, Heavy Metals Distribution, Sources, and Ecological Risk Assessment in Huixian Wetland, South China. Water, NO.12(2), PP. 431.
Islam, M. S., Ahmed, M. K., Raknuzzaman, M., Habibullah-Al-Mamun, M., & Islam, M. K., 2015, Heavy metal pollution in surface water and sediment: a preliminary assessment of an urban river in a developing country. Ecological indicators, NO. 48, PP.282-291.
Ismukhanova, L.; Choduraev, T.; Opp, C.; Madibekov, A. 2022. Accumulation of Heavy Metals in Bottom Sediment and Their Migration in the Water Ecosystem of Kapshagay Reservoir in Kazakhstan. Appl. Sci, 12, 11474.
Helling, D., 1990, Sediments and Environmental Geochemistry. Springer Verlag, New York.
Gupta, S.K.; Chen, K.Y., 1975, Partitioning of Trace Metals in Selective Chemical Fraction of Near shore Sediments. Journal of Environmental Letters, NO,10, PP. 129- 158.
Liu.Y., Guo.H.C., Yu .Y.J., Huang. K., Wang .Z., 2007 ,Sediment chemistry and the variation of three altiplano lakes to recent anthropogenic impacts in south-western China, Water SA, Vol:33, No: 2, p: 305–310.
Larsen.B., Jensen.A., 1989, Evaluation of the sensitivity of sediment stations in pollution monitoring, Mar Pollut Bull ,Vol:20, No:11, PP.556–560.
Lebedev, L.I.; Maev, E.G.; Bordovskii, O.K.; Kulakova, L.S., 1973. The Caspian sediments. Nauka. Moscow (in Russian).
Karbassi, A.R., 1998, Geochemistry of Ni, Zn, Cu, Pb, Co, Cd, V, Mn, Fe, Al and Ca in Sediments of North Western Part of the Persian Gulf. International Journal Gidrometeoizdat, Leningrad, PP. 360 .
Khoshravan, H., & Ghafari, H., 2014, Pollutants Hazard Potential and Environment Vulnerability of Caspian Sea. International Journal of Marine Science, NO.4(4), PP. 57-60.
Khoshravan, H., & Nasehi, F, 2015, Pollutants Hazard Potential and Environmental Vulnerability of Qarah Su River. Journal of Applied Hydrology, NO.2(1), PP. 31-37.
Khoshravan, H., & Ghafari, H., 2014, Pollutants Hazard Potential and Environment Vulnerability of Caspian Sea. International Journal of Marine Science, NO. 4(4), PP.57-60.
Kholodov, V.N.; and Lisitsina N.A., 1989, The Caspian Sea; Sedimentology. Moscow. Nauka. 180 p.
Kos, S., Zupančič, N., Gosar, M. Miler, M., 2022. Solid Carriers of Potentially Toxic Elements and Their Fate in Stream Sediments in the Area Affected by Iron Ore Mining and Processing Minerals, 12 p. 1424, 
Martin JM, Windom HL., 1991Present and future roles of ocean margins in regulating marine biogeochemical cycles of trace elements. In: Mantoura RF, Martin JM, Wollast R, Editors. Ocean Margin Processes in Global Change. New York, NY: John Wiley & Sons, PP. 45-67.
Müller, G., 1969, Index of geoaccumulation in the sediments of the Rhine River, Geojournal, NO. 2, PP.108-118.
Olatunde, K. A., Arowolo, T. A., Bada, B. S., Taiwo, A. M., & Ojekunle, Z. O., 2014, Distribution and enrichment of metals in sediments of the Ogun River within Abeokuta, south-western Nigeria. African Journal of Aquatic Science, NO. 39(1), PP.17-22.
Shajan, K.P., 2001, Geochemistry of Bottom Sediments from a River-Estuary-Shelf Mixing Zone on the Tropical Southwest Coast of India. Bulletin of Geological Survey of Japan, NO. 52 (8), PP. 371-382.
Vengopal B, Luckey TD., 1975, Toxicology of nonradioactive heavy metals and their salts. In: Luckey TD, Venugopal B, Hutcheson D, Editors. Heavy Metal Toxicity, Safety, and Hormology. New York, NY: G. Thieme, PP. 4-73.
Yu K. C.; Tsal L. J.; Chen S. H.; Ho S. T., 2001, Chemical binding of heavy metals in anionic river sediments. Water Research, NO. 35 (17), PP. 4086-4096.
Loska.K., Wiechula.D., Korus.I., 2004, Metal contamination in farming soils affected by industry, Environ Int,Vol: 30, No. 2, PP.159–165.
Mulyaningsih, T. R., & Irmawati, M., 2020, Assessment of heavy metals pollution in the sediment of Ciliwung river. JPhCS, NO.1436(1), 012038.
Yang, P., Yang, M., Mao, R., & Shao, H., 2020, Multivariate-statistical assessment of heavy metals for agricultural soils in northern China. The Scientific World Journal, 2014.
Žibret, G., Čeplak, B., 2021.Distribution of Pb, Zn and Cd in stream and alluvial sediments in the area with past Zn smelting operations,Sci. Rep., 11, p. 17629, 10.1038/s41598-021-96989-y
Zhang, L.; Ye, X.; Feng, H.; Jing, Y.; Ouyang, T.; Yu, X.; Liang, R.; Gao, C.; Chen, W., 2007, Heavy metal contamination in western Xiamen Bay sediments and its vicinity, China. Marine Pollution Bulletin, NO. 54, PP. 974- 982. 
Quaternary Journal of Iran
Volume 10, 1 , 2
September 2025
Pages 239-266

Home

Reviewers

Guide for Authors

Submit Manuscript

Contact Us