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Water Resources Management

, Volume 26, Issue 1, pp 129–145 | Cite as

Determining the Main Factors in Declining the Urmia Lake Level by Using System Dynamics Modeling

  • Elmira Hassanzadeh
  • Mahdi ZarghamiEmail author
  • Yousef Hassanzadeh
Article

Abstract

Urmia Lake in Iran is the second largest saline lake in the world. This ecosystem is the home for different species. Due to various socio-economical and ecological criteria, Urmia Lake has important role in the Northwestern part of the country but it has faced many problems in recent years. Because of droughts, overuse of surface water resources and dam constructions, water level has decreased in such a way that one quarter of the lake has changed to saline area in the last 10 years. The purpose of this research is to determine the main factors which reduce the lake’s water level. To this end, a simulation model, based on system dynamics method, is developed for the Urmia Lake basin to estimate the lake’s level. After successful verification of the model, results show that (among the proposed factors) changes in inflows due to the climate change and overuse of surface water resources is the main factor for 65% of the effect, constructing four dams is responsible for 25% of the problem, and less precipitation on lake has 10% effect on decreasing the lake’s level in the recent years. In the future, the model also can be used by managers as a decision support system to find the effects of building new dams or other infrastructures.

Keywords

System dynamics Simulation Integrated lake management Surface water overuse Climate change 

Notes

Acknowledgments

The authors wish to thank the West and East Azarbayjan Regional Water Companies who provided the relative data. We also kindly appreciate the scientific advices of Dr. Abdolrahim Salvitabar.

References

  1. Abazopoulos TJ, Agh N, Van Stappen G, Razavi Rouhani SM, Sorgeloos P (2006) Artemia sites in Iran. J Mar Biol Assoc 86:299–307CrossRefGoogle Scholar
  2. Abbaspour M, Nazaridoust A (2007) Determination of environmental water requirements of Lake Urmia, Iran: an ecological approach. Int J Environ Stud 64(2):161–169CrossRefGoogle Scholar
  3. Ahmad S, Prashar D (2010) Evaluating municipal water conservation policies using a dynamic simulation model. Water Resour Manage 24(13):3371–3395CrossRefGoogle Scholar
  4. Ahmad S, Simonovic SP (2006) An intelligent decision support system for management of floods. Water Resour Manage 20(3):391–410CrossRefGoogle Scholar
  5. Bagheri A (2006) Sustainable development: Implementation in urban water systems. PhD Dissertation, Lund University, SwedenGoogle Scholar
  6. Bagheri A, Darijani M, Asgary A, Morid S (2010) Crisis in urban water systems during the reconstruction period: a system dynamics analysis of alternative policies after the 2003 earthquake in Bam-Iran. Water Resour Manage 24(11):2567–2596CrossRefGoogle Scholar
  7. Bhatti MA (1995) System analysis techniques in water resource management. Proc., WRM’95, Isfahan University of Technology, IranGoogle Scholar
  8. Elshorbagy A, Ormsbee L (2006) Object-oriented modeling approach to surface water quality management. Environ Model Softw 21(5):689–698CrossRefGoogle Scholar
  9. Ewers M (2005) Combining hydrology and economics in a system dynamics approach: modeling water resources for the San Juan Basin. Proc., 23rd International Conference of the System Dynamics Society, July 17–21, BostonGoogle Scholar
  10. Feng LH, Huang CF (2008) A risk assessment model of water shortage based on information diffusion technology and its application in analyzing carrying capacity of water resources. Water Resour Manage 22(5):621–633CrossRefGoogle Scholar
  11. Ford A (1996) Testing the Snake River explorer. Syst Dyn Rev 12(4):305–329CrossRefGoogle Scholar
  12. Forrester JW (1961) Industrial dynamics. MIT Press, CambridgeGoogle Scholar
  13. Forrester JW (1968) Principles of systems productivity, Cambridge, MAGoogle Scholar
  14. Gastélum RJ, Valdés JB, Stewart S (2010) A system dynamics model to evaluate temporary water transfers in the Mexican Conchos Basin. Water Resour Manage 24(11):1285–1311CrossRefGoogle Scholar
  15. Golian S, Abrishamchi A, Tajrishy M (2007) A System dynamics-based analysis of operation policies for water resources at river basin scale. Water Wastewater J 62:70–80 (in Farsi)Google Scholar
  16. Guo HC, Liu L, Huang GH, Fuller GA, Zou R, Yin YY (2001) A system dynamics approach for regional environmental planning and management: a study for the Lake Erhai Basin. J Environ Manag 61(1):93–111CrossRefGoogle Scholar
  17. Ho CC (2005) The application of system dynamics modeling to study impact of water resources planning and management in Taiwan. Proc., 23rd International Conference of the System Dynamics Society, July 17–21, BostonGoogle Scholar
  18. Huerta JM, Serra M, Sandoval R (2001) A system dynamics approach for the design of sustainable water use strategy in the Middle Lerma-Chapala Basin. In: Hansen AM, Afferden MV (eds) The lerma–Chapala watershed, evaluation and management, 2001. Kluwer/Plenum, DordrechtGoogle Scholar
  19. Iran Department of Environment (2009) Urmia Lake Water and Agricultural Working Group, 6th session, Sanandaj, http://www.kdrw.ir/fa/page.asp?page_id=294 (in Farsi)
  20. Jamshidi (2010) http://jamshidi6.blogfa.com/jamshidi (in Farsi)
  21. Liu Y, Guo HC, Yajuan YU, Dai YL, Zhou F (2008) Ecological–economic modeling as a tool for watershed management: a case study of Lake Qionghai watershed, China. Limnol-Ecol Manag Inland Waters 38(2):89–104CrossRefGoogle Scholar
  22. Madani K, Marino M (2009) A System dynamics analysis for managing Iran’s Zayandeh-Rud river basin. Water Resour Manage 23(11):2163–2187CrossRefGoogle Scholar
  23. Ministry of Energy (2007) Water allocation for the development projects in Urmia Lake basin, technical report of Water and Wastewater Planning OfficeGoogle Scholar
  24. Salavitabar A, Zarghami M, Abrishamchi A (2006) System dynamic model in Tehran urban water management. Water Wastewater J 17(3):12–28 (in Farsi)Google Scholar
  25. Shahbazbegian M, Bagheri A (2010) Rethinking assessment of drought impacts: a systemic approach towards sustainability. Water Resour Manage 5(2):223–236Google Scholar
  26. Simonovic SP (2009) Managing water resources, methods and tools for a systems approach. UNESCO and Earthscan, UKGoogle Scholar
  27. Simonovic SP, Ahmad S (2002) System dynamics modeling of reservoir operation for flood management. J Comput Civ Eng 14(3):190–198Google Scholar
  28. Simonovic SP, Li L (2004) Sensitivity of the Red River Basin flood protection system to climate variability and change. Water Resour Manage 18(2):89–110CrossRefGoogle Scholar
  29. Simonovic SP, Fahmy H, Elshorbaghy A (1997) The use of object oriented modeling for water resource planning in Egypt. Water Resour Manage 11(4):243–261CrossRefGoogle Scholar
  30. Stave KA (2003) A system dynamics model to facilitate public understanding of water management options in Las Vegas, Nevada. J Environ Manag 67(4):303–313CrossRefGoogle Scholar
  31. Sterman JD (2000) Business dynamics, systems thinking and modeling for a complex world. McGraw-Hill, BostonGoogle Scholar
  32. Tidewell VC, Passel HD, Conrad SH, Thomas RP (2004) System dynamics modeling for community-based water planning: application to the Middle Rio Grande. Aquat Sci 66(4):357–372CrossRefGoogle Scholar
  33. Vensim (2010) http://www.vensim.com
  34. Water Research Institute (2003) Data Report. Integrated water resources management of Urmia Lake, TehranGoogle Scholar
  35. Water Research Institute (2006) Synthesis Report. Integrated water resources management of Urmia Lake, TehranGoogle Scholar
  36. West Azerbaijan Regional Water Authority (2010) http://www.agrw.ir/
  37. Winz I, Brierley G, Trowsdale S (2009) The use of system dynamics simulation in water resources management. Water Resour Manage 23(11):1301–1323CrossRefGoogle Scholar
  38. Xu ZX, Takeuchi K, Ishidaira H, Zhang XW (2002) Sustainability analysis for Yellow River water resources using the system dynamics approach. Water Resour Manage 16(3):239–261CrossRefGoogle Scholar
  39. Yang CC, Chang LC, Ho CC (2008) Application of system dynamics with impact analysis to solve the problem of water shortages in Taiwan. Water Resour Manage 22(11):1561–1577CrossRefGoogle Scholar

Copyright information

© Springer Science+Business Media B.V. 2011

Authors and Affiliations

  • Elmira Hassanzadeh
    • 1
  • Mahdi Zarghami
    • 1
    Email author
  • Yousef Hassanzadeh
    • 1
  1. 1.Faculty of Civil EngineeringUniversity of TabrizTabrizIran

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