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Risk evaluation and distribution of arsenic concentration in groundwater resources of villages in Jiroft County, Kerman Province, Iran | ||
Caspian Journal of Environmental Sciences | ||
دوره 19، شماره 3، مهر 2021، صفحه 559-573 اصل مقاله (1.35 M) | ||
نوع مقاله: Research Paper | ||
شناسه دیجیتال (DOI): 10.22124/cjes.2021.4944 | ||
نویسندگان | ||
Bahador Abolpour* 1؛ Mohammad Najaf Tarqi2؛ Yousef Askari Dolatabad3؛ Fatemeh Salahi Sarbijan4 | ||
1Department of Chemical Engineering, Sirjan University of Technology, Sirjan, Iran | ||
2Department of Civil Engineering, Sirjan University of Technology, Sirjan, Iran | ||
3. Department of Civil Engineering, Sirjan University of Technology, Sirjan, Iran | ||
4Department of Rural Water and Wastewater, Jiroft, Iran | ||
چکیده | ||
In this study, the arsenic polution of drinking water wells of rural areas was investigated for obtaining the extent of this pollution and also finding the possible sources for this pollution. So, the distribution of arsenic in 19 wells with different depth from 5 to 100 m and water flows were examined in a 6-month period from September 2016 to February 2017. These samples were compared with the international standards. Effects of well depth, water flow, rainfall, soil and land usage on the arsenic concentration were evaluated. The results show that places with the inceptisols have higher water pollution. The highest and lowest arsenic concentrations are reported in Daryache and Hokerd villages with 153 and 0.5 μg L-1, respectively. In addition, matching the geographical map of water pollution with the land use map by hot spots analysis indicated that more polluted water wells have been located around the agricultural land. The results also indicated that the accuracy of the RBF method for obtaining the zoning arsenic concentration is higher than the other methods. The results of Pearson’s correlation test indicated that there is no significant relationship among the depths, flows and rainfalls of wells and the arsenic concentration. | ||
کلیدواژهها | ||
Groundwater؛ Arsenic؛ Jiroft county؛ Zoning؛ Pollution | ||
مراجع | ||
Abbasnejad, A, Mirzaie, A, Derakhshani, R & Esmaeilzadeh, E 2013, Arsenic in groundwaters of the alluvial aquifer of Bardsir plain, SE Iran, Environmental Earth Sciences, 69: 2549-2557.
Ali, H, Khan, E & Ilahi, I 2019, Environmental chemistry and ecotoxicology of hazardous heavy metals: Environmental persistence, toxicity, and bioaccumulation, Journal of Chemistry, DOI: 10.1155/2019/6730305.
Andrade, A & Stigter, TY 2013, The distribution of arsenic in shallow alluvial groundwater under agricultural land in central Portugal: Insights from multivariate geostatistical modeling, Science of the Total Environment, 449: 37-51.
Asadifard, E & Masoudi, M 2018, Status and prediction of carbon monoxide as an air pollutant in Ahvaz City, Iran, Caspian Journal of Environmental Sciences, 16: 203-213.
Boonkhao, L, Phanprasit, W, Robson, MG, Sujirarat, D, Kwonpongsagoon, S & Tangtong, C 2017, Arsenic exposure levels of petrochemical workers in three workplace settings in Rayong Province, Thailand. Human and Ecological Risk Assessment: An International Journal, 23(7): 1645-1654.
Chai, L, Wang, Z, Wang, Y, Yang, Z, Wang, H & Wu, X 2010, Ingestion risks of metals in groundwater based on TIN model and dose–response assessment - A case study in the Xiangjiang watershed, central-south China. Science of the Total Environment, 408: 3118-3124.
Cinti, D, Poncia, PP, Brusca, L, Tassi, F, Quattrocchi, F & Vaselli, O 2015, Spatial distribution of arsenic, uranium and vanadium in the volcanic-sedimentary aquifers of the Vicano–Cimino Volcanic District (Central Italy), Journal of Geochemical Exploration, 152: 123-133.
Dowling, CB, Poreda, RJ, Basu, AR, Peters, SL & Aggarwal, PK 2002, Geochemical study of arsenic release mechanisms in the Bengal Basin groundwater, Water Resource Research, 38: 1173.
Evenbly, G & Vidal, G 2016, Local scale transformations on the lattice with tensor network renormalization, Physical Review Letters, 116: 040401.
Fallah, M, Pirali Zefrehi, AR, Hedayati, SA & Bagheri T 2021, Comparison of temporal and spatial patterns of water quality parameters in Anzali Wetland (southwest of the Caspian sea) using Support vector machine model, Caspian Journal of Environmental Sciences, 19: 95-104.
Focazio, MJ, Welch, AH, Watkins, SA, Helsel, DR & Horn, MA 2000, A retrospective analysis on the occurrence of arsenic in ground-water resources of the United States and limitations in drinking-water-supply characterizations (No. 99-4279), U.S. Geological Survey Water Resurces Investigation Reports.
Francisca, FM & Perez, MEC 2009, Assessment of natural arsenic in groundwater in Cordoba Province, Argentina, Environmental Geochemistry and Health, 31(6): 673.
Garbarino, JR, Bednar, AJ, Rutherford, DW, Beyer, RS & Wershaw, RL 2003, Environmental fate of roxarsone in poultry litter. I. Degradation of roxarsone during composting. Environmental Science & Technology, 37: 1509-1514.
Kapp Jr, RW 2016, Arsenic: Properties and determination, Encyclopedia of Food and Health, BioTox, Monroe Township, NJ, USA: 249-255.
Keil, AP & Richardson, DB 2017, Reassessing the link between airborne arsenic exposure among anaconda copper smelter workers and multiple causes of death using the parametric g-formula, Environmental Health Perspectives, 125: 608.
Lee, J, Jang C, Wang, S & Liu, C 2007, Evaluation of potential health risk of arsenic-affected groundwater using indicator kriging and dose response model. Science of the Total Environment, 384: 151-162.
Mahram, M, Shahsavari, D, Oveisi, S & Jalilolghadr, S 2013, Comparison of hypertension and diabetes mellitus prevalence in areas with and without water arsenic contamination, Journal of research in medical sciences: The Official Journal of Isfahan University of Medical Sciences, 18: 408.
Meharg, AA & Rahman, MM 2003, Arsenic contamination of Bangladesh paddy field soils: implications for rice contribution to arsenic consumption, Environmental Science & Technology, 37: 229-234.
Mc Arthur, JM, Ghosal, U, Sikdar, PK & Ball, JD 2016, Arsenic in groundwater: the deep late pleistocene aquifers of the Western Bengal Basin. Environment Scince and Technology, 50: 3469-3476.
Moran, JE, Hudson, GB, Eaton, GF & Leif, R 2004, California GAMA Program: A contamination vulnerability assessment for the Bakersfield area (No. UCRL-TR-208179), Lawrence Livermore National Lab., Livermore, California, USA.
Navabian, M, Vazifehdost, M & Esmaeili Varaki, M 2020, Estimation of pollution load to Anzali Wetland using remote sensing technique, Caspian Journal of Environmental Sciences, 18: 251-264.
Nikravesh, M, Karimi, A, Esfandialpour Borujeni, I & Fotovat, A 2019, Multivariate and geostatical analyses of selected heavy metals in surface soils of Semnan industrial complex and surrounding areas. Caspian Journal of Enviromental Sciences, 17: 163-174.
Rafiee, M, Eslami, A, Saeedi, R, Abtahi, M & Jahangirirad, M 2019, Multivariate and geostatical analyses of spatial distribution and potential sources of heavy metals in surface waters. Caspian Journal of Enviromental Sciences, 17: 23-41.
Rahnama, H., Ghanbarpour, M. R, Habibnezhad, RM & Dadrasi, SA 2012. Study of the qualitative and quantitative condition of the groundwater resources (Case Study: Jovain Plain, Khorasan Razavi Province). Geography and Territorial Spatial Arrangement, 2: 31-45.
Rasool, A, Farooqi, A, Masood, S & Hussain, K 2016, Arsenic in groundwater and its health risk assessment in drinking water of Mailsi, Punjab, Pakistan, Human and Ecological Risk Assessment: An International Journal, 22: 187-202.
Phan, K, Sthiannopkao, S, Kim, KW, Hung Wong, M, Sao, V, Hashim, JH, Mohamed Yasin, MS & Aljunid, SM 2010, Health risk assessment of inorganic arsenic intake of Cambodia residents through groundwater drinking pathway. Water Researchs, 44: 5777-5788.
Pourret, O 2018, On the necessity of banning the term "Heavy Metal" from the scientific literature, Sustainability, 10: 2879.
Ravenscroft, P, Brammer, H & Richards, K 2009, Arsenic pollution-a global synthesis. Hoboken: Wiley.
Smedley, PL & Kinniburgh, DG 2002, A review of the source, behaviour and distribution of arsenic in natural waters, Applied Geochemistry, 17: 517-568.
Smith, AH, Goycolea, M, Haque, R & Biggs, ML 1998, Marked increase in bladder and lung cancer mortality in a region of Northern Chile due to arsenic in drinking water, American Journal of Epidemiology, 147: 660-669.
Smith, AH, Lingas, EO & Rahman, M 2000, Contamination of drinking-water by arsenic in Bangladesh: a public health emergency. Bulletin of the World Health Organization, 78: 1093-1103.
Tsionas, E & Tasiopoulos, A 2016, Bayesian implications of Ridge Regression and Zellner'sg Prior, Social Science Research Network Electronic Journal, DOI:10.2139/ssrn.2387582.
Tual, S, Lemarchand, C, Guizard, AV, Velten, M, Marcotullio, E, Baldi, I & Boulanger, M 2017, Lung Cancer And Arsenic Exposure In The Agricultural Workplace: Results of the Agrican cohort, American Journal of Respiratory and Critical Care Medicine, 195: A3858. | ||
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