Abstract
Multi-period optimization of conjunctive water management can utilize reservoirs and aquifer carry-over to alleviate drought impacts. Stakeholders’ socio-economic and environmental indices can be used to minimize the socio-economic and environmental costs associated with water shortages in drought periods. The knowledge gap here is the evaluation and inclusion of the socio-economic and environmental value of conjunctive water management in terms of its drought mitigation capability. In this paper, an integrated water quantity-quality optimization model that considers socio-economic and environmental indices is developed. The model considers and integrates reservoir and aquifer carry-over, river-aquifer interaction and water quality with stakeholders’ socio-economic indices of production, net income and labor force employment to evaluate the socio-economic and environmental value of conjunctive water management. Total dissolved solid (TDS) is used as the water quality index for environmental assessments. The model is formulated as a multi-period nonlinear optimization model, with analysis determining the optimal decisions for reservoir release and withdrawal from the river and aquifer in different months to maximize the socio-economic indices of stakeholders within the environmental constraints. The proposed model is used in Zayandehrood water resource system in Iran, which suffers from water supply and pollution problems. Model analysis results show that conjunctive water use in the Zayandehrood water basin reduces salinity by 50 % in the wetland and keeps water supply reduction during a drought under 10 % of irrigation demand.
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References
Agrawala S, Barlow M, Cullen H (2001) The drought and humanitarian crisis in central and southwest Asia: a climate perspective. IRI Special Report 01–11, 24 pp
Alemu ET, Palmer RN, Polebitski A, Meaker B (2011) Decision support system for optimizing reservoir operation using ensemble streamflow predictions. J Water Resour Plan Manag 137(1):72–82
Bazargan-Lari MR, Kerachian R, Mansoori A (2009) A conflict-resolution model for the conjunctive use of surface and groundwater resources that considers water-quality issues: a case study. Environ manag 43(3):470–482
Cai X, McKinney DC, Lasdon LS (2003) Integrated hydrologic- agronomic- economic model for riverbasin management. J Water Resour Plan Manag 129(1):235–245
Chang LC, Chang FJ, Wang KW, Dai SY (2010) Constrained genetic algorithms for optimizing multi-use reservoir operation. J Hydrol 390:66–74
Chen L, Chiang PK (2005) An application of grammatical evolution for reservoir inflow prediction on operation. Int J Oper Res 2(1):15–20
Food and Agriculture Organization (FAO) of the United Nations (2007) High level conferences on world food security and the challenges of climate change and bioenergy. Thirty-Fourth Session, Food and Agriculture Organization of the United Nations, November, 2007, Rome, Italy
Gaivoronski AA, Sechi GM, Zuddas P (2012) Balancing cost-risk in management optimization of water resource systems under uncertainty. Phys Chem Earth 42:98–107
Georgakakos KP, Graham NE, Cheng FY, Spencer C, Shamir E, Georgakakos AP, Kistenmacher M (2012) Value of adaptive water resources management in northern California under climatic variability and change: dynamic hydroclimatology. J Hydrol 412:47–65
Hejazi MI, Cai X (2011) Building more realistic reservoir optimization models using data mining—a case study of Shelbyville Reservoir. Adv Water Resour 34:701–717
Heydari GR (2005) The incidence of droughts and their specific features in terms of shortand longer term socio-economic impacts at household and community level covering different agro-ecological systems in the country. Consultant Report to the Food and Agriculture Organization of the United Nations Near East Regional Office, Cairo, Egypt
Jamab Consulting Engineers (2005) Master plan studies of adaptation to climate change (Balancing the water resources and consumption), Iran Management and planning organization, water, agriculture and natural resources office, Volume 1 and 2. Tehran, Iran
Karimi A, Ardakanian R (2010) Development of a long-term water allocation model for agriculture and industry demands. Water Resour Manag 24:1717–1746
Karimi A, Nikoo MR, Kerachian R (2013) An interval parameter optimization model for long term basin-wide surface and groundwater allocation considering the water quality issues, 6th International Perspective on Water Resources and Environment, IPWE2013, Izmir, Turkey
Kerachian R, Fallahnia M, Bazargan-Lari MR, Mansoori A, Sedghi H (2010) A fuzzy game theoretic approach for groundwater resources management: application of rubinstein bargaining theory. Resour Conserv Recycl 54(10):673–682
Krol M, Jaeger A, Bronstert A, Guntner A (2006) Integrated modeling of climate, water, soil, agricultural and socioeconomic processes: a general introduction of the methodology and some exemplary results from the semi-arid north-east of Brazil. J Hydrol 328:417–431
Logar I, Bergh JJM (2013) Methods to assess costs of drought damages and policies for drought mitigation and adaptation: review and recommendations. Water Resour Manag 27(6):1707–1720
Mahjouri N, Ardestani M (2011) Application of cooperative and non-cooperative games in large-scale water quantity and quality management: a case study. Environ Monit Assess 172(1–4):157–169
Mishra AK, Singh VP (2010) A review of drought concepts. J Hydrol 391:202–216
Moeini R, Afshar A, Afshar MH (2011) Fuzzy rule-based model for hydropower reservoirs operation. Electr Power Energy Syst 33:171–178
Nikoo MR, Karimi A, Kerachian R, Poorsepahy-Samian H, Daneshmand F (2013a) Rules for optimal operation of reservoir-river-groundwater systems considering water quality targets: application of M5P model. Water Resour Manag 27(8):2771–2784
Nikoo MR, Karimi A, Kerachian R (2013b) Optimal long-term operation of reservoir-river systems under hydrologic uncertainties: application of interval programming. Water Resour Manag Springer 27:3865–3883
Nikoo MR, Kerachian R, Karimi A, Azadnia AA, Jafarzadegan K (2013c) Optimal water and waste load allocation in reservoir–river systems: a case study. Environ Earth Sci. doi:10.1007/s12665-013-2801-5
Preziosi E, Bon A, Romano E, Petrangeli AB, Casadei S (2013) Vulnerability to drought of a complex water supply system. The upper tiber basin case study (Central Italy). Water Resour Manag 27(13):4655–4678
Rozegrant MW, Ringler C, McKinney DC, Cai X, Keller A, Donoso G (2000) Integrated economic-hydrologic water modeling at basin scale: the Maipo riverbasin. Agric Econ 24:33–46
Schoups G, Addams CL, Minjares JL, Gorelick SM (2006) Sustainable conjunctive water management in irrigated agriculture: model formulation and application to the Yaqui valley, Mexico. Water Resour Res 42(10):1–19
Sechi GM, Sulis A (2010) Drought mitigation using operative indicators in complex water systems. Phys Chem Earth 35:195–203
Soltani MA, Karimi A, Bazargan-Lari MR, Shirangi E (2008) Stochastic multi-purpose reservoir operation planning by scenario optimization and differential evolutionary algorithm. J Appl Sci 8(22):4186–4191
Tsakiris G, Nalbantis I, Vangelis H, Verbeiren B, Huysmans M, Tychon B, Batelaan O (2013) A system-based paradigm of drought analysis for operational management. Water Resour Manag 27(15):5281–5297
Water Resources Atlas, Gavkhuni Riverbasin (2011) Ministry of energy, Iran water resources company and isfahan water authority, volumes 1–21. Tehran, Iran
Wilhite D, Svoboda M, Hayes M (2007) Understanding the complex impacts of drought: A key to enhancing drought mitigation and preparedness. Water Resour Manag 21(5):763–774
Zhang W, Wang Y, Peng H, Li Y, Tang J, Wu KB (2010) A coupled water quantity–quality model for water allocation analysis. Water Resour Manag 24:485–511
Zhao T, Cai X, Yang D (2011) Effect of streamflow forecast uncertainty on real-time reservoir operation, Elsevier. Adv Water Resour 34:495–504
Acknowledgments
The authors would like to acknowledge the support of the Islamic Azad University, East Tehran Branch for this research. Technical and scientific contributions of Dr. Kaveh Madani (Department of Civil, Environmental, and Construction Engineering, University of Central Florida, USA) are greatly appreciated.
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Daneshmand, F., Karimi, A., Nikoo, M.R. et al. Mitigating Socio-Economic-Environmental Impacts During Drought Periods by Optimizing the Conjunctive Management of Water Resources. Water Resour Manage 28, 1517–1529 (2014). https://doi.org/10.1007/s11269-014-0549-7
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DOI: https://doi.org/10.1007/s11269-014-0549-7