Abstract
The aim of this study was to investigate how to adjust groundwater withdrawal in the Zayandeh-Rud River Basin in the arid region of central Iran due to changes in groundwater balance components. Two time periods (2006–2012 and 2013–2019) were considered to evaluate changes in groundwater level and different components affecting these changes. Groundwater level unit hydrographs in 6 important aquifers (in terms of groundwater abstraction) located in this study area were prepared using the Thiessen method. Also, the changes in precipitation and evapotranspiration in the study area were determined in both time periods. Groundwater balance equation was revised based on changes in precipitation, evapotranspiration, and surface flow variations between these two time periods. Results showed that the groundwater level has a negative trend since 2013. By 2012, the annual groundwater level increased about the 0.42 m, but from 2013 to 2019, the annual groundwater level declined about the 1.2 m, approximately. The surface flow had the more adjustment coefficient and contribution with groundwater recharge. Due to the decrease in precipitation and surface flow, increase in evapotranspiration, and adjustment of groundwater overdraft, in total, the groundwater withdrawal should be reduced from 2228.9 to 1929.1 MCM (13.1% decrease) in the study area.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Allen RG, Pereira LS, Raes D, Smith M (1998) Crop evapotranspiration. Irrigation and drainage paper no.56. FAO, Rome
Aravena R, Robertson W (1998) The use of multiple isotope tracers to evaluate denitrification in groundwater: a case study in a large septic system plume. Ground Water 36(6):975–982
Arntzen EV, Geist DR, Dresel PE (2006) Effects of fluctuating river flow on groundwater/surface water mixing in the hyporheic zone of a regulated, large cobble bed river. River Res Appl 22(8):937–946
Baalousha H (2009) Stochastic water balance model for rainfall recharge quantification in Ruataniwha Basin, New Zealand. Environ Geol 58(1):85–93
Bakker M, Bartholomeus RP, Ferre TPA (2013) Groundwater recharge: processes and quantification preface. Hydrol Earth Syst Sci 17(7):2653–2655
Barthel R, Reichenau TG, Krimly T, Dabbert S, Schneider K, Mauser W (2012) Integrated modeling of global change impacts on agriculture and groundwater resources. Water Resour Manag 26(7):1929–1951
Batelaan O, De Smedt F (2007) GIS-based recharge estimation by coupling surface-subsurface water balances. J Hydrol 337(3):337–355
Bayat M, Eslamian S, Shams G, Hajiannia A (2020) Groundwater level prediction through GMS software– case study of Karvan area, Iran. Quaest Geog 39(3):139–145
Borowski I, Hare M (2007) Exploring the gap between water managers and researchers: difficulties of model-based tools to support practical water management. Water Resour Manag 21(7):1049–1074
Castaño S, Sanz D, Gómez-Alday JJ (2013) Sensitivity of a groundwater flow model to both climatic variations and management scenarios in a semi-arid region of SE Spain. Water Resour Manag 27(7):2089–2101
Chen WP, Lee CH (2003) Estimating ground-water recharge from streamflow records. Environ Geol 44(3):257–265
Edmunds WM, Darling WG, Kinniburgh DG (1988) Solute profile techniques for recharge estimation in semi-arid areas and arid terrain. In: Simmers I (ed) Estimation of natural groundwater recharge. Kluwer, Dordrecht, The Netherlands, pp 13–157
Elci A, Gunduz O, Simsek CCS (2007) Spatial and temporal assessment of groundwater quality indicators and hydrogeological characterization of a karstic aquifer in Western Turkey. Avaliable from: http://kisi.deu.edu.ir
Falkenmark M, Lundqvist J, Widstrand C (1989) Macro-scale water scarcity requires micro-scale approaches. Aspects of vulnerability in semi-arid development. Nat Res Forum 13(4):258–267
Finch JW (1998) Estimating direct groundwater recharge using a simple water balance model-sensitivity to land surface parameters. J Hydrol 211(1):112–125
Gohari A, Eslamian S, Abedi-Koupaei J, Bavani AM, Wang D, Madani K (2013a) Climate change impacts on crop production in Iran’s Zayandeh-Rud River Basin. Sci Total Environ 442:405–419
Gohari A, Eslamian S, Mirchi A, Abedi-Koupaei J, Massah Bavani A, Madani K (2013b) Water transfer as a solution to water shortage: a fix that can backfire. J Hydrol 491:23–39
Gohari A, Bozorgi A, Madani K, Elledge J, Berndtsson R (2014a) Adaptation of surface water supply to climate change in Central Iran. J Water Clim Chang Doi 5:391–407. https://doi.org/10.2166/wcc.2013.189
Gohari A, Madani K, Mirchi A, Bavani AM (2014b) System-dynamics approach to evaluate climate change adaptation strategies for Iran’s Zayandeh-Rud Water System. World Environmental and Water Resources Congress. Portland, USA
Gohari A, Zareian MJ, Eslamian S (2014c) A multi-model framework for climate change impact assessment. Handbook of Climate Change Adaptation. Springer Press, Dordrecht, Germany
Gunawardhana LN, Kazama S, Kawagoe S (2011) Impact of urbanization and climate change on aquifer thermal regimes. Water Resour Manag 25(13):3247–3276
Hargreaves GH, Samani ZA (1982) Estimating potential evapotranspiration. J Irrig Drain Div 108(3):225–230
Hartmann A, Gleeson T, Wada Y, Wagener T (2017) Enhanced groundwater recharge rates and altered recharge sensitivity to climate variability through subsurface heterogeneity. Proc Natl Acad Sci 114(11):2842–2847
Ivey JL, Smithers J, De Loe RC, Kreutzwiser RD (2004) Community capacity for adaptation to climate-induced water shortages: linking institutional complexity and local actors. Environ Manag 33(1):36–47
Jolly I, McWan K, Holland K (2008) A review of groundwater-surface water interactions in arid/semi-arid wetlands and the consequence for wetland ecology. Ecohydrology 1(1):43–58
Jyrkama MI, Sykes JF, Normani SD (2002) Recharge estimation for transient groundwater modeling. Ground Water 40(6):638–648
Kahsay KD, **ale SM, Hatiye SD (2018) Impact of climate change on groundwater recharge and base flow in the sub-catchment of Tekeze basin, Ethiopia. Groundw Sustain Dev 6:121–133
Keesstra SD, Geissen V, Mosse K, Piiranen S, Scudiero E, Leistra M, van Schaik L (2012) Soil as a filter for groundwater quality. Curr Opin Environ Sustain 4(5):507–516
Keesstra S, Nunes JP, Saco P, Parsons T, Poeppl R, Masselink R, Cerdà A (2018) The way forward: can connectivity be useful to design better measuring and modelling schemes for water and sediment dynamics? Sci Total Environ 644:1557–1572
Khan S, Gabriel HF, Rana T (2008) Standard precipitation index to track drought and assess impact of rainfall on water tables in irrigation areas. Irrig Drain Syst 22(2):159–177
Li XY, Xu HY, Sun YL, Zhang DS, Yang ZP (2007) Lake-level change and water balance analysis at Lake Qinghai, west China during recent decades. Water Resour Manag 21(9):1505–1516
Li Z, Li C, Wang X, Peng C, Cai Y, Huang W (2018) A hybrid system dynamics and optimization approach for supporting sustainable water resources planning in Zhengzhou City, China. J Hydrol 556:50–60
Liang X, Zhang YK (2012) A new analytical method for groundwater recharge and discharge estimation. J Hydrol 450:17–24
Loaiciga HA (2003) Climate change and groundwater. Ann Assoc Am Geogr 93:30–41
López-Vicente M, Kramer H, Keesstra S (2021) Effectiveness of soil erosion barriers to reduce sediment connectivity at small basin scale in a fire-affected forest. J Environ Manag 278:111510
Malakar P, Mukherjee A, Bhanja SN, Ganguly AR, Ray RK, Zahid A, Sarkar S, Saha D, Chattopadhyay S (2021) Three decades of depth-dependent groundwater response to climate variability and human regime in the transboundary Indus-Ganges-Brahmaputra-Meghna mega river basin aquifers. Adv Water Resour 149:103856
McDonald MG, Harbaugh AW (2003) The history of MODFLOW. Ground Water 41(2):280–283
Middelkoop H, Daamen K, Gellens D, Grabs W, Kwadijk JCJ, Lang H, Parmet BWAH, Schädler B, Schulla J, Wilke K (2001) Impact of climate change on hydrological regimes and water resources management in the Rhine basin. Clim Chang 49(1-2):105–128
Nainggolan L, Ni CF, Darmawan Y, Lee I, Lin CP, Li WC (2020) Data-driven approach to assess spatial-temporal interactions of groundwater and precipitation in Choushui River groundwater basin, Taiwan. Water 12(11):3097
Narany TS, Aris AZ, Sefie A, Keesstra S (2017) Detecting and predicting the impact of land use changes on groundwater quality, a case study in Northern Kelantan, Malaysia. Sci Total Environ 599:844–853
Panda DK, Mishra A, Jena SK, James BK, Kumar A (2007) The influence of drought and anthropogenic effects on groundwater levels in Orissa, India. J Hydrol 343:140–153
Peters E, Torfs PJJF, Van Lanen HAJ, Bier G (2003) Propagation of drought through groundwater- a new approach using linear reservoir theory. Hydrol Process 17(15):3023–3040
Peters E, Bier G, Van Lanen HAJ, Torfs PJJF (2006) Propagation and spatial distribution of drought in a groundwater catchment. J Hydrol 321:257–275
Purkey DR, Huber-Lee A, Yates DN, Hanemann M, Herrod-Julius S (2007) Integrating a climate change assessment tool into stakeholder-driven water management decision-making process in California. Water Resour Manag 21(1):315–329
Qian W, Zhu Y (2001) Climate change in China from 1880 to 1998 and its impact on the environment condition. Clim Chang 50(4):419–444
Ringleb J, Sallwey J, Stefan C (2015) Comparison of different estimation techniques to quantify groundwater recharge in Pirna, Germany. Geophys Res Abstr 17 EGU2015-3594-1
Robinson M, Ward R (2000) Principles of hydrology. McGraw-Hill Publishing Company, Berkshire England
Rodrigo Comino J, Keesstra SD, Cerdà A (2018) Connectivity assessment in Mediterranean vineyards using improved stock unearthing method, LiDAR and soil erosion field surveys. Earth Surf Process Landf 43(10):2193–2206
Safavi HR, Darzi F, Mariño MA (2010) Simulation-optimization modeling of conjunctive use of surface water and groundwater. Water Resour Manag 24(10):1965–1988
Sakakibara K, Tsujimura M, Song X, Zhang J (2017) Spatiotemporal variation of the surface water effect on the groundwater recharge in a low-precipitation region: Application of the multi-tracer approach to the Taihang Mountains, North China. J Hydrol 545:132–144
Sidiropoulos P, Mylopoulos N, Loukas A (2013) Optimal management of an overexploited aquifer under climate change: the lake Karla case. Water Resour Manag 27(6):1635–1649
Simmons CS, Meyer PD (2000) A simplified model for the transient water budget of a shallow unsaturated zone. Water Resour Res 36(10):2835–2844
Tanaka SK, Tingju Z, Lund JR, Howitt RE, Jenkins MW, Pulido MA, Tauber M, Ritzema RS, Ferreira IC (2006) Climate warming and water management adaptation for California. Clim Chang 76(3-4):361–387
Von Freyberg J, Moeck C, Schirmer M (2015) Estimation of groundwater recharge and drought severity with varying model complexity. J Hydrol 527:844–857
Wilopo W, Putra DPE, Hendrayana H (2021) Impacts of precipitation, land use change and urban wastewater on groundwater level fluctuation in the Yogyakarta-Sleman Groundwater Basin, Indonesia. Environ Monit Assess 193(2):1–14
Zagonari F (2010) Sustainable, just, equal, and optimal groundwater management strategies to cope with climate change: insights from Brazil. Water Resour Manag 24(13):3731–3756
Zareian MJ (2021) Optimal water allocation at different levels of climate change to minimize water shortage in arid regions (Case Study: Zayandeh-Rud River Basin, Iran). J Hydro-environ Res 35:13–30
Zareian MJ, Eslamian S, Hosseinipour EZ (2014a) Climate change impacts on reservoir inflow using various weighting approaches. World Environmental and Water Resources Congress. Portland, USA
Zareian MJ, Eslamian S, Safavi HR (2014b) A modified regionalization weighting approach for climate change impact assessment at watershed scale. Theor Appl Climatol 122(3):497–516
Zayandab Consulting Engineering Co., 2015. Groundwater balance studies in Gavkhouni River Basin, Iran. (In Persian)
Zhang L, Dawes WR, Walker GR (2001) Response of mean annual evapotranspiration to vegetation changes at catchment scale. Water Resour Res 37(3):701–708
Zhu YH, Wu YQ, Drake S (2004) A survey: obstacles and strategies for the development of ground-water resources in arid inland river basins of Western China. J Arid Environ 59(2):351–367
Author information
Authors and Affiliations
Corresponding author
Ethics declarations
Conflict of interest
The authors declare that they have no competing interests.
Additional information
Responsible Editor: Broder J. Merkel
Rights and permissions
About this article
Cite this article
Zareian, M.J., Eslamian, S. Groundwater withdrawal adjustment based on changes in groundwater balance components (a case study: an arid region in central Iran). Arab J Geosci 14, 1822 (2021). https://doi.org/10.1007/s12517-021-07983-7
Received:
Accepted:
Published:
DOI: https://doi.org/10.1007/s12517-021-07983-7