Journal of Aquifer and Qanat

In collaboration Iranian Hydraulic Association

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Quantity and Quality Modeling of Groundwater Flow in Shahrekord Aquifer

Authors

1 Postdoctoral Researcher, School of Civil Engineering, University of Tehran, Tehran, Iran

2 Professor, School of Civil Engineering, University of Tehran, Tehran, Iran

Abstract

Groundwater resources, as one of the most important factors in sustainable development, need to be intensely considered. Numerical models such as Modflow and MT3D is an applied tool for simulation and management of groundwater flow and solute transport. In this study, Shahrekord aquifer modeling is provided by the use of monthly data’s including hydraulic heads, depletion volume of the wells, springs and qanats, precipitation values. This model has been developed based on the assessment of the hydraulic conductivity and specific yield coefficients in the calibration process. The study year was divided to 12 monthly stress period for calibration (10 periods) and verification (2 periods). The results showed that the hydraulic conductivity from 6 to 16 m/day and specific yield from 0.03 to 0.07 were varied. The predicted water table in calibration process in comparison to observed values of water levels on piezometers with variance of 0.63. These results confirm the need model of groundwater flow prediction. Moreover, Effective molecular diffusion coefficient, longitudinal dispersity and distribution coefficient were calibrated to achieve acceptable variance between observed and calculated nitrate concentration. The most contaminant particles are in the south zone of aquifer where is the nearby urban wastewater wells. Moreover, the central and south parts of plain have the suitable situations for groundwater discharge because of the high amount of transmissivity. 

Keywords

References
Bazargan-Lari, M.R., Kerachian, R., Mansoori, A., 2008. A conflict-resolution model for the conjunctive use of surface and groundwater resources that considers water-quality (case study). Env. Manage. 43(3), 470-482.
Don, N.C., Araki, H., Yamanishi, H., Koga, K., 2005. Simulation of groundwater flow and environmental effects resulting from pumping. Env. Geo. 47, 361-374.
Gieske, A., Miranzadeh, M., 2002. Groundwater Resources Modeling of the Lenjenat Aquifer System. IAERI-IWMI Research Reports. 15.
Isfahan regional water company. 2000. Groundwater of Shahrekord aquifer studies. Isfahan Regional Water Company Report, 285 pp. [In Persian]
Katibeh, H., Hafezi, S., 2004. Application of Modflow in groundwater management and evaluation of artificial recharge project of Ab-barik aquifer (Bam). J. water waste. 50(1), 45-58. [in Persian with English Summary].
Kresic, N., 1997. Quantitative solution in hydrogeology and groundwater modeling. CRC Press LLC, 115 pp.
Lalehzari, R. 2008. The effect of wastewater recharge on nitrate distribution in Shahrekord aquifer using MT3D model. M.Sc. Thesis. Shahrekord University, 130 pp. [in Persian with English Summary].
Lalehzari, R., Boroomand Nasab, S., Moazed, H., Haghighi, A., 2015. Evaluating the impact of drought stresses on groundwater system in Baghmalek plain by discharge pattern changes. J. Water and Soil. 29(3), 539-550. [in Persian with English Summary].
Lalehzari, R., Tabatabaei, S.H. Kholghi, M., 2013. Nitrate transport simulation in groundwater using MT3D model in wastewater seepage condition. Int. J. Env. Sci. Tech. 10, 1367-1376.
Lalehzari, R., Tabatabaei, S.H., 2015. Simulating the impact of subsurface dam construction on the change of nitrate distribution. Env. Earth Sci. 74, 3241-3249.
Lalehzari, R., Tabatabaei, S.H., Kholghi, M. Yarali, N., Saba, A.A., 2014. Evaluation of Scenarios in artificial recharge with treated wastewater on the quantity and quality of Shahrekord aquifer. J. Env. Stu. 40(1), 52-55.
Lalehzari, R., Tabatabaei, S.H., Kholghi, M., 2010. Hydrodynamic coefficients estimation and flow treatment prediction in Shahrekord aquifer using PMWIN model. 14th Inter. Water Technology Conference. Cairo, Egypt.
Lautz,L. K., Siegel, D.I., 2006. Modeling surface and groundwater mixing in the hyporheic zoneusing MT3D and MT3D. Adv. Water Res. 29 (11), 1618–1633.
Mirabbasi, R., Rahnama, M.B., 2008. The impact of construction of Tangooye dam on the groundwater resources by model simulation of Sirjan plain aquifer using Modflow software. Iran Water Res. J. 1(1), 1-9. [in Persian with English Summary].
Neville, C.J., Tonkin, M.J., 2004. Modeling multi-aquifer wells with Modflow. Ground. 42(6), 910-919.
Peeters, L., Haerens, B., Van der Sluys, J., Dassargues, A., 2004. Modelling seasonal variations in nitrate and sulphate concentrations in a vulnerable alluvial aquifer. Env. Geo. 46, 951–961.
Reynolds, D.A., Marimuthu, S., 2006. Deuterium composition and flow path analysis as additional calibration targets to calibrate groundwater flow simulation in a coastal wetlands system. Hyd. J. 15, 515-535.
Thorley, M., Callander, P., 2005. Christhurch city groundwater model. Environment Canterbury report, 10 pp.
Todd, W.R., Kenneth, R.B., 2001. Report: Delineation of capture zones for municipal wells in fractured dolomite. Sturgeon Bay, Wisconsin, USA. Hyd. J. 9, 432-450.
Journal of Aquifer and Qanat
Volume 1, Issue 1
November 2017
Pages 26-37
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