Abstract
Water scarcity is a challenging environmental problem in global arid regions in the twenty-first century. Global climate change and urban economic development exacerbate the problem of limited water supply and water shortage. In Asian arid areas, water has been being an important economic lifeline to maintain a healthy and sustainable oasis system. This study took the Heihe River Basin (HRB) in China’s north-western arid area as a typical case region, identified an analytic framework of water resource system risk (WRSR) and analysed systematically the WRSR degree from the different perspectives. The results indicated that the runoff from mountainous watershed showed an increasing trend, but the total amount of watershed water resource showed a decreasing trend in the HRB in the past 50 years. Besides serious drought risk in recent 20 years, the WRSR is mainly from excessive water use in agriculture irrigation. Overall, the WRSR has increased from the year 2000 onward and is expected to increase and fluctuate in the future. Similarly, the potential WRSR is also huge in some arid watersheds relied heavily on glacial runoff in the world. In order to reduce water scarcity risk, it is necessary to implement and carry out effectively the watershed management policies of water resource; coordinate with the balance between the river and tributaries, surface water and groundwater and water quantity and quality to ensure the reasonable water supply in the different regions and water sectors; and promote rational industry structure adjustment and the innovations and applications of water saving and conservancy science and technology.
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References
Aleksandrova M, Gain AK, Giupponi C (2015) Assessing agricultural systems vulnerability to climate change to inform adaptation planning: an application in Khorezm, Uzbekistan. Mitig Adapt Strateg Glob Chang 21:1263–1287. https://doi.org/10.1007/s11027-015-9655-y
An ML, Zhang B, Sun LW et al (2013) Quantitative analysis of dynamic change of land use and its influencing factors in upper reaches of the Heihe river. J Glaciol Geocryol 35(2):355–363 (in Chinese)
Benini L, Bandini V, Marazza D, Contin A (2010) Assessment of land use changes through an indicator-based approach: a case study from the Lamone river basin in Northern Italy. Ecol Indic 10:4–14
Bie Q, Qiang WL, Wang C et al (2013) Monitor glacier variation in the upper reaches of the Heihe river based on remote sensing in 1960-2010. J Glaciol Geocryol 53(3):574–580 (in Chinese)
Borchardt D, Bogardi J, Ibisch R (2016) Integrated water resources management: concept, research and implementation. Springer, Heidelberg & New York
Bossel H (1999) Indicators for sustainable development: theory, method, applications. A report to the Balaton group, Winnipeg, International Institute for Sustainable Development, Canada
Burke EJ, Brown SJ (2008) Evaluation uncertainties in the projection of future drought. J Hydrometeorol 9(2):292–299
Chen YN, Yang Q, Luo Y et al (2012) Ponder on the issues of water resources in the arid region of northwest China. Arid Land Geography 35(1):1–8 (in Chinese)
Chen J, Wan S, Henebry G et al (2013) Dryland East Asia: land dynamics amid social and climate change. Higher Education Press, Berlin and Beijing
Cheng GD, Zhao CY (2006) Study on ecological water demand in arid area of Northwestern China. Nat Sci Rev 21(11):1101–1106
Cheng GD, Li X, Zhao WZ, Xu Z, Feng Q, Xiao S, Xiao H (2014) Integrated study of the water–ecosystem–economy in the Heihe River Basin. Nat Sci Rev 1(3):413–428
Cutter SL (1996) Vulnerability to environmental hazards. Prog Hum Geogr 20:529–539
Deng XZ, Zhao CH (2015) Identification of water scarcity and providing solutions for adapting to climate changes in the Heihe River basin of China. Adv Meteorol 6-7:1–13
Falkenmark M (2013) The multiform water scarcity dimension. In: Lankford B, Bakker K, Zeitoun M, Conway D (eds) Water security: principles perspectives and practices, 1st edn. Routledge, Oxon
Farinotti D, Longuevergne L, Moholdt G, Duethmann D, Mölg T, Bolch T, Vorogushyn S, Güntner A (2015) Substantial glacier mass loss in the Tien Shan over the past 50 years. Nat Geosci 8:716–723
Fu BJ, Zhou GY, Bai YF et al (2009) The main terrestrial ecosystem services and ecological security in China. Adv Earth Sci 24(6):571–574 (in Chinese)
Fussel HM, Klein RJT (2006) Climate change vulnerability assessments: an evolution of conceptual thinking. Clim Chang 75:301–329
Gain AK, Giupponi C (2015) A dynamic assessment of water scarcity risk in the Lower Brahmaputra River Basin: an integrated approach. Ecol Indic 48:120–131
Gain AK, Giupponi C, Renaud FG (2012) Climate change adaptation and vulnerability assessment of water resources systems in developing countries: a generalized framework and a feasibility study in Bangladesh. Water 4:345–366
Gain AK, Mojtahed V, Biscaro C, Balbi S, Giupponi C (2015) An integrated approach of flood risk assessment in the eastern part of Dhaka City. Nat Hazards 79:1499–1530
Gao X, Zhang SQ, Ye BS, Gao HK (2011) Recent changes of glacier runoff in the Hexi inland river basin. Adv Water Sci 22(3):345–349 (in Chinese)
Gao Y, Feng Q, Li ZS et al (2014) Potential evaporation in the Taolaihe River basin during 1957-2012. J Desert Res 34(4):1125–1132 (in Chinese)
Giupponi C, Mojtahed V, Gain AK, Biscaro C, Balbi S (2015) Integrated risk assessment of water-related disasters. In: Shroder JF (ed) Hydro-meteorological hazards, risks and disasters. Elsevier, Boston, pp 163–200
Gleick PH (2015) On methods for assessing water-resource risks and vulnerabilities. Environ Res Lett 10:11003
Hagg W, Braun LN, Kuhn M, Nesgaard TI (2007) Modeling of hydrological response to climate change in glacierized Central Asian catchments. J Hydrol 332:40–53
Hamouda MA, Nour El-Din MM, Moursy FI (2009) Vulnerability Assessment of Water Resources Systems in the Eastern Nile Basin. Water Resour Manag 23:2697–2725
He C, DeMarchi C, Croley II et al (2009) Modeling the hydrology of the Heihe watershed in Northwestern China. J Glaciol Geocryol 31:420–421 (in Chinese)
Huai BJ, Li ZQ, Su MP et al (2014) RS analysis of glaciers change in the Heihe River Basin in the last 50 years. Acta Geograph Sin 69(3):366–369 (in Chinese)
Huss M, Hock G (2018) Global-scale hydrological response to future glacier mass loss. Nat Clim Chang 8:135–140
IPCC (2013) Summary for policymakers. In: Climate change 2013: the physical science basis. Contribution of Working Group I to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change [Stocker T.F. et al.]. Cambridge University Press, 2013
Jäger J, Bohunovsky L, Giljum S et al (2008) Our planet: how much more can earth take? Haus Publishing, London
Karthe D, Chalov S, Borchardt D (2015) Water resources and their management in Central Asia in the early 21st century: status, challenges and future prospects. Environ Earth Sci 73(2):487–499
Li H (2014) Water quality assessment and trend analysis in the Black River Basin. Master’s degree thesis in Lanzhou University of Technology. (in Chinese)
Li X, Lu L, Cheng GD, Xiao H (2001) Quantifying landscape structure of the Heihe River Basin, north-west China using FRAGSTATS. J Arid Environ 48:521–535
Liu JG, Yang W (2012) Water sustainability for China and beyond. Science 337:649–650
Martensa P, McEvoya D, Chang C (2009) The climate change challenge: linking vulnerability, adaptation, and mitigation. Curr Opin Environ Sustain 1(1):14–18
Mi LN, Xiao HL, Zhu WJ et al (2015) Dynamic variation of the groundwater level in the middle reaches of the Heihe River during 1985-2013. J Glaciol Geocryol 37(2):461–469 (in Chinese)
Nian Y, Li X, Zhou J, Hu XL (2014) Impact of land use change on water resource allocation in northwestern China. J Arid Land 6(3):273–286
Nian YY, Wang XL, Cai DH (2015) Analysis on climate and ecological environment change in the Ejin Delta, the lower reaches of the Heihe River. J Arid Meteorol 33(1):28–37 (in Chinese)
Nuttle WK, Fletcher PJ (2013) Integrated conceptual ecosystem model development for the Florida Keys/Dry Tortugas Coastal Marine Ecosystem. National Oceanic & Atmospheric Administration, Silver Springs, p 28
Odermatt S (2004) Evaluation of mountain case studies by means of sustainability variables: a DPSIR model as an evaluation tool in the context of the north-south discussion. Mt Res Dev 24:336–341
Padowski JC, Gorelick SM, Thompson BH, Rozelle S, Fendorf S (2015) Assessment of human–natural system characteristics influencing global fresh water supply vulnerability. Environ Res Lett 10:104014
Peng JJ, Liu Q, Wang LZ, Liu Q, Fan W, Lu M, Wen J (2015) Characterizing the pixel footprint of satellite albedo products derived from MODIS reflectance in the Heihe River Basin, China. Remote Sens 7:6886–6907
Rapport DJ, Singh A (2006) An eco-health based framework for status of environment reporting. Ecol Indic 6(2):409–428
Reynolds JF, Smith DMS, Lambin EF, Turner BL, Mortimore M, Batterbury SPJ, Downing TE, Dowlatabadi H, Fernandez RJ, Herrick JE, Huber-Sannwald E, Jiang H, Leemans R, Lynam T, Maestre FT, Ayarza M, Walker B (2007) Global desertification: building a science for dryland development. Science 316:847–851
Sadoff CW, Hall JW, Grey D et al (2015) Securing water, sustaining growth, report of the Global Water Partnership (GWP)/OECD Task Force on Water Security and Sustainable Growth. University of Oxford, Oxford
Simonovic SP (2009) Managing water resources: methods and tools for a systems approach. UNESCO and Earthscan, Paris and London
Statistical Bureau of Zhangye City (1980–2015) Statistical yearbook of Zhangye City. China Statistics Press, Beijing
Turner BL, Kasperson RE, Matson P et al (2003) A framework for vulnerability analysis in sustainability science. Proc Natl Acad Sci 100(14):8074–8079
Van Loon AF (2015) Hydrological drought explained. WIREs Water 2:359–392
Vicente-Serrano SM, Beguería S, López-Moreno JI (2010) A multiscalar drought index sensitive to global warming: the Standardized Precipitation Evapotranspiration Index. J Clim 23:1696–1718
Wang F, Niu J (2016) The implication of climate signal for precipitation in the Heihe River basin, Northwest China. Adv Meteorol 4:1–9. https://doi.org/10.1155/2016/1078617
Wang SJ, He YQ, Zhao CZ (2008) Optimized allocation and sustainable utilization of water resources in the inland river basin of northwest regions take Minqin County in Shi Yang River Basin as a case. Res Soil Water Conserv 15(5):22–29 (in Chinese)
Wang XJ, Zhang JY, Shahid S et al (2012) Water resources management strategy for adaptation to droughts in China. Mitig Adapt Strateg Glob Chang 17(8):923–937
Wang JD, Song CQ, Reager JT, Yao F, Famiglietti JS, Sheng Y, MacDonald GM, Brun F, Schmied HM, Marston RA, Wada Y (2018) Recent global decline in endorheic basin water storages. Nat Geosci 11:926–932
Wu F, Zhan J, Zhang Q, Sun Z, Wang Z (2014) Evaluating impacts of industrial transformation on water consumption in the Heihe river basin of Northwest China. Sustainability 6:8283–8296
Xie YW, Li LL, Zhao XJ, Yuan CX (2012) Temporal-spatial changes of the oasis in the Heihe River Basin over the past 25 years. In: Ghenai C (ed) Sustainable development-education, business and management-architecture and building construction-agriculture and food security. InTech, Rijeka, pp 313–340
Xu HJ, Yang TB, Chai SH (2014) Variation characteristics of the mountainous runoff and its driving forces in the upper reaches of the Taolaihe River during 1961-2010. J Desert Res 34(3):878–884 (in Chinese)
Ye BS, Ding YJ, Liu FJ et al (2003) Responses of various sized alpine glaciers and runoff to climate change. J Glaciol 49(164):1–7
Zhao XJ (2012) Study on the spatio-temporal characteristics of oasisization in the reaches of Heihe river basin from 1949 to 2009. Master’s degree thesis in Lanzhou University. (in Chinese)
Zhao Q, Huang WD (2015) Analysis and evaluation on effect of water integrated regulation and comprehensive river basin management of Heihe River. Yellow River 37(8):60–63 (in Chinese)
Ziad AM, Amjad A (2009) Intrinsic vulnerability, hazard and risk mapping for karst aquifers: a case study. J Hydrol 364(3–4):298–310
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The data used in this study can be requested from authors (xiaohanjin@126.com).
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This work was funded by class A strategic pilot science and technology special subtopics, the Chinese Academy of Sciences (XDA19070503).
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Wang, S., Wei, Y. Water resource system risk and adaptive management of the Chinese Heihe River Basin in Asian arid areas. Mitig Adapt Strateg Glob Change 24, 1271–1292 (2019). https://doi.org/10.1007/s11027-019-9839-y
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DOI: https://doi.org/10.1007/s11027-019-9839-y