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Climate Change, Water Resources, and Agriculture: Impacts and Adaptation Measures

  • Durba Kashyap
  • Tripti Agarwal
Chapter

Abstract

Agriculture is one of the key domains that is significantly affected by climate change. The chapter presents the observed and projected impact of climate change on freshwater resources globally. In addition to this, case studies of successful implementation of adaptation measures adopted to tackle climate change-induced water stress in agriculture have been discussed with a special focus on high-altitude farming systems particularly vulnerable to increasing climate risk. As one of the potential adaptation measures, the relevance of water footprint as a tool to optimize water use and strategize cropping patterns with respect to crop water use efficiency and prevailing climatic conditions has also been discussed.

Keywords

Climate change Freshwater resources Water footprint Agriculture Adaptation Irrigation water policy 

References

  1. Adger N, Arnell N, Tompkins E (2005) Successful adaptation to climate change across scales. Glob Environ Chang 15(2):77–86CrossRefGoogle Scholar
  2. Agarwal A, Narain S (eds) (1997) Dying wisdom: rise, fall and potential of India’s traditional water harvesting systems. Center for Science and Environment, New Delhi, 404 ppGoogle Scholar
  3. Aguilera H, Murillo JM (2009) The effect of possible climate change on natural groundwater recharge based on a simple model: a study of four karstic aquifers in SE Spain. Environ Geol 57(5):963–974CrossRefGoogle Scholar
  4. Alkama R, Decharme B, Douville H, Ribes A (2011) Trends in global and basin scale runoff over the late twentieth century: methodological issues and sources of uncertainty. J Clim 24(12):3000–3014CrossRefGoogle Scholar
  5. Allen RG, Pereira LS, Raes D, Smith M (1998) Crop evapotranspiration: guidelines for computing crop water requirements. FAO Irrigation and Drainage Paper 56, 300 ppGoogle Scholar
  6. Anderson J, Arblaster K, Bartley J (2008) Climate change-induced water stress and its impacts on natural and managed ecosystems. European Parliament, BrusselsGoogle Scholar
  7. Baraer M, Mark BG, McKenzie JM, Condom T, Bury J, Huh K, Portocarrero C, Gomez J, Rathay S (2012) Glacier recession and water resources in Peru’s Cordillera Blanca. J Glaciol 58(207):134–150CrossRefGoogle Scholar
  8. Bates BC, Kundzewicz ZW, Wu S, Palutikof JP (eds) (2008) Climate change and water. Technical Paper of the Intergovernmental Panel on Climate Change. IPCC Secretariat, GenevaGoogle Scholar
  9. Birkenholtz T (2017) Assessing India’s drip-irrigation boom: efficiency, climate change and groundwater policy. Water Int 42:663–677CrossRefGoogle Scholar
  10. Boland AM, Mitchell PD, Jerie PH, Goodwin I (1993) Effect of regulated deficit irrigation on tree water use and growth of peach. J Hortic Sci 68:261–274CrossRefGoogle Scholar
  11. Bolch T, Kulkarni A, Kaab A, Huggel C, Paul F, Cogley JG, Frey H, Kargel JS, Fujita K, Scheel M, Bajracharya S, Stoffel M (2012) The state and fate of Himalayan glaciers. Science 336(6079):310–314CrossRefGoogle Scholar
  12. Bruinsma J (2003) World agriculture: towards 2015/2030. An FAO perspective. Earthscan, London, 444 ppGoogle Scholar
  13. Burke EJ, Brown SJ, Christidis N (2006) Modelling the recent evolution of global drought and projections for the 21 st century with the Hadley Centre climate model. J Hydrometeorol 7:1113–1125CrossRefGoogle Scholar
  14. Burton I (1996) The growth of adaptation capacity: practice and policy. In: Smith JB et al (eds) Adapting to climate change: an international perspective. Springer, New York, pp 55–67CrossRefGoogle Scholar
  15. Chapagain AK, Hoekstra AY, Savenije HHG (2006) Water saving through international trade of agricultural products. Hydrol Earth Syst Sci 10:455–468CrossRefGoogle Scholar
  16. Chartzoulakis K, Bertaki M (2015) Sustainable water management in agriculture under climate change, 4 agriculture and agricultural. Sci Procedia 4:88–98Google Scholar
  17. Chen Y, Li W, Deng H, Fang G, Li Z (2016) Changes in Central Asia’s water tower: past, present and future. Sci Report 6:35458CrossRefGoogle Scholar
  18. Cisneros JBE, Oki T, Arnell NW, Benito G, Cogley JG, Döll P, Jiang T, Mwakalila SS, (2014) Freshwater resources. In: Climate change 2014: impacts, adaptation, and vulnerability. Part A: Global and sectoral aspects. Contribution of Working Group II to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge University Press, Cambridge/New York, pp 229–269Google Scholar
  19. Clements T, D’Amato V, Taylor T (2010) Integrating water infrastructure in a new paradigm for sustainable, resilient communities. In: Proceedings of the Water Environment Federation, Cities of the Future/Urban River Restoration, pp 801–825Google Scholar
  20. Clouse C, Anderson N, Shippling T (2017) Ladakh’s artificial glaciers: climate-adaptive design for water scarcity. Clim Dev 9(5):428–438.  https://doi.org/10.1080/17565529.2016.1167664CrossRefGoogle Scholar
  21. Clow DW (2010) Changes in the timing of snowmelt and streamflow in Colorado: a response to recent warming. J Clim 23(9):2293–2306CrossRefGoogle Scholar
  22. Collins DN (2008) Climatic warming, glacier recession and runoff from Alpine basins after the Little Ice Age maximum. Ann Glaciol 48(1):119–124CrossRefGoogle Scholar
  23. Crosbie RS, Pickett T, Mpelasoka FS, Hodgson G, Charles SP, Barron OV (2013) An assessment of the climate change impacts on groundwater recharge at a continental scale using a probabilistic approach with an ensemble of GCMs. Clim Chang 117(1–2):41–53CrossRefGoogle Scholar
  24. Dai A, Trenberth KE, Qian T (2004) A global data set of Palmer Drought Severity Index for 1870–2002: relationship with soil moisture and effects of surface warming. J Hydro meteorol 5:1117–1130Google Scholar
  25. Dai A, Qian T, Trenberth KE, Milliman JD (2009) Changes in continental freshwater discharge from 1948 to 2004. J Clim 22(10):2773–2792CrossRefGoogle Scholar
  26. Döll P, Müller Schmied H (2012) How is the impact of climate change on river flow regimes related to the impact on mean annual runoff? A global-scale analysis. Environ Res Lett 7:014037CrossRefGoogle Scholar
  27. Earman S, Campbell AR, Phillips FM, Newman BD (2006) Isotopic exchange between snow and atmospheric water vapor: estimation of the snowmelt component of groundwater recharge in the southwestern United States. J Geophys Res Atmos 111(D9):D09302CrossRefGoogle Scholar
  28. Elliott M, Armstrong A, Lobuglio J, Bartram J (2011) In: De Lopez T (ed) Technologies for climate change adaptation: the water sector, TNA guidebook series. UNEP Risø Centre, Roskilde, 114 ppGoogle Scholar
  29. Finger R, Hediger W, Schmid S (2011) Irrigation as adaptation strategy to climate change – a biophysical and economic appraisal for Swiss maize production. Clim Chang 105(3–4):509–528CrossRefGoogle Scholar
  30. Gardelle J, Arnaud Y, Berthier E (2011) Contrasted evolution of glacial lakes along the Hindu Kush Himalaya mountain range between 1990 and 2009. Glob Planet Chang 75(1–2):47–55CrossRefGoogle Scholar
  31. Gardner AS, Moholdt G, Cogley JG, Wouters B, Arendt AA, Wahr J, Berthier E, Hock R, Pfeffer WT, Kaser G, Ligtenberg SRM, Bolch SMJ, Hagen JO, Van den Broeke MR, Paul F (2013) A reconciled estimate of glacier contributions to sea level rise: 2003 to 2009. Science 340(6134):852–857Google Scholar
  32. Gerten D, Rost S, von Bloh W, Lucht W (2008) Causes of change in 20th century global river discharge. Geophys Res Lett 35(20):L20405CrossRefGoogle Scholar
  33. Gerten D, Heinke J, Hoff H, Biemans H, Fader M, Waha K (2011) Global water availability and requirements for future food production. J Hydrometeorol 12(5):885–899CrossRefGoogle Scholar
  34. Gerten D, Lucht W, Ostberg S, Heinke J, Kowarsch M, Kreft H, Kundzewicz ZW, Rastgooy J, Warren R, Schellnhuber HJ (2013) Asynchronous exposure to global warming: freshwater resources and terrestrial ecosystems. Environ Res Lett 8(3):034032CrossRefGoogle Scholar
  35. Ghazouani W, Molle F, Swelam A, Rap E, Abdo A (2014) Understanding farmers’ adaptation to water scarcity: a case study from the western Nile Delta, Egypt, IWMI Research Report 160. International Water Management Institute (IWMI), Colombo. 31pGoogle Scholar
  36. Giannakis E, Bruggeman A, Djuma H, Kozyra J, Hammer J (2016) Water pricing and irrigation across Europe: opportunities and constraints for adopting irrigation scheduling decision support systems. Water Sci Technol Water Supply 16(1):245–252CrossRefGoogle Scholar
  37. Gil J, Kamanda J (2015) Policies and initiatives related to water and climate change in agriculture: case studies from Brazil and Africa. In: Zolin CA, Rodrigues R (eds) Impact of climate change on water resources in agriculture. CRC Press, Taylor and Francis Group, Boca Raton, pp 39–61Google Scholar
  38. Goodwin I, Jerie P (1992) Regulated deficit irrigation: from concept to practice. Aust N Z Wine Ind J 5:131–133Google Scholar
  39. Government of Western Australia (2003) Securing our water future: a state water strategy for Western Australia. Government of WA, 64 pp. Available http://dows.lincdigital.com.au/files/State_Water_Strategy_complete_001.pdf
  40. Grafton RQ, Williams J, Perry CJ, Molle F, Ringler C, Steduto P et al (2018) The paradox of irrigation efficiency. Science 361:748–750CrossRefGoogle Scholar
  41. Grossman D (2015) As Himalayan glaciers melt, two towns face the fallout. Yale Environment 360. http://e360.yale.edu/feature/as_himalayan_glaciers_melt_two_towns_face_the_fallout/2858/. Accessed 8 Oct 2018
  42. Gutschow K, Mankelow S (2001) Dry winters, dry summers: water shortages in Zanskar. Ladakh Studies 15:28–32Google Scholar
  43. Hanasaki N, Fujimori S, Yamamoto T, Yoshikawa S, Masaki Y, Hijioka Y, Kainuma M, Kanamori Y, Masui T, Takahashi K, Kanae S (2013) A global water scarcity assessment under shared socio-economic pathways – part 2: water availability and scarcity. Hydrol Earth Syst Sci 17:2393–2413CrossRefGoogle Scholar
  44. Hidalgo HG, Das T, Dettinger MD, Cayan DR, Pierce DW, Barnett TP, Bala G, Mirin A, Wood AW, Bonfils C, Santer BD, Nozawa T (2009) Detection and attribution of streamflow timing changes to climate change in the western United States. J Clim 22(13):3838–3855CrossRefGoogle Scholar
  45. Hirabayashi Y, Mahendran R, Koirala S, Konoshima L, Yamazaki D, Watanabe S, Kanae S (2013) Global flood risk under climate change. Nat Clim Chang 3:816–821CrossRefGoogle Scholar
  46. Hoekstra AY, Chapagain AK, Aldaya MM, Mekonnen MM (2011) The water footprint assessment manual: setting the global standard. Earthscan, LondonGoogle Scholar
  47. Holman IP, Tascone D, Hess TM (2009) A comparison of stochastic and deterministic downscaling methods for modelling potential groundwater recharge under climate change in East Anglia, UK: implications for groundwater resource management. Hydrogeol J 17(7):1629–1641CrossRefGoogle Scholar
  48. Huss M (2011) Present and future contribution of glacier storage change to runoff from macroscale drainage basins in Europe. Water Resour Res 47:W07511CrossRefGoogle Scholar
  49. ICIMOD (2009) Water storage: a strategy for climate change adaptation in the Himalayas, sustainable mountain development no. 56, special issue. International Centre for Integrated Mountain Development, KathmanduGoogle Scholar
  50. Iglesias A, Garrote L (2015) Adaptation strategies for agricultural water management under climate change in Europe. Agric Water Manag 155:113–124CrossRefGoogle Scholar
  51. Immerzeel WW, Beek LPH, Bierkens MFP (2010) Climate change will affect the Asian water towers. Science 328:1382–1385CrossRefGoogle Scholar
  52. IPCC (2000) Summary for policy makers: emission scenarios. A special report of IPCC Working Group III. Available https://ipcc.ch/pdf/special-reports/spm/sres-en.pdf. Accessed 25 Oct 2018
  53. IPCC (2007a) Climate change 2007: the physical science basis. Contribution of Working Group I to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge University Press, Cambridge/New York, 996 ppGoogle Scholar
  54. IPCC (2007b) Climate change 2007: impacts, adaptation and vulnerability. Contribution of Working Group II to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change [Parry ML, Canziani OF, Palutikof JP, van der Linden PJ, Hanson CE, eds]. Cambridge University Press, Cambridge, 976ppGoogle Scholar
  55. IPCC (2007c) Climate change 2007: synthesis report. Contribution of working groups I, II and III to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change. IPCC, Geneva, 104 ppGoogle Scholar
  56. IPCC (2013) Climate change 2013: the physical science basis. Contribution of Working Group I to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge University Press, Cambridge/New York, 1535 ppGoogle Scholar
  57. Jansson P, Hock R, Schneider T (2003) The concept of glacier storage: a review. J Hydrol 282:116–129CrossRefGoogle Scholar
  58. Jeelani G (2008) Aquifer response to regional climate variability in a part of Kashmir Himalaya in India. Hydrogeol J 16(8):1625–1633CrossRefGoogle Scholar
  59. Kang S, Hao X, Du T, Tong L, Su X, Lu H, Li X, Huo Z, Li S, Ding R (2017) Improving agricultural water productivity to ensure food security in China under changing environment: from research to practice. Agric Water Manag 179:5–17.  https://doi.org/10.1016/j.agwat.2016.05.007CrossRefGoogle Scholar
  60. Knox JW, Kay MG, Weatherhead EK (2012) Water regulation, crop production and agricultural water management—understanding farmer perspectives on irrigation efficiency. Agric Water Manag 108(1):3–8CrossRefGoogle Scholar
  61. Koboltschnig GR, Schöner W, Zappa M, Holzmann H (2007) Contribution of glacier melt to stream runoff: if the climatically extreme summer of 2003 had happened in 1979. Ann Glaciol 46(1):303–308CrossRefGoogle Scholar
  62. Konar M, Hussein Z, Hanasaki N, Mauzerall DL, Rodriguez-Iturbe I (2013) Virtual water trade flows and savings under climate change. Hydrol Earth Syst Sci 17(8):3219–3234CrossRefGoogle Scholar
  63. Korhonen J, Kuusisto E (2010) Long-term changes in the discharge regime in Finland. Hydrol Res 41(3–4):253–268CrossRefGoogle Scholar
  64. Kundzewicz ZW, Döll P (2009) Will groundwater ease freshwater stress under climate change? Hydrol Sci J 54(4):665–675CrossRefGoogle Scholar
  65. Levidow L, Zaccaria D, Maia R, Vivas E, Todorovic M, Scardigno A (2014) Improving water-efficient irrigation: prospects and difficulties of innovative practices. Agric Water Manag 146:84–94CrossRefGoogle Scholar
  66. Lovarelli D, Bacenetti J, Fiala M (2016) Science of the total environment water footprint of crop productions: a review. Sci Total Environ 548–549:236–251CrossRefGoogle Scholar
  67. Loveys BR, Dry PR, McCarthy MG (1999) Using plant physiology to improve water use efficiency of horticultural crops. Acta Hortic 537:187–199Google Scholar
  68. Luquet D, Vidal A, Smith M, Dauzatd J (2005) More crop per drop: how to make it acceptable for farmers? Agric Water Manag 76(2):108–119CrossRefGoogle Scholar
  69. Mali S, Singh DK, Sarangi A, Parihar SS (2018) Assessing water footprints and virtual water flows in Gomti river basin of India. Curr Sci 115(4):721–728CrossRefGoogle Scholar
  70. Malik RPS, Giordano M, Rathore MS (2016) The negative impact of subsidies on the adoption of drip irrigation in India: evidence from Madhya Pradesh. Int J Water Resour Dev 0627:1–12Google Scholar
  71. Malone EL (2010) Changing glaciers and hydrology in Asia: addressing vulnerabilities to glacier melt impacts. United States Agency for International Development (USAID) Report November 2010, pp 1–113Google Scholar
  72. Mamitimin Y, Feike T, Seifert I, Doluschitz R (2015) Irrigation in the Tarim Basin, China: farmers’ response to changes in water pricing practices. Environ Earth Sci 73(2):559–569CrossRefGoogle Scholar
  73. Mann M, Gaudet B (2018) SRES’ scenarios and ‘RCP’ pathways. In: Meteorology to mitigation: understanding global warming. Available https://www.e-education.psu.edu/meteo469/node/145. Accessed 25 Oct 2018
  74. Mannini P, Genovesi R, Letterio T (2013) IRRINET: large scale DSS application for on-farm irrigation scheduling. Procedia Environ Sci 19:823–829CrossRefGoogle Scholar
  75. McCartney M, Smakhtin V (2010) Water storage in an era of climate change: addressing the challenges of increasing rainfall variability, IWMI Blue Paper. International Water Management Institute, ColomboGoogle Scholar
  76. McVeigh M, Wyllie A (2018) Memo on irrigation efficiency and ESPA storage changes, State of Idaho Department of Water ResourcesGoogle Scholar
  77. Min S, Zhang X, Zwiers FW, Hegerl GC (2011) Human contribution to more intense precipitation extremes. Nature 470(7334):378–381CrossRefGoogle Scholar
  78. Mingle J (2009) When the glacier left. Boston Globe. Available http://archive.boston.com/bostonglobe/ideas/articles/2009/11/29/when_the_glacier_left/. Accessed 20 Oct 2018
  79. Mingle J (2015) Fire and ice: soot, solidarity and survival on the roof of the world. St. Martin’s Press, New YorkGoogle Scholar
  80. Molden D, Oweis T, Steduto P, Bindraban P, Hanjra MA, Kijne J (2010) Improving agricultural water productivity: between optimism and caution. Agric Water Manag 97:528–535CrossRefGoogle Scholar
  81. Molden DJ, Vaidya RA, Shrestha AB, Rasul G, Shrestha MS (2014) Governance and management of local water storage in the Hindu Kush Himalayas. Int J Water Resour Dev. Taylor & FrancisGoogle Scholar
  82. Molle F, Berkoff J (2007) Water pricing in irrigation: the lifetime of an idea. In: Molle F, Berkoff J (eds) Irrigation water pricing: the gap between theory and practice. CABI, Wallingford, pp 1–20CrossRefGoogle Scholar
  83. Molle F (2008) Can water pricing policies regulate irrigation use? In: 13th World Water Congress, September, Montpellier, FranceGoogle Scholar
  84. Molle F, Tanouti O (2017) Squaring the circle: agricultural intensification vs. water conservation in Morocco. Agric Water Manag 192:170–179CrossRefGoogle Scholar
  85. Nelson G, Palazzo A, Ringler C, Sulser T, Batka M (2009) The role of international trade in climate change adaptation, ICTSDIPC platform on climate change, Agriculture and Trade Series, Issue Brief 4Google Scholar
  86. Nüsser M, Dame J, Kraus B, Baghel R, Schmidt S (2018) Socio-hydrology of “artificial glaciers” in Ladakh, India: assessing adaptive strategies in a changing cryosphere. Reg Environ Chang:1–11Google Scholar
  87. Oki T, Kanae S (2006) Global hydrological cycles and world water resources. Science 313(5790):1068–1072CrossRefGoogle Scholar
  88. Pall P, Aina T, Stone DA, Stott PA, Nozawa T, Hilberts AGJ, Lohmann D, Allen MR (2011) Anthropogenic greenhouse gas contribution to flood risk in England and Wales in autumn 2000. Nature 470(7334):382–385CrossRefGoogle Scholar
  89. Perry C, Steduto P, Allen RG, Burt CM (2009) Increasing productivity in irrigated agriculture: agronomic constraints and hydrological realities. Agric Water Manag 96:1517–1524CrossRefGoogle Scholar
  90. Perry C, Steduto P, Karajeh F (2017) Does improved irrigation technology save water? A review of the evidence. Food and Agriculture Organization of the United Nations, CairoGoogle Scholar
  91. Pfeiffer L, Lin Lawell C-YC (2014) Does efficient irrigation technology lead to reduced groundwater extraction? Empirical evidence. J Environ Econ Manag 67(2):189–208.  https://doi.org/10.1016/j.jeem.2013.12.002CrossRefGoogle Scholar
  92. Piao S, Friedlingstein P, Ciais P, de Noblet-Ducoudre N, Labat D, Zaehle S (2007) Changes in climate and land use have a larger direct impact than rising CO2 on global river runoff trends. Proc Natl Acad Sci U S A 104(39):15242–15247CrossRefGoogle Scholar
  93. Piao S, Ciais P, Huang Y, Shen Z, Peng S, Li J, Zhou L, Liu H, Ma Y, Ding Y, Friedlingstein P, Liu C, Tan K, Yu Y, Zhang T, Fang J (2010) The impacts of climate change on water resources and agriculture in China. Nature 467(7311):43–51CrossRefGoogle Scholar
  94. Portmann FT, Döll P, Eisner S, Flörke M (2013) Impact of climate change on renewable groundwater resources: assessing the benefits of avoided greenhouse gas emissions using selected CMIP5 climate projections. Environ Res Lett 8(2):024023CrossRefGoogle Scholar
  95. Rabassa J (2009) Impact of global climate change on glaciers and permafrost of South America, with emphasis on Patagonia, Tierra del Fuego, and the Antarctic Peninsula. Dev Earth Surf Process 13:415–438CrossRefGoogle Scholar
  96. Rabatel A et al (2013) Current state of glaciers in the tropical Andes: a multi-century perspective on glacier evolution and climate change. Cryosphere 7(1):81–102CrossRefGoogle Scholar
  97. Ridoutt BG, Pfister S (2010) A revised approach to water footprinting to make transparent the impacts of consumption and production on global freshwater scarcity. Glob Environ Chang 20(1):113–120CrossRefGoogle Scholar
  98. Rizvi J (1998) Ladakh: crossroads of high Asia. Oxford University Press, DelhiGoogle Scholar
  99. Rosenzweig C, Casassa G, Karoly DJ, Imeson A, Liu C, Menzel A, Rawlins S, Root TL, Seguin B, Tryjanowski P (2007) Assessment of observed changes and responses in natural and managed systems. In: Climate change 2007: impacts, adaptation and vulnerability. Contribution of Working Group II to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change [Parry ML, Canziani OF, Palutikof JP, van der Linden PJ, Hanson CE (eds)]Google Scholar
  100. Schewe J, Heinke J, Gerten D, Haddeland I, Arnell N, Clark D, Dankers R, Eisner S, Fekete B, Colón-González F, Gosling S, Kim H, Liu X, Masaki Y, Portmann F, Satoh Y, Stacke T, Tang Q, Wada Y, Wisser D, Albrecht T, Frieler K, Piontek F, Warszawski L, Kabat P (2014) Multimodel assessment of water scarcity under climate change. Proc Natl Acad Sci 111:3245–3250.  https://doi.org/10.1073/pnas.1222460110CrossRefGoogle Scholar
  101. Sepaskhah AR, Ahmadi SH (2010) A review on partial root-zone drying irrigation. Int J Plant Prod 4(4)Google Scholar
  102. Shaheen FA (2016) The art of glacier grafting: innovative water harvesting techniques in Ladakh. IWMI-Tata Water Policy Research Highlight, 8. 8pGoogle Scholar
  103. Shiklomanov AI, Lammers RB, Rawlins MA, Smith LC, Pavelsky TM (2007) Temporal and spatial variations in maximum river discharge from a new Russian data set. J Geophys Res Biogeosci 112(G4):G04S53CrossRefGoogle Scholar
  104. Skaugen T, Stranden HB, Saloranta T (2012) Trends in snow water equivalent in Norway (1931–2009). Hydrol Res 43(4):489–499CrossRefGoogle Scholar
  105. Smit B, Skinner MW (2002) Adaptation options in agriculture to climate change: a typology. Mitig Adapt Strateg Glob Chang 7:85–114CrossRefGoogle Scholar
  106. Smith M, Kivumbi D (2000) Use of the FAO CROPWAT model in deficit irrigation studies. In: Deficit irrigation practices. Food and Agriculture Organization, Rome. Available http://www.fao.org/docrep/004/Y3655E/y3655e05.htm. Accessed 3 Oct 2018
  107. Stern N (2006) The economics of climate change: the stern review. Cambridge University Press, CambridgeGoogle Scholar
  108. Sugden F, Shrestha L, Bharati L, Gurung P, Maharjan L, Janmaat J, Price J, Sherpa TYC, Bhattarai U, Koirala S (2014) Climate change, out-migration and agrarian stress: the potential for upscaling small-scale water storage in Nepal (research report). International Water Management Institute (IWMI), Colombo.  https://doi.org/10.5337/2014.210
  109. Takala M, Pulliainen J, Metsamaki SJ, Koskinen JT (2009) Detection of snowmelt using spaceborne microwave radiometer data in Eurasia from 1979 to 2007. IEEE Trans Geosci Remote Sens 47(9):2996–3007CrossRefGoogle Scholar
  110. Tan A, Adam JC, Lettenmaier DP (2011) Change in spring snowmelt timing in Eurasian Arctic rivers. J Geophys Res Atmos 116:D03101Google Scholar
  111. Taylor IH, Burke E, McColl L, Falloon PD, Harris GR, McNeall D (2013) The impact of climate mitigation on projections of future drought. Hydrol Earth Syst Sci 17(6):2339–2358CrossRefGoogle Scholar
  112. United Nations Framework Convention on Climate Change (UNFCCC) (1992) United nations framework convention on climate change: text, Geneva, World Meteorological Organization and United Nations Environment ProgramGoogle Scholar
  113. United Nations Framework Convention on Climate Change (UNFCCC) (1998) The Kyoto Protocol to the UNFCCC. In: UNFCCC, Report of the Conference of the Parties Third Session, Kyoto, UNFCCC, pp 4–29Google Scholar
  114. Vaidya RA (2015) Governance and management of local water storage in the Hindu Kush Himalayas. Int J Water Resour Dev 31(2):253–268CrossRefGoogle Scholar
  115. Venkatramanan V, Shah S (2019) Climate smart agriculture technologies for environmental management: the intersection of sustainability, resilience, wellbeing and development. In: Shah S et al (eds) Sustainable green technologies for environmental management. Springer Nature Singapore Pte Ltd., Singapore, pp 29–51.  https://doi.org/10.1007/978-981-13-2772-8_2CrossRefGoogle Scholar
  116. Vidal JP, Martin E, Kitova N, Najac J, Soubeyroux J-M (2012) Evolution of spatio-temporal drought characteristics: validation, projections and effect of adaptation scenarios. Hydrol Earth Syst Sci 16(8):2935–2955CrossRefGoogle Scholar
  117. Vince G (2010) A Himalayan village builds artificial glaciers to survive global warming. Sci Am. https://www.scientificamerican.com/article/artificial-glaciers-to-survive-global-warming/. Accessed 21 Oct 2018
  118. Viviroli D, Dürr HH, Messerli B, Meybeck M, Weingartner R (2007) Mountains of the world, water towers for humanity: typology, mapping, and global significance. Water ResWater Res 43:W07447Google Scholar
  119. Viviroli D, Archer DR, Buytaert W, Fowler HJ, Greenwood GB, Hamlet AF, Huang Y, Koboltschnig G, Litaor MI, López-Moreno JI, Lorentz S, Schädler B, Schreier H, Schwaiger K, Vuille M, Woods R (2011) Climate change and mountain water resources: overview and recommendations for research, management and policy. Hydrol Earth Syst Sci 15(2):471–504CrossRefGoogle Scholar
  120. Wada Y, Wisser D, Eisner S, Flörke M, Gerten D, Haddeland I, Hanasaki N, Masaki Y, Portmann FT, Stacke T, Tessler Z, Schewe J (2013) Multi-model projections and uncertainties of irrigation water demand under climate change. Geophys Res Lett 40(17):4626–4632CrossRefGoogle Scholar
  121. Wang A, Lettenmaier DP, Sheffield J (2011) Soil moisture drought in China, 1950–2006. J Clim 24(13):3257–3271CrossRefGoogle Scholar
  122. Wang YB, Wu PT, Engel BA, Sun SK (2015) Comparison of volumetric and stress-weighted water footprint of grain products in China. Ecol Indic 48:324–333Google Scholar
  123. Ward FA, Pulido-Velazquez M (2008) Water conservation in irrigation can increase water use. Proc Natl Acad Sci U S A 105:18215–18220CrossRefGoogle Scholar
  124. Yoo S-H, Choi J-Y, Lee S-H, Oh Y-G, Yun DK (2013) Climate change impacts on water storage requirements of an agricultural reservoir considering changes in land use and rice growing season in Korea. Agric Water Manag 117:43–54CrossRefGoogle Scholar
  125. Zeng Z, Liu J, Koeneman PH, Zarate E, Hoekstra AY (2012) Assessing water footprint at river basin level: a case study for the Heihe River Basin in Northwest China. Hydrol Earth Syst Sci 16(8):2771–2781CrossRefGoogle Scholar
  126. Zou X, Li Y, Gao Q, Wan Y (2012) How water saving irrigation contributes to climate change resilience – a case study of practices in China. Mitig Adapt Strateg Glob Chang 17:111–132CrossRefGoogle Scholar
  127. Zou X, Cremades R, Gao Q, Wan Y, Qin X (2013) Cost-effectiveness analysis of water-saving irrigation technologies based on climate change response : a case study of China. Agric Water Manag 129:9–20CrossRefGoogle Scholar

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© Springer Nature Singapore Pte Ltd. 2020

Authors and Affiliations

  • Durba Kashyap
    • 1
  • Tripti Agarwal
    • 1
  1. 1.National Institute of Food Technology Entrepreneurship and ManagementKundli, SonipatIndia

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