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Climatic Change

, Volume 152, Issue 3–4, pp 379–391 | Cite as

Compounding effects of human activities and climatic changes on surface water availability in Iran

  • Samaneh Ashraf
  • Amir AghaKouchakEmail author
  • Ali Nazemi
  • Ali Mirchi
  • Mojtaba Sadegh
  • Hamed R. Moftakhari
  • Elmira Hassanzadeh
  • Chi-Yuan Miao
  • Kaveh Madani
  • Mohammad Mousavi Baygi
  • Hassan Anjileli
  • Davood Reza Arab
  • Hamid Norouzi
  • Omid Mazdiyasni
  • Marzi Azarderakhsh
  • Aneseh Alborzi
  • Mohammad J. Tourian
  • Ali Mehran
  • Alireza Farahmand
  • Iman Mallakpour
Article

Abstract

By combining long-term ground-based data on water withdrawal with climate model projections, this study quantifies the compounding effects of human activities and climate change on surface water availability in Iran over the twenty-first century. Our findings show that increasing water withdrawal in Iran, due to population growth and increased agricultural activities, has been the main source of historical water stress. Increased levels of water stress across Iran are expected to continue or even worsen over the next decades due to projected variability and change in precipitation combined with heightened water withdrawals due to increasing population and socio-economic activities. The greatest rate of decreased water storage is expected in the Urmia Basin, northwest of Iran, (varying from ~ − 8.3 mm/year in 2010–2039 to ~ − 61.6 mm/year in 2070–2099 compared with an observed rate of 4 mm/year in 1976–2005). Human activities, however, strongly dominate the effects of precipitation variability and change. Major shifts toward sustainable land and water management are needed to reduce the impacts of water scarcity in the future, particularly in Iran’s heavily stressed basins like Urmia Basin, which feeds the shrinking Lake Urmia.

Notes

Acknowledgement

This study was not supported by any funding agency.

Supplementary material

10584_2018_2336_MOESM1_ESM.docx (1.1 mb)
ESM 1 (DOCX 1107 kb)

References

  1. Abbaspour et al (2009) Assessing the impact of climate change on water resources in Iran. Water Resour Res 45(10):1–16Google Scholar
  2. AghaKouchak A et al (2015a) Aral Sea syndrome desiccates Lake Urmia: call for action. J Great Lakes Res 41(1):307–311Google Scholar
  3. AghaKouchak A et al (2015b) Water and climate: recognize anthropogenic drought. Nature 524(7566):409–411Google Scholar
  4. Alborzi A et al (2018) Climate-informed environmental inflows to revive a drying lake facing meteorological and anthropogenic droughts. Environ Res Lett 13(8):084010Google Scholar
  5. Alcamo J et al (2007) Future long-term changes in global water resources driven by socio-economic and climatic changes. Hydrol Sci J 52(2):247–275Google Scholar
  6. Allen MR, Ingram WJ (2002) Constraints on future changes in climate and the hydrologic cycle. Nature 419(6903):224–232Google Scholar
  7. Arnell NW (2004) Climate change and global water resources. Glob Environ Chang 14(1):31–52Google Scholar
  8. Ashraf B et al (2014) Investigation of temporal and spatial climate variability and aridity of Iran. Theor Appl Climatol 118(1–2):35–46Google Scholar
  9. Ashraf B et al (2017) Quantifying anthropogenic stress on groundwater resources. Sci Rep 7:12910Google Scholar
  10. Cheng L, AghaKouchak A (2015) A methodology for deriving ensemble response from multimodel simulations. J Hydrol 522:49–57Google Scholar
  11. Di Baldassarre G et al (2017) Drought and flood in the Anthropocene: feedback mechanisms in reservoir operation. Earth Syst Dynam 8(1):225–233Google Scholar
  12. Döll P et al (2012) Impact of water withdrawals from groundwater and surface water on continental water storage variations. J Geodyn 59–60:143–156Google Scholar
  13. Döll P, Siebert S (2002) Global modeling of irrigation water requirements. Water Resour Res 38(4):8-1–8-10Google Scholar
  14. Elliott J, Deryng D, Müller C, Frieler K, Konzmann M, Gerten D, Glotter M, Flörke M, Wada Y, Best N, Eisner S, Fekete BM, Folberth C, Foster I, Gosling SN, Haddeland I, Khabarov N, Ludwig F, Masaki Y, Olin S, Rosenzweig C, Ruane AC, Satoh Y, Schmid E, Stacke T, Tang Q, Wisser D (2014) Constraints and potentials of future irrigation water availability on agricultural production under climate change. Proc Natl Acad Sci 111(9):3239–3244Google Scholar
  15. Forootan E et al (2014) Separation of large scale water storage patterns over Iran using GRACE, altimetry and hydrological data. Remote Sens Environ 140:580–595Google Scholar
  16. Frans C et al (2013) Are climatic or land cover changes the dominant cause of runoff trends in the Upper Mississippi River Basin? Geophys Res Lett 40(6):1104–1110Google Scholar
  17. Gleick PH et al (2013) Improving Understanding of the Global Hydrologic Cycle. In: Asrar G, Hurrell J (eds) Climate Science for Serving Society. Springer, DordrechtGoogle Scholar
  18. Gohari A et al (2014) Adaptation of surface water supply to climate change in Central Iran. Journal of Water and Climate Change 5(3):391–407Google Scholar
  19. Gohari A et al (2017) System dynamics evaluation of climate change adaptation strategies for water resources management in Central Iran. Water Resour Manag 31(5):1413–1434Google Scholar
  20. Hanasaki N et al (2008) An integrated model for the assessment of global water resources – part 1: model description and input meteorological forcing. Hydrol Earth Syst Sci 12(4):1007–1025Google Scholar
  21. Hanasaki N et al (2013) A global water scarcity assessment under shared socio-economic pathways part 1: water use. Hydrol Earth Syst Sci 17(7):2375–2391Google Scholar
  22. Hassanzadeh E et al (2012) Determining the main factors in declining the Urmia Lake level by using system dynamics modeling. Water Resour Manag 26(1):129–145Google Scholar
  23. Hassanzadeh E et al (2017) The ecohydrological vulnerability of a large inland delta to changing regional streamflows and upstream irrigation expansion. Ecohydrology 10(4):e1824Google Scholar
  24. Hejazi MI, Voisin N, Lu L, Bramer LM, Fortin DC, Hathaway JE, Huang M, Page K, Ruby Leung L, Li H-Y, Liu Y, Patel PL, Pulsipher TC, Rice JS, Tesfa TK, Vernon CR, Zhou Y (2015) 21st century United States emissions mitigation could increase water stress more than the climate change it is mitigating. Proc Natl Acad Sci 112(34):10635–10640Google Scholar
  25. Held IM, Soden BJ (2006) Robust responses of the hydrological cycle to global warming. J Clim 19(21):5686–5699Google Scholar
  26. Huntington TG (2006) Evidence for intensification of the global water cycle: review and synthesis. J Hydrol 319(1–4):83–95Google Scholar
  27. Iran Water Resource Management Company (IR WRM Co). (2018). Water resource management and sustainable development, Report No 7374, (in Persian). http://www.wrm.ir/index.php?l=EN
  28. Jaramillo P, Nazemi A (2017) Assessing urban water security under changing climate: challenges and ways forward. Sustainable Cities and Society 41:907–918Google Scholar
  29. Knutti R et al (2010) Challenges in combining projections from multiple climate models. J Clim 23(10):2739–2758Google Scholar
  30. Leng G et al (2015) A modeling study of irrigation effects on global surface water and groundwater resources under a changing climate. J Adv Model Earth Syst 7(3):1285–1304Google Scholar
  31. Liu Z et al (2014) Seasonal and regional biases in CMIP5 precipitation simulations. Clim Res 60:35–50.  https://doi.org/10.3354/cr01221 Google Scholar
  32. Loucks DP (2015) Debates-perspectives on socio-hydrology: simulating hydrologic-human interactions. Water Resour Res 51(6):4789–4794Google Scholar
  33. Madani K (2014) Water management in Iran: what is causing the looming crisis? J Environ Stud Sci 4(4):315–328Google Scholar
  34. Madani K et al (2016) Iran’s socio-economic drought: challenges of a water-bankrupt nation. Iran Stud 49(6):997–1016Google Scholar
  35. Mehran A et al (2015) A hybrid framework for assessing socioeconomic drought: linking climate variability, local resilience, and demand. J Geophys Res-Atmos 120(15):7520–7533Google Scholar
  36. Mehran A et al (2017) Compounding impacts of human-induced water stress and climate change on water availability. Sci Rep 7:6282Google Scholar
  37. Mesgaran, B., and Azadi, P., (2018). A national adaptation plan for water scarcity in Iran, working paper 6, Stanford Iran 2040 project, Stanford University, August 2018Google Scholar
  38. Miao C et al (2014) Assessment of CMIP5 climate models and projected temperature changes over Northern Eurasia. Environ Res Lett 9(5):055007Google Scholar
  39. Mirchi A et al (2012) Synthesis of system dynamics tools for holistic conceptualization of water resources problems. Water Resour Manag 26(9):2421–2442Google Scholar
  40. Mirchi A, et al. (2013) Climate change impacts on California’s water resources., In: Schwabe, K., et al. (eds) Drought in arid and semi-arid regions: a multi-disciplinary and cross-country perspective. Springer, pp. 301–319.  https://doi.org/10.1007/978-94-007-6636-5
  41. Mirchi A et al (2014) Water resources management in a homogenizing world: averting the growth and underinvestment trajectory. Water Resour Res 50(9):7515–7526Google Scholar
  42. Nasrollahi N et al (2015) How well do CMIP5 climate simulations replicate historical trends and patterns of meteorological droughts? Water Resour Res 51(4):2847–2864Google Scholar
  43. Nazemi A, Madani K (2017) Urban water security: emerging discussion and remaining challenges. Sustainable Cities and Society 41:925–928Google Scholar
  44. Nazemi A, Wheater HS (2014) Assessing the vulnerability of water supply to changing streamflow conditions. EOS 95(32):288–288Google Scholar
  45. Nazemi A, Wheater HS (2015a) On inclusion of water resource management in earth system models; part 1: problem definition and representation of water demand. Hydrol Earth Syst Sci 19(1):33–61Google Scholar
  46. Nazemi A, Wheater HS (2015b) On inclusion of water resource management in Earth system models; part 2: representation of water supply and allocation and opportunities for improved modeling. Hydrol Earth Syst Sci 19(1):63–90Google Scholar
  47. Nazemi A et al (2013) A stochastic reconstruction framework for analysis of water resource system vulnerability to climate-induced changes in river flow regime. Water Resour Res 49(1):291–305Google Scholar
  48. Nazemi A et al (2017) Forms and drivers of annual streamflow variability in the headwaters of Canadian Prairies during the 20th century: forms and drivers of streamflow variability in Canadian Prairies. Hydrol Process 31(1):221–239Google Scholar
  49. Newman BD et al (2006) Ecohydrology of water-limited environments: a scientific vision. Water Resour Res 42(6):WR004141Google Scholar
  50. Oki T, Kanae S (2006) Global hydrological cycles and world water resources. Science 313(5790):1068–1072Google Scholar
  51. Pokhrel YN et al (2016) Recent progresses in incorporating human land–water management into global land surface models toward their integration into Earth system models. Wiley Interdisciplinary Reviews: Water 3(4):548–574Google Scholar
  52. Rockström J et al (2009) Future water availability for global food production: the potential of green water for increasing resilience to global change. Water Resour Res 45(7):1–16Google Scholar
  53. Sadegh M et al (2010) Optimal inter-basin water allocation using crisp and fuzzy Shapley games. Water Resour Manag 24(10):2291–2310Google Scholar
  54. Santer BD et al (2009) Incorporating model quality information in climate change detection and attribution studies. Proc Natl Acad Sci 106(35):14778–14783Google Scholar
  55. Scanlon B et al (2012) Ground water and climate change. Nat Clim Chang 3(4):322–329Google Scholar
  56. Sima S, Tajrishy M (2013) Using satellite data to extract volume–area–elevation relationships for Urmia Lake, Iran. J Great Lakes Res 39(1):90–99Google Scholar
  57. Sivapalan M (2015) Debates-perspectives on socio-hydrology: changing water systems and the “tyranny of small problems”. Water Resour Res 51(6):4795–4805Google Scholar
  58. Stevens T, Madani K (2016) Future climate impacts on maize farming and food security in Malawi. Sci Rep 6:36241Google Scholar
  59. Taylor KE (2001) Summarizing multiple aspects of model performance in a single diagram. J Geophys Res-Atmos 106(D7):7183–7192Google Scholar
  60. Taylor KE et al (2012) An overview of CMIP5 and the experiment design. Bull Am Meteorol Soc 93(4):485–498Google Scholar
  61. Tourian MJ et al (2015) A spaceborne multisensor approach to monitor the desiccation of Lake Urmia in Iran. Remote Sens Environ 156:349–360Google Scholar
  62. Van Loon AF et al (2016a) Drought in a human-modified world: reframing drought definitions, understanding, and analysis approaches. Hydrol Earth Syst Sci 20(9):3631–3650Google Scholar
  63. Van Loon AF et al (2016b) Drought in the Anthropocene. Nat Geosci 9(2):89–91Google Scholar
  64. Vogel RM et al (2015) Hydrology: the interdisciplinary science of water. Water Resour Res 51(6):4409–4430Google Scholar
  65. Vörösmarty CJ et al (2000) Global water resources: vulnerability from climate change and population growth. Science 289(5477):284–288Google Scholar
  66. Wada Y et al (2010) Global depletion of groundwater resources. Geophys Res Lett 37(20):GL044571Google Scholar
  67. Wang D, Hejazi M (2011) Quantifying the relative contribution of the climate and direct human impacts on mean annual streamflow in the contiguous United States. Water Resour Res 47(10):WR010283Google Scholar
  68. Wang W, Ding Y, Shao Q, Xu J, Jiao X, Luo Y, Yu Z (2017) Bayesian multi-model projection of irrigation requirement and water use efficiency in three typical rice plantation region of China based on CMIP5. Agric For Meteorol 232:89–105Google Scholar
  69. Weiskel PK et al (2007) Water use regimes: characterizing direct human interaction with hydrologic systems. Water Resour Res 43(4):WR005062Google Scholar
  70. Wheater HS, Gober P (2015) Water security and the science agenda. Water Resour Res 51(7):5406–5424Google Scholar
  71. World Bank (2017) Annual freshwater withdrawals, total. Retrieved from https://data.worldbank.org/indicator/ER.H2O.FWTL.ZS?view=chart, 1962–2014

Copyright information

© Springer Nature B.V. 2018

Authors and Affiliations

  • Samaneh Ashraf
    • 1
    • 2
  • Amir AghaKouchak
    • 1
    Email author
  • Ali Nazemi
    • 3
  • Ali Mirchi
    • 4
  • Mojtaba Sadegh
    • 5
  • Hamed R. Moftakhari
    • 1
    • 6
  • Elmira Hassanzadeh
    • 7
  • Chi-Yuan Miao
    • 8
  • Kaveh Madani
    • 9
    • 10
  • Mohammad Mousavi Baygi
    • 2
  • Hassan Anjileli
    • 1
  • Davood Reza Arab
    • 11
  • Hamid Norouzi
    • 12
  • Omid Mazdiyasni
    • 1
  • Marzi Azarderakhsh
    • 13
  • Aneseh Alborzi
    • 1
  • Mohammad J. Tourian
    • 14
  • Ali Mehran
    • 15
  • Alireza Farahmand
    • 16
  • Iman Mallakpour
    • 1
  1. 1.University of CaliforniaIrvineUSA
  2. 2.Ferdowsi University of MashhadMashhadIran
  3. 3.Concordia UniversityMontrealCanada
  4. 4.Oklahoma State UniversityStillwaterUSA
  5. 5.Boise State UniversityBoiseUSA
  6. 6.University of AlabamaTuscaloosaUSA
  7. 7.Polytechnique MontrealMontrealCanada
  8. 8.Beijing Normal UniversityBeijingChina
  9. 9.Imperial College LondonLondonUK
  10. 10.Stockholm UniversityStockholmSweden
  11. 11.Rahbord Danesh Pooya InstituteTehranIran
  12. 12.City University of New YorkNew YorkUSA
  13. 13.Fairleigh Dickinson UniversityTeaneckUSA
  14. 14.University of StuttgartStuttgartGermany
  15. 15.University of CaliforniaLos AngelesUSA
  16. 16.NASA Jet Propulsion LaboratoryPasadenaUSA

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