Assess groundwater quality with help of Hydrochemical parameters (Case study: in Gheydar area, Zanjan Province)
Subject Areas :
Water and Environment
Tahereh Janisarnavi
1
,
SeyedVahid Shahrokhi
2
1 - M.Sc. Student, Department of Geology, Khoramabad Branch, Islamic Azad University, Khoramabad, Iran.
2 - Associate Professor, Department of Geology, Khoramabad Branch, Islamic Azad University, Khoramabad, Iran. *(Corresponding Author)
Received: 2021-10-04
Accepted : 2022-04-06
Published : 2022-05-22
Keywords:
Hydrogeochemistry,
Gheydar,
metal Index (MI),
Ionic Ratio,
Groundwater,
Abstract :
Background and Objective: the aim of this paper is the assessment of groundwater with respect to the chemistry and its subsequent impact on groundwater quality for drinking and irrigation consumption in the Qheydar area, Zanjan Province.Material and Methodology: In order to determine of physico-chemical parameters, anions, cations and heavy metals were sampled from the water sources of the study area and measured by different methods.Findings: The groundwater facies in the studied area belong to the bicarbonate to chloride type and generally hard due to the total hardness, Except for 2 Samples the others have hardness. In terms of EC and sodium adsorption ratio (SAR), Na% and residual sodium carbonate (RSC), the groundwater is Very salty in more of samples and totally unsuitable for agriculture. Moreover, dissolved heavy elements and Ions kind of As, Se, NO3 and SO4concentrations in the groundwater of the Qheydar area have the unsafe limits which recommended by the WHO.Discussion and Conclusion: Based on ionic ratios, Gibbs diagram, saturation index and multivariate analysis for indicating the sources of inorganic solutes in groundwater indicate carbonate sources and ion exchange have the greatest impact on water chemistry in the area. The metal index (MI) showed that some samples were non-drinking. Also, the results obtained from factor analysis showed the effect of salinity, agriculture, geology and faults in the Qeydar study area.
References:
Koundouri, P., Groom, B., 2010. Groundwater Management: An Overview of Hydrogeology, Economic Values and Principles of Management, Groundwater, Vol. 3, Encyclopedia of Life Support Systems.
Shrestha, S., Viet Bachb, T., Prasad Pandeya, V., 2016. Climate change impacts on groundwater resources in Mekong Delta under representative concentration pathways (RCPs) scenarios, Environmental Science & Policy, Vol.61, PP.1–13.
Chidambaram, S., Karmegam, U., Prasanna, M.V., Sasidhar, P., Vasanthavigar, M., 2011. A study on hydrochemical elucidation of coastal groundwater in and around kalpakkam region, southern india, Environmental Earth Science, Vol.64, N.5, PP.1419-1431.
Zaidi, F., Mogren, S., Mukhopadhyay, M., Ibrahim, E., 2016. Evaluation of groundwater chemistry and its impact on drinking and irrigation water quality in the eastern part of the Central Arabian graben and trough system, Saudi Arabia, Journal of African Earth Sciences, Vol.120, PP.208–219.
2011. Guidelines for Drinking-water Quality, fourth edition, World Health Organization, Switzerland, PP. 469-475.
Yan, W., Li, J., Bai, X., 2016. Comprehensive assessment and visualized monitoring of urban drinking water quality, Chemometrics and Intelligent Laboratory Systems, Vol.155, PP.26–35.
Smita, A., Chary, M., Panigrahi, S., Satpathy, K.K., Prabhu, R.K., Panigrahy, R.C., 2016. Health risk assessment and seasonal distribution of dissolved trace metals in surface waters of Kalpakkam, southwest coast of Bay of Bengal: Regional Studies in Marine Science, Vol.6, PP.96–108.
Krishna, A.K., Satyanarayanan, M., Govil, P.K., 2009. Assessment of heavy metal pollution in water using multivariate statistical techniques in an industrial area, a case
study from Patancheru, Medak District, Andhra Pradesh India, J. Hazard. Mater,
167, PP.366–373.
Gibbs, R.J. 1970. Mechanisms controlling world water chemistry: Science, Vol.170, PP.1088–1090.
Yang, Q., Wang, L., Ma, H., Yu, K., Martín, J.D., 2016. Hydrochemical characterization and pollution sources identification of groundwater in Salawusu aquifer system of Ordos Basin, China, Environmental Pollution, Vol.216, PP.340-349.
Mahrooyan, F., Taghavi, L., Sarai Tabrizi, M., Babazadeh, H., 2021, Water Quality Assessment of Qazvin River Using Nsfwqi Index for Water Quality Classification, Journal of weland ecobiology, 12(1): 99-112 (Persion).
Pourkhbbaz, H.R., Aghdar, H., Mohamadyari, F., 2017, Zoning groundwater quality for agriculture by classification WILCOX index (Case study: Qazvin plain), Geographic space, 17(58): 111-129 (Persion).
Bolourchi, M.H. 1977. Geological Map of Avaj Area, Geological survey and mineral exploration of Iran, No. 5861 sheet. 17 p.
Majidifard, M.R., 2006. Report of Marzban Geological 1/100000 Map, Geological survey and mineral exploration of Iran, No. 5761 sheet. 15p. (Persion).
JaniSarnavi, T., 2022. Environmental Geology and Hydrogeochemistry in Qeydar Area (NE of Qazvin Province), M.Sc. Thesis, Khorramabad Branch, Islamic Azad University, Khorramabad, Iran, 149p.
Freeze, R.A., Cherry, J.A., 1979. Groundwater: Prentice-Hall, 604 p.
Piper, A.M., 1944. A Graphic Procedure in the Geochemical Interpretation of Water-Analyses. Transactions, Arnerican Geophysical Union, Vol.25, PP.914-928.
Halim, M.A., Majumder, R.K., Nessa, S.A., Hiroshiro, Y., Uddin, M.J., Shimada, J., Jinno, K., 2009. Hydrogeochemistry and arsenic contamination of groundwater in the Ganges Delta Plain, Bangladesh, Journal of Hazardous Materials, Vol.164, PP.1335–1345.
Wilcox, L.V., 1955, Classification and Use of Irrigation Water, US Department of Agriculture, Circular 969, Washington DC.
1994. Water Quality for Agriculture: Food and Agriculture Organization of United Nations.
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Koundouri, P., Groom, B., 2010. Groundwater Management: An Overview of Hydrogeology, Economic Values and Principles of Management, Groundwater, Vol. 3, Encyclopedia of Life Support Systems.
Shrestha, S., Viet Bachb, T., Prasad Pandeya, V., 2016. Climate change impacts on groundwater resources in Mekong Delta under representative concentration pathways (RCPs) scenarios, Environmental Science & Policy, Vol.61, PP.1–13.
Chidambaram, S., Karmegam, U., Prasanna, M.V., Sasidhar, P., Vasanthavigar, M., 2011. A study on hydrochemical elucidation of coastal groundwater in and around kalpakkam region, southern india, Environmental Earth Science, Vol.64, N.5, PP.1419-1431.
Zaidi, F., Mogren, S., Mukhopadhyay, M., Ibrahim, E., 2016. Evaluation of groundwater chemistry and its impact on drinking and irrigation water quality in the eastern part of the Central Arabian graben and trough system, Saudi Arabia, Journal of African Earth Sciences, Vol.120, PP.208–219.
2011. Guidelines for Drinking-water Quality, fourth edition, World Health Organization, Switzerland, PP. 469-475.
Yan, W., Li, J., Bai, X., 2016. Comprehensive assessment and visualized monitoring of urban drinking water quality, Chemometrics and Intelligent Laboratory Systems, Vol.155, PP.26–35.
Smita, A., Chary, M., Panigrahi, S., Satpathy, K.K., Prabhu, R.K., Panigrahy, R.C., 2016. Health risk assessment and seasonal distribution of dissolved trace metals in surface waters of Kalpakkam, southwest coast of Bay of Bengal: Regional Studies in Marine Science, Vol.6, PP.96–108.
Krishna, A.K., Satyanarayanan, M., Govil, P.K., 2009. Assessment of heavy metal pollution in water using multivariate statistical techniques in an industrial area, a case
study from Patancheru, Medak District, Andhra Pradesh India, J. Hazard. Mater,
167, PP.366–373.
Gibbs, R.J. 1970. Mechanisms controlling world water chemistry: Science, Vol.170, PP.1088–1090.
Yang, Q., Wang, L., Ma, H., Yu, K., Martín, J.D., 2016. Hydrochemical characterization and pollution sources identification of groundwater in Salawusu aquifer system of Ordos Basin, China, Environmental Pollution, Vol.216, PP.340-349.
Mahrooyan, F., Taghavi, L., Sarai Tabrizi, M., Babazadeh, H., 2021, Water Quality Assessment of Qazvin River Using Nsfwqi Index for Water Quality Classification, Journal of weland ecobiology, 12(1): 99-112 (Persion).
Pourkhbbaz, H.R., Aghdar, H., Mohamadyari, F., 2017, Zoning groundwater quality for agriculture by classification WILCOX index (Case study: Qazvin plain), Geographic space, 17(58): 111-129 (Persion).
Bolourchi, M.H. 1977. Geological Map of Avaj Area, Geological survey and mineral exploration of Iran, No. 5861 sheet. 17 p.
Majidifard, M.R., 2006. Report of Marzban Geological 1/100000 Map, Geological survey and mineral exploration of Iran, No. 5761 sheet. 15p. (Persion).
JaniSarnavi, T., 2022. Environmental Geology and Hydrogeochemistry in Qeydar Area (NE of Qazvin Province), M.Sc. Thesis, Khorramabad Branch, Islamic Azad University, Khorramabad, Iran, 149p.
Freeze, R.A., Cherry, J.A., 1979. Groundwater: Prentice-Hall, 604 p.
Piper, A.M., 1944. A Graphic Procedure in the Geochemical Interpretation of Water-Analyses. Transactions, Arnerican Geophysical Union, Vol.25, PP.914-928.
Halim, M.A., Majumder, R.K., Nessa, S.A., Hiroshiro, Y., Uddin, M.J., Shimada, J., Jinno, K., 2009. Hydrogeochemistry and arsenic contamination of groundwater in the Ganges Delta Plain, Bangladesh, Journal of Hazardous Materials, Vol.164, PP.1335–1345.
Wilcox, L.V., 1955, Classification and Use of Irrigation Water, US Department of Agriculture, Circular 969, Washington DC.
1994. Water Quality for Agriculture: Food and Agriculture Organization of United Nations.
