Skip to main content Accessibility help

We use cookies to distinguish you from other users and to provide you with a better experience on our websites. Close this message to accept cookies or find out how to manage your cookie settings.

Close cookie message
×
Hostname: page-component-78c5997874-m6dg7 Total loading time: 0 Render date: 2024-11-03T02:34:38.735Z Has data issue: false hasContentIssue false

Part III - Engineered Rivers

Past, Present, and Future

Published online by Cambridge University Press:  16 September 2021

Edited by
Jurgen Schmandt  and
Aysegül Kibaroglu
Edited in association with
Regina Buono  and
Sephra Thomas
Jurgen Schmandt
Affiliation:
Houston Advanced Research Center
Aysegül Kibaroglu
Affiliation:
MEF University, Istanbul
Regina Buono
Affiliation:
University of Texas, Austin
Sephra Thomas
Affiliation:
University of Texas, Austin
Get access

Summary

A summary is not available for this content so a preview has been provided. Please use the Get access link above for information on how to access this content.
Image of the first page of this content. For PDF version, please use the ‘Save PDF’ preceeding this image.'
Type
Chapter
Information
Sustainability of Engineered Rivers In Arid Lands
Challenge and Response
 , pp. 77 - 232
Publisher: Cambridge University Press
Print publication year: 2021

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

References

Abtew, W. and Dessu, S. B. (2019). The Grand Ethiopian Renaissance Dam on the Blue Nile. Berlin: Springer International Publishing AG, p. 173.Google Scholar
Abu-Zeid, M. A., and El-Shibini, F. Z. (1997). Egypt’s High Aswan Dam. Water Resources Development, 13(2), pp. 209217.CrossRefGoogle Scholar
Adem, A., Tilahun, S. A., Ayana, E. K. et al. (2016). Climate Change Impact on Sediment Yield in the Upper Gilgel Abay Catchment, Blue Nile Basin, Ethiopia. In Abtew, W. and Melesse, A. M., eds., Landscape Dynamics, Soils and Hydrological Processes in Varied Climates. Berlin: Springer International Publishing, pp. 615642.CrossRefGoogle Scholar
African Development Bank (2000). Policy for Integrated Water Resources Management.Google Scholar
Ahmed, A. A. (2004). Sediment Transport and Watershed Management Component, Friend/Nile Project, Khartoum.Google Scholar
Amdihun, A., Gebremaria, E., Rebelo, L., and Zeleke, G. (2014). Modelling Soil Erosion Dynamics in the Blue Nile (Abbay) Basin: A Landscape Approach. Research Journal of Environmental Sciences, 8(5), pp. 243258. https://doi.org/10.3923/rjes.2014.243.258CrossRefGoogle Scholar
Appelgren, B., Klohn, W. W., and Alam, U. (2000). Water and Agriculture in the Nile Basin. Rome: FAO.Google Scholar
Ashour, M. A., Aly, T. E., and Abueleyon, H. M. (2019). Transboundary Water Resources “A Comparative Study”: The Lessons Learnt to Help Solve the Nile Basin Water Conflict. Limnological Review, 19(1), pp. 314. https://doi.org/10.2478/limre-2019-0001Google Scholar
Ashton, P. J. (2002). Avoiding Conflicts over Africa’s Resources. Royal Swedish Academy of Science, 31(3), pp. 236242.Google Scholar
Awulachew, S. B., Demissie, S. S., Ragas, F., Erkossa, T., and Peden, D. (2012). Water Management Intervention Analysis in the Nile Basin. IWMI.Google Scholar
Barnes, J. (2017). The Future of the Nile: Climate Change, Land Use, Infrastructure Management, and Treaty Negotiations in a Transboundary River Basin. WIREs Climate Change, 8(2). https://doi.org/10.1002/wcc.449Google Scholar
Basheer, M., Wheeler, K. G., Ribbe, L. et al. (2018). Quantifying and Evaluating the Impacts of Cooperation in Transboundary River Basins on the Water-Energy-Food Nexus: The Blue Nile Basin. Science of The Total Environment, 630(15), pp. 13091323.Google Scholar
Bastiaanssen, W., Karimi, P., Rebelo, L. et al. (2014). Earth Observation Based Assessment of the Water Production and Water Consumption of Nile Basin Agro-Ecosystems. Remote Sens, 6, pp. 1030610334. https://doi.org/10.3390/rs61110306Google Scholar
Betrie, G. D., Mohamed, Y. A., van Griensven, A., and Srinivasan, R. (2011). Sediment Management Modelling in the Blue Nile Basin Using SWAT Model. Hydrology and Earth System Sciences, 15, pp. 807818.Google Scholar
Blackmore, D. and Whittington, D. (2008). Opportunities for Cooperative Water Resources Development on the Eastern Nile: Risks and Rewards. Nile Basin Initiative (NBI).Google Scholar
Brooks, N. (2006). Cultural Responses to Aridity in the Middle Holocene and Increased Social Complexity. Quaternary International, 151, pp. 2949.Google Scholar
CCE News (2019). Ethiopia Brings in Chinese Firms to Accelerate Mega Dam Construction. Available at https://cceonlinenews.com/2019/02/21/ethiopia-brings-in-chinese-firms-to-accelerate-mega-dam-construction/Google Scholar
Coffel, E. D., Keith, B., Lesck, C. et al. (2019). Future Hot and Dry Years Worsen Nile Basin Water Scarcity Despite Projected Precipitation Increases. Earth’s Future, 7(8), pp. 967977. https://doi.org/10.1029/2019EF001247CrossRefGoogle Scholar
Connif, R. (2017). The Vanishing Nile: A Great River Faces a Multitude of Threats, Yale Environment 360. Available at www.e360.yale.edu/features/vanishing-nile-a-great-river-faces-a-multitude-of-threats-egypt-damGoogle Scholar
Degefu, D. M. and He, W. (2015). Water Bankruptcy in the Mighty Nile River Basin. Sustainable Water Resources Management, 2(1), pp. 2937.Google Scholar
Dessu, S. (2019). The Battle for the Nile with Egypt over Ethiopia’s Grand Renaissance Dam Has Just Begun, Quartz Africa. Available at www.qz.com/africa/1559821/ethiopias-grand-renaissance-dam-battles-egypt-sudan-on-the-nile/Google Scholar
Environmental Protection Council (EPA) (2010). Africa Review Report on Drought and Desertification.Google Scholar
ESRI (2019). GlobCover. Available at www.due.esrin.esa.int/page_globcover.phpGoogle Scholar
FAO (2005). Irrigation in Africa in Figures. AQUASTAT Survey 2005, Rome.Google Scholar
FAO (2011). Agricultural Water Use Projections in the Nile basin 2030: Comparison with the Food for Thought (F4T) Scenarios – Projections Reports.Google Scholar
FAO (2019a). AQUASTAT. Available at www.fao.org/nr/water/aquastat/data/query/index.html?lang=enGoogle Scholar
FAO (2019b). FAOSTAT. Available at www.fao.org/faostat/en/#data/QCGoogle Scholar
FAO (2020). WorldClim. Available at www.worldclim.org/version2Google Scholar
Fick, S. E. and Hijmans, R. J. (2017). Worldclim 2: New 1-km Spatial Resolution Climate Surfaces for Global Land Areas. International Journal of Climatology, 37(12), pp. 43024315. https://doi.org/10.1002/joc.5086Google Scholar
GADM (2018). GADM Database. Available at www.gadm.org/index.htmlGoogle Scholar
Gebremicael, T. G., Mohamed, Y. A., Betrie, G. D. et al. (2013). Trend Analysis of Runoff and Sediment Fluxes in the Upper Blue Nile Basin: A Combined Analysis of Statistical Tests, Physically Based Models, and Land Use Maps. Journal of Hydrology, 482, pp. 5768. https://doi.org/10.1016/j.jhydrol.2012.12.023Google Scholar
Heinz, S. (1983). Sadd el-Ali, der Hochdamm von Assuan (Sadd el-Ali, the High Dam of Aswan). Geowissenschaften in Unserer Zeit (in German), 1(2), pp. 5185.Google Scholar
IEA (2015). Energy Atlas. Available at www.energyatlas.iea.org/#!/tellmap/-1118783123/0Google Scholar
Kaluarachchi, J. J. and Kim, U. (2009). Climate Change Impacts on Water Resources in the Upper Blue Nile River Basin, Ethiopia. Journal of the American Water Resources Association, 45(6), pp. 13611378.Google Scholar
Kaluarachchi, J. J., Kim, U., and Smakhtin, V. U. (2008). Climate Change Impacts on Hydrology and Water Resources of the Upper Blue Nile River Basin, Ethiopia. Colombo: International Water Management Institute, p. 27.Google Scholar
Keith, B., Enos, J., Cadets, G. B. et al. (2013). Limits to Population Growth and Water Resource Adequacy in the Nile River Basin, 1994–2100. In Proceedings of the 31st International Conference of the System Dynamics Society, Cambridge.Google Scholar
Kimenyi, M. S. and Mbaku, J. M. (2015). The Limits of the New “Nile Agreement.” Available at www.brookings.edu/blog/africa-in-focus/2015/04/28/the-limits-of-the-new-nile-agreement/Google Scholar
Kumagai, J. (2016). The Grand Ethiopian Renaissance Dam Gets Set to Open, IEEE Spectrum. Available at https://spectrum.ieee.org/energy/policy/the-grand-ethiopian-renaissance-dam-gets-set-to-openGoogle Scholar
Lazarus, S. (2018). Is Ethiopia Taking Control of the River Nile? CNN. Available at www.cnn.com/2018/10/19/africa/ethiopia-new-dam-threatens-egypts-water/index.htmlGoogle Scholar
Li, R. (2005). Transboundary Water Conflicts in the Nile Basin. Water Encyclopedia. https://doi.org/10.1002/047147844X.wr152Google Scholar
Mark, J. (2014). Nile. Ancient History Encyclopedia.Google Scholar
McCartney, M. P., Alemayehu, T., Easton, Z. M. et al. (2012). Simulating Current and Future Water Resources Development in the Blue Nile River Basin. In Awulachew, S. B., Smakhtin, V., Molden, D., and Peden, D., eds., The Nile River Basin: Water, Agriculture, Governance and Livelihoods, pp. 269291. Abingdon: Routledge – Earthscan.Google Scholar
Multsch, S., Elshamy, M. E., Batarseh, S. et al. (2017). Improving Irrigation Efficiency Will Be Insufficient to Meet Future Water Demand in the Nile Basin. Journal of Hydrology: Regional Studies, 12, pp. 315330.Google Scholar
Nile Basin Initiative (NBI) (2012). State of the River Nile Basin Report.Google Scholar
Oestigaard, T. (2012). Water Scarcity and Food Security along the Nile: Politics, Population Increase and Climate Change. Current African Issues, 49, Uppsala: Nordiska Afrikainstitutet, Uppsala.Google Scholar
Onencan, A., Enserink, B., Van de Walle, B., and Chelang, J. (2016). Coupling Nile Basin 2050 Scenarios with the IPCC 2100 Projections for Climate-Induced Risk Reduction. Procedia Engineering, 159, pp. 357365.Google Scholar
Rahman, M. (2012). Water Security: Ethiopia–Egypt Transboundary Challenges over the Nile River Basin. Journal of Asian and African Studies, 48(1), pp. 3546. https://doi.org/10.1177/0021909612438517Google Scholar
Rullia, M. C., Savioria, A., and D’Odorico, P. (2013). Global Land and Water Grabbing. Proceedings of the National Academy of Sciences of the United States of America (PNAS), 110(3), pp. 892897. https://doi.org/10.1073/pnas.1213163110CrossRefGoogle Scholar
Salman, M. A. S. (2013). The Nile Basin Cooperative Framework Agreement: A Peacefully Unfolding African Spring? Water International, 38(1), pp. 1729. https://doi.org/10.1080/02508060.2013.744273CrossRefGoogle Scholar
Setegn, S. G., Rayner, D., Melesse, A. M. et al. (2011). Climate Change Impact on Agricultural Water Resources Variability in the Northern Highlands of Ethiopia. In Melesse, A. M., ed., Nile River Basin. Dordrecht: Springer.Google Scholar
Shahin, M. (1993). An Overview of Reservoir Sedimentation in Some African River Basins. In Proceedings of Sediment Problems: Strategies for Monitoring, Prediction and Control. Yokohama: LAHS Publications, pp. 93100.Google Scholar
Sutcliffe, J. V. and Parks, Y. P. (1999). The Hydrology of the Nile. Oxfordshire: The International Association of Hydrological Science (IAHS).Google Scholar
United Nations, Department of Economic and Social Affairs, Population Division (DESA) (2019). World Population Prospects 2019, Online Edition. Rev. 1. Available at www.population.un.org/wpp/Download/Standard/Population/Google Scholar
United Nations Economic and Social Council. (2007) Africa Review Report on Drought and Desertification. Available at www.un.org/esa/sustdev/csd/csd16/rim/eca_bg3.pdfGoogle Scholar
Wheeler, K. G., Basheer, M., Mekonnen, Z. et al. (2016). Cooperative Filling Approaches for the Grand Ethiopian Renaissance Dam. Water International, 41(4), pp. 611634. https://doi.org/10.1080/02508060.2016.1177698Google Scholar
Williams, M. A. J. (2009). Human Impact on the Nile Basin: Past, Present, Future. In Dumont, H. J., ed., The Nile. Dordrecht: Springer.Google Scholar
World Bank (2019). World Bank Data. Available at www.data.worldbank.org/indicatorGoogle Scholar
Worqlul, A. W., Dile, Y. T., Ayana, E. K. et al. (2018). Impact of Climate Change on Streamflow Hydrology in Headwater Catchments of the Upper Blue Nile Basin, Ethiopia. Water, 10, p. 120. https://doi.org/0.3390/w10020120Google Scholar
Yihdego, Y., Khalil, A., and Salem, H. S. (2017). Nile River’s Basin Dispute: Perspectives of the Grand Ethiopian Renaissance Dam (GERD). Global Journal of Environmental Science and Management, 17(2), pp. 121.Google Scholar
Yletyinen, J. (2009). Holocene Climate Variability and Cultural Changes at River Nile and Its Saharan Surroundings. Stockholm: Stockholm University, Department of Natural Geography. Available at www.diva-portal.org/smash/get/diva2:400169/FULLTEXT01.pdfGoogle Scholar
Yoffe, S. (2002). Basins at Risk: Conflict and Cooperation over International Freshwater Resources. Ph.D. Dissertation, Oregon State University, Corvallis. p. 79.Google Scholar

References

Allan, J. A. (1990). Agricultural Sector in Iraq. London: University of London.Google Scholar
Altinbilek, D. H. (2004). Development and Management of the Euphrates–Tigris Basin. International Journal of Water Resources Development, 20(1), pp. 1533.Google Scholar
Anderson, E. W. (1986). Water Geopolitics in the Middle East: Key Countries. Conference on US Foreign Policy on Water Resources in the Middle East: Instrument for Peace and Development, Washington, DC: CSIS.Google Scholar
Bakour, Y. (1992). Planning and Management of Water Resources in Syria. In Le Moigne, G., Barghouti, S., Feder, G., Garbus, L., and Xie, M., eds., Country Experiences with Water Resources Management, Economic, Institutional, Technological, and Environmental Issues. Washington, DC: World Bank, pp. 151155.Google Scholar
Beaumont, P. (1992). Water: A Resource under Pressure. In Nonneman, G., ed., The Middle East and Europe: An Integrated Communities Approach. London: Federal Trust for Education and Research, pp. 183188.Google Scholar
Belül, M. L. (1996). Hydropolitics of the Euphrates–Tigris Basin. Unpublished master’s thesis. Ankara: Middle East Technical University.Google Scholar
Bilen, O. (1994). Prospects for Technical Cooperation in the Euphrates–Tigris Basin. In Biswas, A. K., ed., International Waters of the Middle East: From Euphrates–Tigris to Nile. Oxford: Oxford University Press, pp. 95116.Google Scholar
Bozkurt, D. and Sen, O. L. (2013). Climate Change Impacts in the Euphrates–Tigris Basin Based on Different Model and Scenario Simulations. Journal of Hydrology, 480, pp. 149161. https://doi.org/10.1016/j.jhydrol.2012.12.02Google Scholar
Central Bureau of Statistics in the Syrian Arab Republic. (2005). General Census, Population in the Areas and Suburbs 2004. http://cbssyr.org/General%20census/census%202004/pop-man.pdfGoogle Scholar
Central Organization for Statistics in Iraq. (2010). Annual Abstract for Statistics 2008–2009. www.iraqcosit.org/english/section_2.phpGoogle Scholar
Christen, E. W. and Saliem, K. A. (eds.) (2012). Managing Salinity in Iraq’s Agriculture: Current State, Causes and Impacts, Iraq Salinity Assessment: Report 1.Google Scholar
Cullmann, J. (2013). Hydrology. In Kibaroglu, A., Kirschner, A., Mehring, S., and Wolfrum, R., eds., Water Law and Cooperation in the Euphrates–Tigris Region. Leiden: Brill, pp. 183189.Google Scholar
FAO (2008). Water Reports 34, Irrigation in the Middle East Region in Figures, Aquastat Survey.Google Scholar
GAP Administration. (2019). Available at www.gap.gov.tr/gap-ta-son-durum-sayfa-32.htmlGoogle Scholar
Gurun, K. (1994). Akintiya Kürek Cekmek: Bir Büyükelcinin Aniları [Akintiya Rowing: Memories of an Ambassador]. Istanbul: Milliyet Yayinlari.Google Scholar
Harris, L. and Alatout, S. (2010). Negotiating Scales, Forging States: Comparison of the Upper Tigris/Euphrates and Jordan River Basins. Political Geography, 29(3), pp. 148156. https://doi.org/10.1016/j.polgeo.2010.02.01Google Scholar
Hashim, A. S. (2014). The Islamic State: From al-Qaeda Affiliate to Caliphate. Middle East Policy, 21(4), pp. 6983. https://doi.org/10.1111/mepo.12096Google Scholar
Institute in Turkstat (Statistical Turkey) (2010). Population Statistics. www.turkstat.gov.tr/VeriBilgi.do?tb_id=39&ust_id=11Google Scholar
Kavvas, M. L., Chen, Z. Q., Anderson, M. L. et al. (2011). A Study of Waterbalances over the Tigris–Euphrates Watershed. Physics and Chemistry of the Earth, Parts A/B/C, 36(5–6), pp. 197203.Google Scholar
Kibaroglu, A. (2002). Building a Regime for the Waters of the Euphrates–Tigris River Basin. London and The Hague: Kluwer Academic Publishers.Google Scholar
Kibaroglu, A. (2014). An Analysis of Turkey’s Water Diplomacy and Its Evolving Position Vis-à-vis International Water Law. Water International, 40(1), pp. 153167. https://doi.org/10.1080/02508060.2014.978971Google Scholar
Kibaroglu, A. and Gursoy, S. I. (2015). Water–Energy–Food Nexus in a Transboundary Context: The Euphrates–Tigris River Basin as a Case Study. Water International, 40(5–6), pp. 824838. https://doi.org/10.1080/02508060.2015.1078577Google Scholar
Kibaroglu, A. and Scheumann, W. (2013). Evolution of Transboundary Politics in the Euphrates–Tigris River System: New Perspectives and Political Challenges. Global Governance, 19, pp. 279307. https://doi.org/10.5555/1075– 2846-19.2.279Google Scholar
Kibaroglu, A. and Unver, I. O. (2000). An Institutional Framework for Facilitating Cooperation. International Negotiation, 5(2), pp. 311330. https://doi.org/10.1163/15718060020848785Google Scholar
Kibaroglu, A., Klaphake, A., Kramer, A., Scheumann, W., and Carius, A. (2005). Cooperation on Turkey’s Transboundary Waters. Research report, German Federal Ministry for Environment, Nature Conservation and Nuclear Safety, Berlin.Google Scholar
Kirschner, A. and Tiroch, K. (2012). The Waters of the Euphrates and Tigris: An International Law Perspective. In von Bogdandy, A. and Wolfrum, R., eds., Max Planck UNYB 16. Leiden: Martinus Nijhoff Publishers, pp. 329394.Google Scholar
Kliot, N. (1994). Water Resources and Conflict in the Middle East. New York: Taylor & Francis.Google Scholar
Kolars, J. F. (1994). Problems of International River Management: The Case of the Euphrates. In Biswas, A. K., ed., International Waters of the Middle East: From Euphrates–Tigris to Nile. Oxford: Oxford University Press, pp. 4494.Google Scholar
Kolars, J. F. and Mitchell, W. A. (1991). The Euphrates River and the Southeast Anatolia Development Project. Carbondale: Southern Illinois University Press.Google Scholar
Law No. 14 of 1990, Ratifying the Joint Minutes Concerning the Provisional Division of the Waters of the Euphrates River. Available at www.informea.org/en/legislation/law-no-14-1990-ratifyingjoint-minutes-concerning-provisional-division-waters-euphratesGoogle Scholar
McLachlan, K. (1991). The South-East Anatolia Project (GAP) and Its Effect on Water Supply and Management in Iraq. London: University of London.Google Scholar
Meliczek, H. (1987). Land Settlement in the Euphrates Basin of Syria: In Land Reform: Land Settlement and Cooperatives. Rome: Food and Agriculture Organization Publications.Google Scholar
Memorandum of Understanding between the Ministry of the Environment and Forestry of the Republic of Turkey and the Ministry of Water Resources of the Republic of Iraq on Water. (2009a). On file with the author.Google Scholar
Memorandum of Understanding between the Government of the Republic of Turkey and the Government of the Syrian Arab Republic for the Construction of a Joint Dam on the Orontes River under the Name ‘Friendship Dam’. (2009b). On file with the author.Google Scholar
Memorandum of Understanding between the Government of the Republic of Turkey and the Government of the Syrian Arab Republic in the Field of Efficient Utilization of Water Resources and Coping with Drought; Memorandum of Understanding between the Government of the Republic of Turkey and the Government of the Syrian Arab Republic in the Field of Remediation of Water Quality. (2009c). On file with the author.Google Scholar
Naff, T. and Matson, R. C. (1984). Water in the Middle East: Conflict or Cooperation? Boulder, CO: Westview Press.Google Scholar
Nippon, K. and Yuksel, P. (1989). Vols. I–IV, Southeastern Anatolia Project Master Plan Study. Tokyo and Ankara: State Planning Organization.Google Scholar
Richards, A. and Waterbury, J. (1990). A Political Economy of the Middle East. Boulder, CO: Westview.Google Scholar
Sayan, R. C. and Kibaroglu, A. (2016). Understanding Water–Society Nexus: Insights from Turkey’s Small-Scale Hydropower Policy. Water Policy, 18(5), pp. 12861301. https://doi.org/10.2166/wp.2016.235Google Scholar
Scheumann, W. (1998). Conflicts on the Euphrates: An Analysis of Water and Non-water Issues. In Scheumann, W. and Schiffler, M., eds., Water in the Middle East. Berlin: Springer, pp. 3145.Google Scholar
Sen, O. L., Unal, A., Bozkurt, D., and Kindap, T. (2011). Temporal Changes in Euphrates and Tigris Discharges and Teleconnections. Environmental Research Letters, 6 (024012). https://doi.org/10.1088/1748-9326/6/2/024012Google Scholar
Tice, V. L. (2016). Water Management and Water Challenges in Iraq. Available at https://water.fanack.com/iraq/water-management-and-water-challenges-in-iraq/Google Scholar
Tigrek, S. and Kibaroglu, A. (2011). Strategic Role of Water Resources for Turkey. In Kibaroglu, A., Scheumann, W., and Kramer, Annika, eds., Turkey’s Water Policy. New York: Springer Verlag, pp. 2742.Google Scholar
Trondalen, J. M. (2008). Water and Peace for the People: Proposed Solutions to Water Disputes in the Middle East. Paris: UNESCO International Hydrological Programme (IHP).Google Scholar
Turkish Ministry of Foreign Affairs (1996). Water Issues between Turkey, Syria, and Iraq. Perceptions: Journal of International Affairs. Retrieved from http://sam.gov.tr/wp-content/uploads/2012/01/WATER-ISSUES-BETWEEN-TURKEY-SYRIA-AND-IRAQ.pdfGoogle Scholar
UN-ESCWA and BGR (2013). Inventory of Shared Water Resources in Western Asia. Beirut: ESCWA. Available at: https://waterinventory.org/Google Scholar
Unver, I. H. O. (1997). Southeastern Anatolia Project (GAP). International Journal of Water Resources Development, 13(4), pp. 453484. https://doi.org/10.1080/07900629749575Google Scholar
Vishwanath, A. (2015). The Water Wars Waged by the Islamic State. Available at www.stratfor.com/weekly/water-wars-waged-islamic-stateGoogle Scholar
Von Lossow, T. (2016). Water as Weapon: IS on the Euphrates and Tigris. German Institute for International and Security Affairs. Available at www.swp-berlin.org/fileadmin/contents/products/comments/2016C03_lsw.pdfGoogle Scholar
Wakil, M. (1993). Analysis of Future Water Needs for Different Sectors in Syria. Water International, 18(1), pp. 1822. https://doi.org/10.1080/02508069308686144Google Scholar
Waslekar, S. (2017). Wars Will Not Be Fought over Water: Our Thirst Could Pave the Way to Peace. Available at www.theguardian.com/global-development-professionals-network/2017/jan/19/water-wars-infrastructure-isis-peaceGoogle Scholar
World Bank (2001). Syrian Arab Republic Irrigation Sector Report. Report No. 22602-SYR. Washington, DC: Rural Development Department, Water, and Environment Group, World Bank.Google Scholar
Yucel, I., Guventurk, A., and Sen, O. L. (2014). Climate Change Impacts of Snowmelt Runoff for Mountainous Transboundary Basins in Eastern Turkey. International Journal of Climatology, 35(2), pp. 215228.Google Scholar

References

Ball, P. (2016). The Water Kingdom: A Secret History of China. Chicago: The University of Chicago Press, pp. 6067.Google Scholar
Branigan, T. (2008). One-third of China’s Yellow river “Unfit for Drinking or Agriculture,” The Guardian. Available at www.theguardian.com/environment/2008/nov/25/Google Scholar
Chen, A., Wu, M., Wu, S. et al. (2019). Bridging Gaps between Environmental Flows Theory and Practices in China. Water Science and Engineering, 12(4), pp. 284292.Google Scholar
Chen, D., Luo, Z., Webber, M. et al. (2020). Between Project and Region: The Challenges of Managing Water in Shandong Province after the South–North Water Transfer Project. Water Alternatives, 13, pp. 4969.Google Scholar
Chen, J., He, D., and Cui, S. (2003) The Response of River Water Quality and Quantity to the Development of Irrigation Agriculture in the Last 4 Decades in the Yellow River Basin, China. Water Resources Research, 39, p. 1047. https://doi.org/10.1029/2001WR001234Google Scholar
Chen, Z. (1989). Flood Forecasting and Flood Warning System in the Lower Yellow River. In Brush, L. M., Wolman, M. G., and Bing-Wei, H., eds., Taming the Yellow River: Silt and Floods. Dordrecht: Springer, pp. 425449.Google Scholar
China Water Risk (2012). 2011 State of Environment Report Review. Available at www.chinawaterrisk.org/resources/analysis-reviews/2011-state-of-environment-report-reviewGoogle Scholar
China Water Risk (2017) 2016 State of Environment Report Review. Available at www.chinawaterrisk.org/resources/analysis-reviews/2016-state-of-environment-report-reviewGoogle Scholar
Dai, L. (2015). A New Perspective on Water Governance in China: Captain of the River. Water International, 49, pp. 8799.Google Scholar
Dodgen, R. A. (2001). Controlling the Dragon: Confucian Engineers and the Yellow River in Late Imperial China. Honolulu: University of Hawaii Press.Google Scholar
Dong, Z. (2020) Greening the Yellow River for a Beautiful China. China Water Risk. Available at www.chinawaterrisk.org/opinions/greening-the-yellow-river-for-a-beautiful-chinaGoogle Scholar
Fu, G. and Chen, S. (2006). Water Crisis in the Yellow River: Facts, Reasons, Impacts and Countermeasures. Water Practice & Technology, 1. https://doi.org/wpt2006028Google Scholar
Gippel, C. J., Jiang, X., Fu, X. et al. (2012). Assessment of River Health in the Lower Yellow River. Brisbane: International Water Centre.Google Scholar
Greer, C. (1979). Water Management in the Yellow River Basin of China. Austin and London: University of Texas Press.Google Scholar
Han, J., Onishi, A., Shirakawa, H., and Imura, H. (2006). An Analysis of Population Migration and Its Environmental Implications in China: Application to Domestic Water Use. Environmental Systems Research, 34, pp. 515523.Google Scholar
Jia, S. (1995). Calculating Natural Erosion and Accelerated Erosion on the Loess Plain Based on Vegetative Cover: The Case of Anzhai County. Water and Soil Conservation Bulletin, 4, pp. 2532.Google Scholar
Jia, S. and Liang, Y. (2020). Suggestions for Strategic Allocation of Yellow River Water Resources under the New Situation. Resources Science, 42, pp. 2936.Google Scholar
Jia, S. et al. (2019a). New Technologies, Strategies, Policies, and Institutions. International Specialty Conference on Water Security. Beijing.Google Scholar
Jia, S. (2019b). A Portfolio of China’s Urban Water Governance Sector: Administrative System, Coordination Problems and Policy Evolution. International Journal of Water Resources Development. https://doi.org/10.1080/07900627.20191668754Google Scholar
Jiang, X., Arthington, A., and Liu, C. (2010). Environmental Flow Requirements of Fish in the Lower Reach of the Yellow River. Water International, 35, pp. 381396.Google Scholar
Klein, J. (2017). A New Formula to Help Tame China’s Yellow River. The New York Times. Available at www.nytimes.com/2017/06/02/science/china-yellow-river-xiaolangdi-dam.htmlGoogle Scholar
Kong, D., Miao, C., Borthwick, A. G. L. et al. (2014). Evolution of the Yellow River Delta and Its Relationship with Runoff and Sediment Load from 1983 to 2011. Journal of Hydrology, 520, pp. 157167.Google Scholar
Leonard, J. K. (1996). Controlling from Afar: The Daoguang Emperor’s Management of the Grand Canal Crisis, 1824–1826. Ann Arbor: University of Michigan Center for Chinese Studies. Michigan Monographs in Chinese Studies, Vol. 69.Google Scholar
Liu, J., Cao, L., Liu, J., Wang, J., and Liu, Y. (2013). Sedimentation and Water Use in the Yellow River. In Wang, J., Zhao, J., Li, H., Zhao, Y., Peng, S., and Sang, X., eds., South–North Water Transfer, and the Comprehensive Arrangement of Water Resources. Beijing: Kexue Chubanshe, pp. 229251.Google Scholar
Liu, X. et al. (2016). Why Water and Silt Drastically Declined in the Yellow River in Recent Years. Beijing: Kexue Chubanshe.Google Scholar
Ministry of Water Resources (2016). 2016 Statistic Bulletin on China Water Activities. Yellow River Commission Bulletins, China. Available at www.mwr.gov.cn/english/publs/201806/P020180601369706877305.pdfGoogle Scholar
Ministry of Water Resources (2018). 2018 Statistic Bulletin on China Water Activities. Yellow River Commission Bulletins, China. Available at www.mwr.gov.cn/english/publs/202001/P020200102601837201385.pdfGoogle Scholar
Moore, S. M. (2018) Subnational Hydropolitics. New York: Oxford University Press.Google Scholar
Nickum, J. E. (2004). Water and Regional Development in the Yellow River Basin. In Tortajada, C., Unver, O., and Biswas, A. K., eds., Water and Regional Development. Oxford: Oxford University Press, pp. 114136.Google Scholar
Nickum, J. E. and Greenstadt, D. (1998). Transacting a Commons: The Lake Biwa Comprehensive Development Plan, Shiga Prefecture, Japan. In Donahue, J. M. and Johnston, B. R., eds., Water, Culture, & Power. Washington, DC and Covelo, CA: Island Press, pp. 141161.Google Scholar
Nickum, J. E., Jia, S., and Moore, S. (2017). Red Lines and China’s Water Resources Policy in the Twenty-first Century. In Sternfeld, E., ed., Routledge Handbook on China’s Environmental Policy. London: Routledge Earthscan, pp. 7182.Google Scholar
Ottinger, M., Kuenzer, C., Liu, G., Wang, S., and Dech, S. (2013). Monitoring Land Cover Dynamics in the Yellow River Delta from 1995 to 2010 Based on Landsat 5 TM. Applied Geography, 44, pp. 5368.Google Scholar
Peng, S., Wang, H., and Zhang, X. (2011). Development of Energy Resources and Heavy Chemical Industry Bases in the Upper and Middle Reaches of the Yellow River and a Strategy for Water Resources Regulation. Zhongguo Shuili [China Water Resources], 21, pp. 2831.Google Scholar
Pietz, D. A. (2015). The Yellow River: The Problem of Water in Modern China. Cambridge, MA, and London: Harvard University Press.Google Scholar
Ren, C., Wang, Z., Zhang, B. et al. (2018). Remote Monitoring of Expansion of Aquaculture Ponds along Coastal Region of the Yellow River Delta from 1983 to 2015. China Geographical Science, 28, pp. 430442.Google Scholar
Ringler, C., Cai, X., Wang, J. et al. (2010) Yellow River Basin: Living with Scarcity. Water International, 35, pp. 681701.Google Scholar
Rogers, P. (1996). America’s Water. Cambridge, MA, and London: The MIT Press.Google Scholar
Seeger, M. (2014). Zähmung der Flüsse: Staudämme und das Streben nach produktiven Landschaften in China [Taming of the Rivers: Dams and the Striving for Productive Landscapes in China]. Berlin: LIT Verlag.Google Scholar
Shen, D. (2009) River Basin Water Resources Management in China: A Legal and Institutional Assessment. Water International, 34, pp. 484496.Google Scholar
Svensson, J., Garrick, D. E., and Jia, S. (2019). Water Markets as Coupled Infrastructure Systems: Comparing the Development of Water Rights and Water Markets in Heihe, Shiyang and Yellow Rivers. Water International, 44, pp. 834853.Google Scholar
Tan, D. (2013). Water for Coal: Thirsty Miners? China Water Risk. Available at www.chinawaterrisk.org/resources/analysis-reviews/water-for-coal-thirsty-miners-feel-the-pain/Google Scholar
Tan, D., Hu, F., and Lazareva, I. (2014). 8 Facts on China’s Wastewater. China Water Risk. Available at www.chinawaterrisk.org/resources/analysis-reviews/8-facts-on-china-wastewater/Google Scholar
United Nations, Department of Economic and Social Affairs, Population Division (2017). World Population Prospects: The 2017 Revision, DVD Edition. New York: United Nations.Google Scholar
UNESCO Representative Office in China (2011). Climate Change Impacts and Adaptation Strategies in the Yellow River Basin. Beijing: Popular Science Press.Google Scholar
Wang, D. (2018). Water Pollution Control and Policy in the Yellow River Basin. Democracy and Science, 175(6), pp. 2627.Google Scholar
Wang, H., Yang, Z., Saito, Y., Liu, J. P., and Sun, X. (2006) Interannual and Seasonal Variation of the Huanghe (Yellow River) Water Discharge over the Past 50 years: Connection to Impacts from ENSO Events and Dams. Global and Planetary Change, 50, pp. 212225.Google Scholar
Wang, J., Zhao, J., Li, H. et al. (2013). Studies on Integrated Water Resources Allocation of the South–North Water Transfer. Beijing: Science Press.Google Scholar
Wang, S., Fu, B., Piao, S. et al. (2016). Reduced Sediment Transport in the Yellow River Due to Anthropogenic Changes. Nature Geosciences, 9, pp. 3842.Google Scholar
Wang, Y. (2003) Water Dispute in the Yellow River Basin: Challenges to a Centralized System. Woodrow Wilson Center China Environment Series, 6, pp. 9498.Google Scholar
Wang, Y., Ding, Y., Ye, B. et al. (2013). Contributions of Climate and Human Activities to Changes in Runoff of the Yellow and Yangtze Rivers from 1950 to 2008. Science China Earth Sciences, 56(8), pp. 13981412.Google Scholar
Wang, Y., Peng, S., Jiang, G., and Fang, H. (2018). Thirty Years of the Yellow River Water Allocation Scheme and Future Prospects. MATEC Web of Conferences 2018. https://doi.org/10.1051/matecconf/201824601083Google Scholar
Wang, Y., Zhao, W., Wang, S., Feng, X., and Liu, Y. (2019). Yellow River Water Rebalanced by Human Regulation. Nature Scientific Reports, 9, p. 9707. https://doi.org/10.10388/s41598-019-46063-5Google Scholar
Watts, J. (2011). Provincial Tug-of-War Waters down China’s Yellow River Success Story, The Guardian. Available at www.theguardian.com/environment/2011/jun/28/water-yellow-river-chinaGoogle Scholar
Xia, J., Bing, Q., and Li, Y. (2012). Water Resources Vulnerability and Adaptive Management in the Huang, Huai, and Hai River Basins of China. Water International, 37(5), pp. 523536. https://doi.org/10.1080/02508060.2012.724649Google Scholar
Xiang, X., Svensson, J., and Jia, S. (2017). Will the Energy Industry Drain the Water Used for Agricultural Irrigation in the Yellow River Basin? International Journal of Water Resources Development, 33, pp. 6980.Google Scholar
Xie, J. X., Tang, W. J., and Yang, Y. H. (2018). Fish Assemblage Changes over Half a Century in the Yellow River, China. Ecology and Evolution, 8, pp. 41734182. https://doi.org/10.1002/ece3.3890Google Scholar
Xu, Y. (2017) China’s River Chiefs: Who Are They? China Water Risk. Available at www.chinawaterrisk.org/resources/analysis-reviews/chinas-river-chiefs-who -are-theyGoogle Scholar
Xu, Y. and Chan, W. (2018). Ministry Reform: 9 Dragons to 2, China Water Risk. Available at www.chinawaterrisk.org/resources/analysis-reviews/ministry -reform-9-dragons-to-2Google Scholar
Yang, H. and Jia, S. (2008). Meeting the Basin Closure of the Yellow River in China. International Journal of Water Resources Development, 24, pp. 265274.Google Scholar
Yellow Basin Project Team (2010). Yellow River Basin: Living with Scarcity. Synthesis Report submitted to the Challenge Program on Water and Food (CPWF). Washington, DC: International Food Policy Research Institute & Partner Organizations.Google Scholar
Yellow River Conservancy Commission (YRCC) (2013). The Yellow River Basin General Plan (2012–2030). Zhengzhou: Yellow River Water Press.Google Scholar
Yu, L. (2006). The Huanghe (Yellow) River: Recent Changes and Its Countermeasures. Continental Shelf Research, 26, pp. 22812298.Google Scholar
Zhang, H., Yang, L., and Zhang, X. (2013). An Analysis of Indicators of Socioeconomic Development in the Yellow River Basin. People’s Yellow River, 10, pp. 1517.Google Scholar
Zhang, L. (2012). The Practice of Water Rights Reform in Northern China. In Jia, S., Zhang, L., Cao, Y., Yan, H., Li, J., and Nickum, J., eds., When Water Rights Are Implemented in China: The Case of Gollmud. Beijing: Shuili shuidian chubanshe, pp. 4362.Google Scholar
Zhang, L. (2016). The River, the Plain, and the State. Cambridge: Cambridge University Press.Google Scholar
Zhang, P., Bo, P., Li, Y. et al. (2019). Analyzing Spatial Disparities of Economic Development of Yellow River Basin, China. GeoJournal, 84, pp. 303320. https://doi.org/10.1007/210708-018-9860-9Google Scholar
Zhonghuarenmingongheguo shuilibu shuiwensi [Hydrology Section of the Ministry of Water Resources, People’s Republic of China] (1997). Zhongguo shui ziyuan zhiliang pingjia tuji [Maps of China’s Water Resources Quality Assessment]. Zhengzhou: Yellow River Water Press.Google Scholar
Zhou, X., Yang, Y., Sheng, Z., and Zhang, Y. (2019). Reconstructed Natural Runoff Helps to Quantify the Relationship between Upstream Water Use and Downstream Water Scarcity in China’s River Basins. Hydrology and Earth System Sciences, 23, pp. 115. https://doi.org/10.5194/hess-23-1-2019Google Scholar
Zhuang, C., Xu, J., and Chen, G. (2015). Sustainable Management of Water Resources in the Yellow River Basin: The Main Issues and Legal Approaches. WIT Transactions on Ecology and the Environment, 197, pp. 1523. https://doi.org/10.2495/RM150021Google Scholar

References

Australian Bureau of Statistics (ABS) (2015). Gross State Product. Statement for Year Ending June 30, 2014. 52220.0 Australian National Accounts: State Accounts, 2014/15.Google Scholar
Bruntland, G. (ed.) (1987). Our Common Future: The World Commission on Environment and Development. Oxford: Oxford University Press.Google Scholar
Commonwealth Environmental Water Office (2019). Available at www.environment.gov.au/water/cewoGoogle Scholar
Commonwealth of Australia (2009). Water Act 2007. Canberra: Commonwealth Parliament.Google Scholar
Connell, D. (2007). Water Politics in the Murray–Darling Basin. Sydney: Federation Press.Google Scholar
Council of Australian Governments (COAG) (2003). Intergovernmental Agreement on Addressing Water Over-allocation and Achieving Environmental Objectives in the Murray–Darling Basin.Google Scholar
Council of Australian Governments (COAG) (2004). Intergovernmental Agreement on a National Water Initiative. Attachment A: A Water Resource Policy (1994).Google Scholar
CSIRO (2015). Murray Basin Cluster Report: Projections for Australia’s NRM Regions. Canberra: Australian Government.Google Scholar
Davies, A. et al. (2018). Murray–Darling: When the River Runs Dry. The Guardian. Available at www.theguardian.com/environment/ng-interactive/2018/apr/05/murray-darling-when-the-river-runs-dryGoogle Scholar
Dole, D. (2002). Managers for All Seasons. In Connell, D., ed., Uncharted Waters. Canberra: Murray–Darling Basin Commission.Google Scholar
Dovers, S. R. and Lindenmayer, D. B. (1997). Managing the Environment: Rhetoric, Policy, and Reality. Australian Journal of Public Administration, 56(2), pp. 6580. https://doi.org/10.1111/j.1467-8500.1997.tb01547.xGoogle Scholar
Guest, C. (2017). Sharing the Water: 100 years of River Murray Politics. Canberra: Murray–Darling Basin Authority.Google Scholar
Jones, G., Arthington, A., Gawne, B. et al. (2003). Ecological Assessment of Environmental Flow Reference Points for the River Murray System: Interim Report Prepared by the Scientific Reference Panel for the Murray–Darling Basin Commission. Canberra: Living Murray Initiative, Cooperative Research Centre for Freshwater Ecology.Google Scholar
Kirby, M. et al. (2014). Sustainable Irrigation: How Did Irrigated Agriculture in Australia’s Murray–Darling Basin Adapt in the Millennium Drought? Agricultural Water Management, 145, pp. 154162.Google Scholar
Lintermans, M. (2009). Fishes of the Murray–Darling Basin: An Introductory Guide. Canberra: Murray–Darling Basin Authority.Google Scholar
Marsden Jacob Associates (2000). Companion Paper 2 – Economic and Social Impacts. Review of the Operation of the Cap: Overview Report of the Murray–Darling Basin Commission. Canberra: Murray–Darling Basin Ministerial Council.Google Scholar
Murray–Darling Basin Authority (MDBA) (2015). Water Markets in the Murray–Darling Basin. Available at www.mdba.gov.auGoogle Scholar
Murray–Darling Basin Authority (MDBA) (2019a). Critical Human Water Needs. Available at www.mdba.gov.au/river-information/water-sharing/critical-human-water-needsGoogle Scholar
Murray–Darling Basin Authority (MDBA) (2019b). Water Storage. Available at www.mdba.gov.au/managing water/water-storageGoogle Scholar
National Water Accounts (NWA) (2013). Murray–Darling Basin Water Access and Use. Available at www.bom.gov.au/nwa/Google Scholar
Painter, M. (1998). Collaborative Federalism: Economic Reform in Australia in the 1990s. Cambridge: Cambridge University Press.Google Scholar
Powell, J. M. (1989). Watering the Garden State: Water, Land, and Community in Victoria 1834–1988. Sydney: Allen & Unwin.Google Scholar
Wallis, P. J. (2015). Governing Irrigation Renewal in Rural Australia. International Journal of Water Governance – Special Issue, pp. 1–18. https://doi.org/10.7564/14-IJWG41Google Scholar
Young, M. et al. (2008). A Future Proof Basin. In Manne, R., ed., Dear Mr Rudd. Melbourne: Black Rock Inc.Google Scholar
Young, W. J. (ed.) (2001). Rivers as Ecological Systems: The Murray–Darling Basin. Canberra: Murray–Darling Basin Commission.Google Scholar

References

Agência Nacional de Águas [National Water Agency] (ANA) (2010). Atlas Brasil. Brasilia.Google Scholar
Agência Nacional de Águas [National Water Agency] (ANA) (2016). Conjuntura de Recursos Hídricos no Brasil. Regiões Hidrográficas Brasileiras [Water Resources in Brazil. Brazilian Hydrographic Regions]. Brasilia. Available at http://conjuntura.ana.gov.br/docs/regioeshidrograficas.pdfGoogle Scholar
Agência Nacional de Águas [National Water Agency] (ANA) (2017). Ficha RH_SF. Available at www.ana.gov.brGoogle Scholar
Barbosa, J. M. C., Pinto, M. R., and de Castro, M. A. H. (2008). Erosão e Assoreamento em Reservatórios [Erosion and Sedimentation in Reservoirs], ABRH. Available at www.abrh.org.brGoogle Scholar
Brazil Presidency (1997). Law 9433. Brasilia, 8 January 1997.Google Scholar
Carvalho, N. O. (2008). Hidrossedimentologia Prática [Practical Hydrosedimentology]. Rio de Janeiro: CPRM-Eletrobrás.Google Scholar
Carvalho, N. O., dos Santos, P. M. C., and Lima, J. E. F. W. (2000). Guia de Avaliação de Associamento de Reservatórios no Brasil [Reservoir Sedimentation Assessment Guide].Google Scholar
Comitê da Bacia Hidrográfica do Rio São Francisco [Committee of the Hydrographic Basin of the São Francisco] (CBHSF) (2015a). Plano de Recursos Hídricos da Bacia Hidrográfica do Rio São Francisco – 2015–2016 [Water Resources Plan for the São Francisco River Basin – 2015–2016].Google Scholar
Comitê da Bacia Hidrográfica do Rio São Francisco [Committee of the Hydrographic Basin of the São Francisco] (CBHSF) (2015b). Diagnóstico da Dimensão Técnica e Institucional [Diagnostic of the Technical and Institutional Dimensions]. Vol. VII of Usos, Balanço Hídricos e Síntese do Diagnóstico [Use, Water Balance and Synthesis of the Diagnostic].Google Scholar
Comitê da Bacia Hidrográfica do Rio São Francisco [Committee of the Hydrographic Basin of the São Francisco] (CBHSF) (2015c). Relatório Consolidado da Bacia do Rio São Francisco [São Francisco River Basin Consolidated Report].Google Scholar
Comitê da Bacia Hidrográfica do Rio São Francisco [Committee of the Hydrographic Basin of the São Francisco] (CBHSF) (2017). Available at www.cbhsaofrancisco.org.brGoogle Scholar
De Nys, E., Engle, N. L., and Magalhães, A. R. (2016). Secas no Brasil: Política e Gestão Proativas [Droughts in Brazil: Proactive Management and Policy]. Brasilia: Centro de Gestão e Estudos Estratégicos and The World Bank.Google Scholar
Gomes, A. (2017). As águas barrentas morem em Sobradinho [Fisherman in the Lower São Francisco]. Available at www.cbhsaofrancisco.org.brGoogle Scholar
Lima, J. E. F. W., dos Santos, P. M. C., Chaves, A. G. M., and Scilewski, L. R. (2001). Diagnóstico do Fluxo de Sedimentos em Suspensão na Bacia do Rio São Francisco [Diagnostic of the Suspended Sediment Flow in the São Francisco River Basin]. Embrapa/Aneel.Google Scholar
Mantua, N. J. and Hare, S. R. (2002). The Pacific Decadal Oscillation. Journal of Oceanography, 58, pp. 3544. https://doi.org/10.1023/A:1015820616384Google Scholar
Ministério da Integração Nacional [Ministry of National Integration] (MI) (2018). Integração do Rio São Francisco [Integration of the São Francisco River]. Available at www.mi.gov.br/web/projeto-sao-franciscoGoogle Scholar
Secretaria de Assuntos Estrategicos [Secretariat for Strategic Affairs] (SAE) (2015). Brasil 2040 Resumo Executivo [Brazil 2040 Executive Summary]. Governo Federal, Presidencia Da Republica [Federal Government, Presidency of the Republic]. Available at www.mma.gov.br/images/arquivo/80182/BRASIL-2040-Resumo-Executivo.pdfGoogle Scholar
Silva, W. F., Medeiros, P. R. P., and Viana, F. G. B. (2010). Quantificação Preliminar do Aporte de Sedimentos no Baixo São Francisco e seus principais impactos [Preliminary Assessment of Sediment Inflow in the Lower São Francisco River and Its Impacts].Google Scholar
Universidade Federal de Alagoas (2010). Sedimentos no Baixo São Francisco e seus principais impactos [São Francisco River in the Wrong Path: Degradation and Revitalization]. Presentation in the X Symposium of Water Resources in the Northeast.Google Scholar
Zellhuber, A. and Siqueira, R. (2007). Rio São Francisco em Descaminho: Degradação e Revitalização [São Francisco River in Descaminho: Degradation and Revitalization]. Salvador: Cadernos CEAS. Available at www.cptba.org.brGoogle Scholar

References

Adam, J. C., Hamlet, A., and Lettenmaier, D. P. (2009). Implications of Global Climate Change for Snowmelt Hydrology in the Twenty-first Century. Hydrological Processes, 23, pp. 962972. https://doi.org/10.1002/hyp.7201Google Scholar
Álvarez, P. (2018). The Water Footprint Challenge for Water Resources Management in Chilean Arid Zones. Water International, 43(6), pp. 846859. https://doi.org/10.1080/02508060.2018.1516092Google Scholar
Álvarez, P., Kretschmer, N., and Oyarzun, R. (2006). Water Management for Irrigation in Chile: Causes and Consequences, Technology, Resource Management and Development. Paper presented at the international water fair “Wasser Berlin 2006.”Google Scholar
Alvarez-Garreton, C., Mendoza, P. A., and Boisier, J. P. et al. (2018). The CAMELS-CL Dataset: Catchment Attributes and Meteorology for Large Sample Studies – Chile Dataset. Hydrology and Earth System Sciences, https://doi.org/10.5194/hess-2018-23Google Scholar
Baez-Villanueva, O. M., Zambrano-Bigiarini, M., and Ribbe, L. et al. (2019). A Novel Methodology for Merging Different Gridded Precipitation Products and Ground-Based Measurements. Remote Sensing of Environment. RSE-D-19-00549Google Scholar
Barnett, T. P., Adam, J. C., and Lettenmaier, D. P. (2005). Potential Impacts of a Warming Climate on Water Availability in Snow-Dominated Regions. Nature, 438, pp. 303309. https://doi.org/10.1038/nature04141Google Scholar
Bates, B. C., Kundzewicz, Z. W., Wu, S., and Palutikov, J. P. (2008). Climate Change and Water, Technical Paper of the Intergovernmental Panel on Climate Change. Geneva: IPCC Secretariat.Google Scholar
Bauer, C. (2004). Results of Chilean Water Markets: Empirical Research since 1990. Water Resources Research, 40, W09S06, https://doi.org/10.1029/2003WR002838CrossRefGoogle Scholar
Bauer, C. J. (2015). The Evolving Water Market in Chile’s Maipo River Basin: A Case Study for the Political Economy of Water Markets Project.Google Scholar
Boisier, J. P., Alvarez-Garreton, C., and Cordero, R. R. et al. (2018). Anthropogenic Drying in Central-Southern Chile Evidenced by Long-Term Observations and Climate Model Simulations. Elementa: Science of the Anthropocene, 6(74). https://doi.org/10.1525/elementa.328Google Scholar
Boisier, J. P., Rondanelli, R., Garreaud, R. D., and Muñoz, F. (2016). Anthropogenic and Natural Contributions to the Southeast Pacific Precipitation Decline and Recent Megadrought in Central Chile. Geophysical Research Letters, 43(1), pp. 413421. https://doi.org/10.1002/2015GL067265Google Scholar
CIREN (2011). Catastro frutícola [Fruit Crop Records, Land Registry], Principales Resultados [Principal Results], IV. Región de Coquimbo: CIREN, ODEPA.Google Scholar
CIREN (2015). Catastro frutícola [Fruit Crop Records, Land Registry], Principales Resultados [Principal Results], IV. Región de Coquimbo: CIRENGoogle Scholar
Cooper, M. G., Schaperow, J. R., Cooley, S. W. et al. (2018). Climate Elasticity of Low Flows in the Maritime Western U.S. Mountains. Water Resources Research, 54, pp. 56025619. https://doi.org/10.1029/2018WR022816Google Scholar
Dirección General de Aguas [General Directorate of Water] (DGA) (2004) Diagnostico y Clasificación de los cursos y cuerpos de agua según objetivos de calidad-Cuenca del Rio Limari [Diagnosis and Classification of Water Courses and Bodies According to Quality Objectives – Limari River Basin]. Sistema Nacional de Información Ambiental [National Environmental Information System]. Available at www.sinia.cl/1292/articles-31018_Limari.pdfGoogle Scholar
Donoso, G. (2006) Water Markets: Case Study of Chile’s 1981 Water Code. International Journal of Agriculture and Natural Resources, 33(2), pp. 131146.Google Scholar
Donoso, G. (2012). The Evolution of Water Markets in Chile. In Maestu, J., ed., Water Trading and Global Water Scarcity: International Experiences, pp. 111–129.Google Scholar
Donoso, G. (2018). Water Policy in Chile. Berlin: Springer International Publishing AG. https://doi.org/10.1007/978-3-319-76702-4Google Scholar
Endo, T., Kakinuma, K., Yoshikawa, S., and Kanae, S. (2018). Are Water Markets Globally Applicable? Environmental Research Letters, 13(3). https://doi.org/10.1088/1748-9326/aaac08Google Scholar
Favier, V., Falvey, M., Rabatel, A., Praderio, E., and Lopez, D. (2009). Interpreting Discrepancies between Discharge and Precipitation in High-Altitude Area of Chile’s Norte Chico Region (26–32°S). Water Resources Research, 45(2). https://doi.org/10.1029/2008WR006802Google Scholar
Finlayson, B. L., McMahon, T. A., and Peel, M. C. (2007). Updated World Map of the Köppen-Geiger Climate Classification. Hydrology and Earth System Sciences, 11(5), pp. 16331644.Google Scholar
Garreaud, R. D., Alvarez-Garreton, C., and Barichivich, J. et al. (2017). The 2010–2015 Megadrought in Central Chile: Impacts on Regional Hydroclimate and Vegetation. Hydrology and Earth System Sciences, 21, pp. 63076327.Google Scholar
Garreaud, R. D., Vuille, M., Compagnucci, R., and Marengo, J. (2009). Present-Day South American Climate. Palaeogeography, Palaeoclimatology, Palaeoecology, 281(3–4), pp. 180195.Google Scholar
Hearne, R. (2018). Water Markets. In Donoso, G., ed., Water Policy in Chile. Springer Book Series: Global Issues in Water Policy, pp. 117127.Google Scholar
Hearne, R. and Easter, K. (1997). An Analysis of Gains‐from‐Trade in Chile: The Economic and Financial Gains from Water Markets in Chile. Agricultural Economics Journal. https://doi.org/10.1016/S0169-5150(96)01205-4Google Scholar
Instituto Nacional de Estadistica [National Institute of Statistics] (INE) (2007). Censo Nacional Agropecuario y Forestal [National Agricultural and Forestry Census] VII. Santiago, Chile: Ministry of Agriculture, Government of Chile. Available at www.censoagropecuario.cl/Google Scholar
Kalthoff, N., Fiebig-Wittmaack, M., and Meißner, C. et al. (2006). The Energy Balance, Evapotranspiration, and Nocturnal Dew Deposition of an Arid Valley in the Andes. Journal of Arid Environments, 65(3), pp. 420443.Google Scholar
Krause, P. and Kraslisch, S. (2005). The Hydrological Modelling System J2000-knowledge core for JAMS. In Zerger, A., and Argent, R. M., eds., MODSIM 2005 International Congress on Modelling and Simulation, pp. 676–682.Google Scholar
Kretschmer, N.; Nauditt, A.; Ribbe, L., 2013: Basin Inventory, Limarí, Chile. Project Report CNRD – unpublished.Google Scholar
Kretschmer, N., Nauditt, A., Ribbe, L., and Becker, R. (2014). Limarí River Basin Study Phase I-Current Conditions, History and Plans. Institute for Technology and Resources Management in the Tropics and Subtropics.Google Scholar
Meza, F. (2013) Recent Trends and ENSO Influence on Droughts in Northern Chile: An Application of the Standardized Precipitation Evapotranspiration Index. Weather and Climate Extremes, 1, pp. 5158.Google Scholar
Ministerio de Justica (1981). Código de Aguas [Water Code]. In Diario Oficial de Chile [Official Gazette of Chile]. Available at www.leychile.cl/Navegar?idNorma=5605&idParte=0Google Scholar
Nauditt, A., Gaese, H., and Ribbe, L. (2000). Water Resources Management in Chile. Available at www.tt.fh-koeln.de/d/itt/publications/subject_bundles.htm#2002Vol2Google Scholar
Nauditt, A., Soulsby, C., and Birkel, C. et al. (2017). Using Synoptic Tracer Surveys to Assess Runoff Sources in an Andean Headwater Catchment in Central Chile. Environmental Monitoring and Assessment. https://doi.org/10.1007/s10661-017-6149-2Google Scholar
Nauditt, A., Thurner, J., and Zambrano-Bigiarini, M. et al. (2018). Evaluating the Performance of Satellite-Based Rainfall Estimates in Low Flow Modelling in Data Scarce Andean Catchments at Different Latitudes of Chile, EGU2018–18702.Google Scholar
Nauditt, A., Birkel, C., Soulsby, C., and Ribbe, L. (2016). Conceptual Modelling to Assess the Influence of Hydroclimatic Variability on Runoff Processes in Data Scarce Semi-arid Andean Catchments. Hydrological Sciences Journal, https://doi.org/10.1080/02626667.2016.1240870Google Scholar
Neitsch, S. L., Arnold, J. G., Kiniry, J. R., Williams, J. R., and King, K. W. (2005). Soil and Water Assessment Tool Theoretical Documentation. Ver. 2005. Temple, TX.: USDA‐ARS Grassland Soil and Water Research Laboratory, and Texas A&M University, Blackland Research and Extension Center.Google Scholar
Observatorio Laboral Chile [Chile Labor Observatory] (2019). Panorama Regional. Available at www.observatoriocoquimbo.cl/panorama.htmlGoogle Scholar
OECD (2017). Gaps and Governance Standards of Public Infrastructure in Chile. Infrastructure Governance Review.Google Scholar
Oyarzun, R. (2010) Estudio de caso: Cuenca del Limarí, Región de Coquimbo, Chile [Case study: Limarí Basin, Coquimbo Region, Chile]. Compilación Resumida de Antecedentes, Centro de Estudios Avanzados en Zonas Aridas – Universidad de la Serena (CEAZA-ULS) [Summary Compilation of Background, Center for Advanced Studies in Arid Zones – University of La Serena (CEAZA-ULS)].Google Scholar
Oyarzún, R., Arumí, J. L., Alvarez, P., and Rivera, D. (2008). Water Use in the Chilean Agriculture: Current Situation and Areas for Research Development. In Sorensen, M. L., ed., Agricultural Water Management Trends. New York: Nova Publishers, pp. 213236.Google Scholar
Oyarzun, R., Jofre, E., and Morales, P. et al. (2015). A Hydrogeochemistry and Isotopic Approach for the Assessment of Surface Water–Groundwater Dynamics in an Arid Basin: The Limarí Watershed, North−Central Chile. Environ Earth Science, 73, 3955.Google Scholar
https://doi.org/10.1007/s12665-014-3393-4Google Scholar
Penedo-Julien, S., Nauditt, A., and Künne, A. et al. (2019). Hydrological Modelling to Assess Runoff in a Semi-arid Andean Headwater Catchment for Water Management in Central Chile. In Godoy-Faundez, A. and Rivera, D., eds., Andean Hydrology. Boca Raton, FL: CRC Press.Google Scholar
Pepin, N., Bradley, R., and Diaz, H. et al. (2015). Elevation-Dependent Warming in Mountain Regions of the World. Nature Climate Change, 5, pp. 424430. https://doi.org/10.1038/nclimate2563Google Scholar
Price, M. F. and Egan, P. A. (2014). Our Global Water Towers: Ensuring Ecosystem Services from Mountains under Climate Change. Policy Brief, Paris: UNESCO.Google Scholar
Schmandt, J., North, G. R., and Ward, G. H. (2013). How Sustainable Are Engineered Rivers in Arid Lands? Journal of Sustainable Development of Energy, Water, and Environment Systems, 1(2), pp. 7893. https://doi.org/10.13044/j.sdewes.2013.01.0006Google Scholar
Seibert, J., Vis, M., and Kaser, D. (2012). HBV Light – A User Friendly Catchment-Runoff-Model Software. Geophysical Research Abstracts, EGU General Assembly, 2012, p. 14.Google Scholar
Servicio Agricola y Ganadero [Agricultural and Livestock Service] (SAG) (2018) Catastro Vitivinicola Nacional [National Wine Registry]. Available at www.sag.cl/ambitos-de-accion/catastro-viticola-nacional/1490/publicationsGoogle Scholar
Sheffield, J., Wood, E. F., and Pan, M. et al. (2018). Satellite Remote Sensing for Water Resources Management: Potential for Supporting Sustainable Development in Data-Poor Regions. Water Resources Research, 54(12), pp. 97249758. https://doi.org/10.1029/2017WR022437Google Scholar
Sheffield, J., Wood, E. F., and Roderick, M. L. (2012). Little Change in Global Drought over the Past 60 Years. Nature, 491, pp. 435438. https://doi.org/10.1038/nature11575Google Scholar
Souvignet, M., Oyarzun, R., and Verbist, K. et al. (2012). Hydro-meteorological Trends in Semi-arid North-Central Chile (29-32º S): Water Resources Implications for a Fragile Andean Region. Hydrological Sciences Journal, 57(3), p. 479.Google Scholar
Souvignet, M., Gaese, H., Ribbe, L., Kretschmer, N., and Oyarzun, R. (2010). Statistical Downscaling of Precipitation and Temperature in North-Central Chile: An Assessment of Possible Climate Change Impacts in an Arid Andean Watershed. Hydrological Sciences Journal, 55(1), pp. 4157.Google Scholar
Universidad de Chile, Facultad de Ciencias Agronomicas, Laboratorio de análisis Territorial [University of Chile, Faculty of Agronomic Sciences, Territorial Analysis Laboratory] (2018). Diagnostico Nacional de Organizaciones de Usuarios [National Diagnosis of User Organizations]. Resumen Ejecutivo [Executive Summary]. Available at https://snia.mop.gob.cl/sad/ADM5812v1.pdfGoogle Scholar
Urquiza, A. and Billi, M. (2018). Water Markets and Socio-ecological Resilience to Water Stress in the Context of Climate Change: An Analysis of the Limarí Basin, Chile. In Environment, Development and Sustainability, pp. 1–23. https://doi.org/10.1007/sl0668-018-0271-3Google Scholar
Van Loon, A. F. and Van Lanen, H. A. (2012). A Process-Based Typology of Hydrological Drought. Hydrology and Earth System Sciences, 16, pp. 19151946. https://doi.org/10.5194/hess-16-1915-2012Google Scholar
Verbist, K., Robertson, A. W., Cornelis, W., and Gabriels, D. (2010) Seasonal Predictability of Daily Rainfall Characteristics in Central-Northern Chile for Dry-Land Management. Journal for Applied Meteorology and Climate, 49(9), pp. 19381955.Google Scholar
Vergara, A. and Rivera, D. (2018) Legal and Institutional Framework of Water Resources. In Donoso, G., ed., Water Policy in Chile. Berlin: Springer Book Series, Global Issues in Water Policy, pp. 6784.Google Scholar
Vicuña, S., McPhee, J., and Garreaud, R. D. (2011). Climate Change Impacts on the Hydrology of a Snowmelt Driven Basin in Semiarid Chile. Climatic Change, 105(3–4), pp. 469488.Google Scholar
Vicuña, S., McPhee, J., and Garreaud, R. D. (2012). Agriculture Vulnerability to Climate Change in a Snowmelt Driven Basin in Semiarid Chile. Journal of Water Resources Planning and Management, 138(5), pp. 431441. https://doi.org/10.1061/(ASCE)WR.1943-5452.0000202Google Scholar
Vicuña, S., Alvarez, P., Melo, O., Dale, L., and Meza, F. (2014). Irrigation Infrastructure Development in the Limarí Basinte Variability and Climate Change. Water International, 39(5), pp. 620634. https://doi.org/10.1080/02508 060.2014.94506 8Google Scholar
Viviroli, D., Durr, H. H., Messerli, B., Meybeck, M., and Weingartner, R. (2007). Mountains of the World, Water Towers for Humanity: Typology, Mapping, and Global Significance. Water Resources Research, 43(7). https://doi.org/10.1029/2006WR005653Google Scholar
Vuille, M., Franquist, E., Garreaud, R., Lavado Casimiro, W., and Caceres, B. (2015). Impact of the Global Warming Hiatus on Andean Temperature. Journal of Geophysical Research: Atmospheres, 120(9), pp. 37453757. https://doi.org/10.1002/2015JD023126Google Scholar
WEIN (2014). Increasing Water Use Efficiency in the Limarí Basin. Available at www.hidro-limari.infoGoogle Scholar
Zambrano-Bigiarini, M., Nauditt, A., Birkel, C., Verbist, K., and Ribbe, L. (2017). Temporal and Patial Evaluation of Satellite-Based Rainfall Estimates across the Complex Topographical and Climatic Gradients of Chile. Hydrology and Earth System Sciences. https://doi.org/10.5194/hess-2016-453Google Scholar

References

Antunes, P., Kallis, G., Videira, N., and Santos, R. (2009). Participation and Evaluation for Sustainable River Basin Governance. Ecological Economics, 68(4), pp. 931939. https://doi.org/10.1016/j.ecolecon.2008.12.004Google Scholar
Ault, T. R., Cook, B. I., Mankin, J. S., and Smerdon, J. E. (2016). Relative Impacts of Mitigation, Temperature, and Precipitation on 21st-Century Megadrought Risk in the American Southwest. Science Advances, 2(10), e1600873.Google Scholar
Barnum, D. A., Bradley, T., Cohen, M., Wilcox, B., and Yanega, G. (2017). State of the Salton Sea: A Science and Monitoring Meeting of Scientists for the Salton Sea (Open-File Report No. 2017–1005) (p. 20). U.S. Geological Survey. https://doi.org/10.3133/ofr20171005Google Scholar
Blomquist, W., Dinar, A., and Kemper, K. (2005). Comparison of Institutional Arrangements for River Basin Management in Eight Basins.pdf (World Bank Policy Research Working Paper No. 3636). World Bank. https://doi.org/10.2139/ssrn.757225Google Scholar
Bloom, P. L. (1986). Law of the River: A Critique of an Extraordinary Legal System. In Brown, F. and Weatherford, G., eds., New Courses for the Colorado River: Major Issues for the Next Century. Albuquerque: University of New Mexico Press, pp. 139154.Google Scholar
Bureau of Reclamation, US Department of the Interior (2012). Colorado River Basin Water Supply and Demand Study. Available at www.usbr.gov/watersmart/bsp/docs/finalreport/ColoradoRiver/CRBS_Executive_Summary_FINAL.pdfGoogle Scholar
Bureau of Reclamation, US Department of the Interior (2015). Colorado River Basin Stakeholders Moving Forward to Address Challenges Identified in the Colorado River Basin Water Supply and Demand Study. Available at www.usbr.gov/lc/region/programs/crbstudy/MovingForward/Phase1Report/fullreport.pdfGoogle Scholar
Cohen, M. J. (2011). Municipal Deliveries of Colorado River Basin Water. Pacific Institute. Available at http://pacinst.org/publication/municipal-deliveries-of-colorado-river-basin-water-new-report-examines-100-cities-and-agencies/Google Scholar
Cohen, M. J., Christian-Smith, J., and Berggren, J. (2013). Water to Supply the Land: Irrigated Agriculture in the Colorado River Basin. Pacific Institute. Available at http://pacinst.org/publication/water-to-supply-the-land-irrigated-agriculture-in-the-colorado-river-basin/Google Scholar
Colorado River Basin Salinity Control Forum. (2011 ). 2011 Review: Water Quality Standards for Salinity Colorado River System (October). Available at http://coloradoriversalinity.org/docs/2011 percent20REVIEW-October.pdfGoogle Scholar
Cook, B. I., Ault, T. R., and Smerdon, J. E. (2015). Unprecedented 21st Century Drought Risk in the American Southwest and Central Plains. Science Advances, 1(1), e1400082–e1400082. https://doi.org/10.1126/sciadv.1400082Google Scholar
Cook, B. I., Cook, E. R., Smerdon, J. E., Seager, R., Williams, A. P., Coats, S., Stahle, D. W., and Dias, J. V. (2016). North American Megadroughts in the Common Era: Reconstructions and Simulations. WIREs Climate Change, 7(3), pp. 411432. https://doi.org/10.1002/wcc.394Google Scholar
Fleck, J. (2016). Water Is for Fighting Over: And Other Myths About Water in the West. Washington, DC: Island Press.Google Scholar
Fradkin, P. L. (1981). A River No More: The Colorado River and the West. Tucson: University of Arizona Press.Google Scholar
Fulp, T. (2017). How Does DCP Address Lake Mead’s “Math Problem”? Presented at the Martz Summer Conference. University of Colorado – Boulder.Google Scholar
Getches, D. H. (1985). Competing Demands for the Colorado River. University of Colorado Law Review, 56, pp. 413479.Google Scholar
Getches, D. H. (1997). Colorado River Governance: Sharing Federal Authority as an Incentive to Create a New Institution. University of Colorado Law Review, 68, p. 573.Google Scholar
Grant, D. L. (2007). Collaborative Solutions to Colorado River Water Shortages: The Basin States’ Proposal and beyond. Nevada Law Journal, 8, p. 964.Google Scholar
Hundley, N. jr. (1966 ). Dividing the Waters: A Century of Controversy between the United States and Mexico. Los Angeles: University of California Press.Google Scholar
Kendy, E. and Pitt, J. (2017). Shaping the 2014 Colorado River Delta Pulse Flow: Rapid Environmental Flow Design for Ecological Outcomes and Scientific Learning. Ecological Engineering, 106, pp. 704714. https://doi.org/10.1016/j.ecoleng.2016.12.002Google Scholar
Kenney, D. (2005). In Search of Sustainable Water Management: International Lessons for the American West and beyond. Massachusetts, MA: Edward Elgar Publishing.Google Scholar
King, J. S., Culp, P. W., and de la Parra, C. (2014). Getting to the Right Side of the River: Lessons for Binational Cooperation on the Road to Minute 319. University of Denver Water Law Review, 18, p. 36.Google Scholar
Miller, M. P., Buto, S. G., Susong, D. D., and Rumsey, C. A. (2016). The Importance of Base Flow in Sustaining Surface Water Flow in the Upper Colorado River Basin. Water Resources Research. https://doi.org/10.1002/2015WR017963Google Scholar
Mueller, E. R., Grams, P. E., Hazel, J. E., and Schmidt, J. C. (2018). Variability in Eddy Sandbar Dynamics during Two Decades of Controlled Flooding of the Colorado River in the Grand Canyon. Sedimentary Geology, 363, pp. 181199.Google Scholar
Mulroy, P. (2007). Collaboration and the Colorado River Compact. Nevada Law Journal, 8, p. 890.Google Scholar
Pitt, J. (2001). Can We Restore the Colorado River Delta? Journal of Arid Environments, 49, pp. 211220.Google Scholar
Pitt, J. and Kendy, E. (2017). Shaping the 2014 Colorado River Delta Pulse Flow: Rapid Environmental Flow Design for Ecological Outcomes and Scientific Learning. Ecological Engineering, 106, pp. 704714. https://doi.org/10.1016/j.ecoleng.2016.12.002Google Scholar
Powell, J. (2010). Calamity on the Colorado. Orion. Available at www.orionmagazine.org/index.php/articles/article/5617/Google Scholar
Reisner, M. (1986). Cadillac Desert: The American West and Its Disappearing Water. New York: Penguin.Google Scholar
Robison, J. and Kenney, D. (2012). Equity and the Colorado River Compact. Environmental Law, 42, p. 1157.Google Scholar
Rosenberg, K. V., Ohmart, R. D., Hunter, W. C., and Anderson, B. W. (1991). Birds of the Lower Colorado River Valley. Tucson: University of Arizona Press, p. 416.Google Scholar
Southwick Associates (2012). Economic Contributions of Outdoor Recreation on the Colorado River & Its Tributaries. Prepared for Protect the Flows. Available at http://protectflows.com/wp-content/uploads/2013/09/Colorado-River-Recreational-Economic-Impacts-Southwick-Associates-5-3-12_2.pdfGoogle Scholar
Tipton and Kalbach Inc. (1965). Water Supplies of the Colorado River. Report Prepared for the Upper Colorado River Commission. Denver, CO.Google Scholar
Udall, B. and Overpeck, J. (2017).  The 21st Century Colorado River Hot Drought and Implications for the Future. Water Resources Researchhttps://doi.org/10.1002/2016WR019638Google Scholar
Vano, J. A., Udall, B., and Cayan, D. R. et al. (2014). Understanding Uncertainties in Future Colorado River Streamflow. Bulletin of the American Meteorological Society, 95, pp. 5978.Google Scholar
Whiteley, J. M., Ingram, H. M., and Perry, R. W. (eds.) (2008). Water, Place, and Equity. Cambridge, MA: MIT Press.Google Scholar

References

Action Committee of the Middle Rio Grande Water Assembly (ACMRGWA) (1999). Middle Rio Grande Water Budget (Where Water Comes from, & Goes, & How Much), Averages for 1972–1997, Albuquerque, NM: ACMRGWA.Google Scholar
Adams, D. and Comrie, A. (1997). The North American Monsoon. Bulletin of the American Meteorological Society, 78(10), pp. 21972213.Google Scholar
Adams, D. and Keller, G. (1994). Crustal Structure and Basin Geometry in South-Central New Mexico. In Keller, G. and Cather, S., eds., Basins of the Rio Grande Rift: Structure, Stratigraphy, and Tectonic Setting. Special Paper 291, Boulder, CO: Geological Society of America, pp. 241255.Google Scholar
Anaya, R., Boghici, R., and French, L. et al. (2016). Texas Aquifers Study: Groundwater Quantity, Quality, Flow, and Contributions to Surface Water. Special report to Legislature, Austin: Texas Water Development Board.Google Scholar
Atwood, W. W. (1918). Relation of Landslides and Glacial Deposits to Reservoir Sites. Bulletin 685, US Geological Survey. Washington, DC: Government Printing Office.Google Scholar
Baldridge, W. and Olsen, K. (1989). The Rio Grande Rift: What Happens When the Earth’s Lithosphere Is Pulled Apart? American Scientist, 77 (3), pp. 240247.Google Scholar
Baldridge, W., Damon, P., Shafiqullah, M., and Bridwell, R. (1980). Evolution of the Central Rio Grande Rift, New Mexico: New Potassium-Argon Ages. Earth & Planetary Science Letters, 51, pp. 309321.Google Scholar
Baldwin, B. and Kottlowski, F. (1968). Santa Fe: Scenic Trips to the Geologic Past No. 1, 2nd ed., Socorro: State Bureau of Mines & Mineral Resources.Google Scholar
Barry, R. and Carleton, A. (2001). Synoptic and Dynamic Climatology. New York: Routledge.Google Scholar
Bartolino, J. and Cole, J. (2002). Ground-Water Resources of the Middle Rio Grande Basin. Circular 1222, Denver, CO: US Geological Survey.Google Scholar
Benke, A. and Cushin, C. (2005). Rivers of North America. Burlington, MA: Elsevier Academic Press.Google Scholar
Bexfield, L. M. (2010). Section 11: Middle Rio Grande Basin, New Mexico. In Thiros, et al., eds., Conceptual Understanding and Groundwater Quality of Selected Basin-Fill Aquifers in the Southwestern United States. National Water-Quality Assessment Program: USGS, pp. 189218.Google Scholar
Bexfield, L. and Anderholm, S. (2010). Section 10: San Luis Valley, Colorado, and New Mexico. In Thiros, et al., eds., Conceptual Understanding and Groundwater Quality of Selected Basin-Fill Aquifers in the Southwestern United States. National Water-Quality Assessment Program: USGS, pp. 165187.Google Scholar
Bjorklund, L. and Maxwell, B. (1961). Availability of Ground Water in the Albuquerque Area, Bernalillo and Sandoval Counties, New Mexico. Technical Report 21, New Mexico State Engineer, Santa Fe.Google Scholar
Blake, E., Gibney, D., and Brown, M. et al. (2009). Tropical Cyclones of the Eastern North Pacific Basin, 1949–2006. Historical Climatology Series 6-5, Asheville, NC: US National Oceanic and Atmospheric Administration.Google Scholar
Blakey, R. and Ranney, W. (2018). Ancient Landscapes of Western North America: A Geologic History with Paleogeographic Maps. Cham, Switzerland: Springer International Publishing.Google Scholar
Bluestein, H. B. (1993). Synoptic-Dynamic Meteorology in Midlatitudes. Vol II: Observations and Theory of Weather Systems. New York: Oxford University Press.Google Scholar
Bogener, S. D. (1993). Carlsbad Project. Albuquerque: Bureau of Reclamation.Google Scholar
Bogener, S. D. (1997). Ditches across the Desert: A Story of Irrigation along New Mexico’s Pecos River. Ph.D. dissertation: Texas Tech University, Lubbock.Google Scholar
Booker, J., Michelsen, A., and Ward, F. (2005). Economic Impact of Alternative Policy Responses to Prolonged and Severe Drought in the Rio Grande Basin. Water Resources Research, 41, https://doi.org/10.1029/2004WR003486Google Scholar
Brand, D. D. (1937). The Natural Landscape of Northwestern Chihuahua. Albuquerque: The University of New Mexico Press.Google Scholar
Bryan, K. (1938). Geology and Ground-Water Conditions of the Rio Grande Depression in Colorado and New Mexico. In US Natural Resources Planning Board, The Rio Grande Joint Investigation in the Upper Rio Grande Basin in Colorado, New Mexico, and Texas 1936–1937. Washington, DC: Government Printing Office, pp. 197225.Google Scholar
Bureau of Reclamation, US Department of Interior (2008). Elephant Butte Reservoir: 2007 Reservoir Survey. Washington, DC: Government Printing Office.Google Scholar
Bureau of Reclamation, US Department of Interior (2013). Impacts of Climate Change on the Upper Rio Grande Basin: Adaptation and Mitigation Strategies. Washington, DC: Government Printing Office.Google Scholar
Castro, C., McKee, T., and Pielke, R. (2001). The Relationship of the North American Monsoon to Tropical and North Pacific Sea Surface Temperatures as Revealed by Observational Analyses. Journal of Climate, 14, pp. 44494473.Google Scholar
Chapin, C. E. (2008). Interplay of Oceanographic and Paleoclimate Events with Tectonism during Middle to Late Miocene Sedimentation across the Southwestern USA. Geosphere, 4 (6), pp. 976991. https://doi.org/10.1130/GES00171.1Google Scholar
Chapin, C. and Cather, S. (1994). Tectonic Setting of the Axial Basins of the Northern and Central Rio Grande Rift. In Keller, G. and Cather, S., eds., Basins of the Rio Grande Rift: Structure, Stratigraphy, and Tectonic Setting. Special Paper 291, Boulder, CO: Geological Society of America, pp. 525.Google Scholar
Chapin, C. and Seager, W. (1975). Evolution of the Rio Grande Rift in the Socorro and Las Cruces Areas. Guidebook, 26th Field Conference, Socorro: New Mexico Geological Society.Google Scholar
Clark, I. G. (1987). Water in New Mexico. Albuquerque: University of New Mexico Press.Google Scholar
Cliet, T. (1969). Ground-Water Occurrence of the El Paso Area and Its Related Geology. In Cordoba, D., Wengerd, S., and Shomaker, J., eds., The Border Region (Chihuahua, Mexico & USA). 20th Annual Fall Field Conference Guidebook, New Mexico Geological Society, pp. 209214.Google Scholar
Connell, S., Hawley, J., and Love, D. (2005). Late Cenozoic Drainage Development in the Southeastern Basin and Range of New Mexico, Southeasternmost Arizona, and Western Texas. In Lucas, S., Morgan, G., and Zeigler, K., eds., New Mexico’s Ice Ages. Science Bulletin No. 28, Socorro: New Mexico Museum of Natural History and Science, pp. 125150.Google Scholar
Cook, E., Seager, R., Cane, M., and Stahle, D. (2007). North American Drought: Reconstructions, Causes, and Consequences. Earth-Science Reviews, 81, 93134.Google Scholar
Cooper, D., Sanderson, J., Stannard, D., and Groeneveld, D. (2006). Effects of Long-Term Water Table Drawdown on Evapotranspiration and Vegetation in an Arid Region Phreaphyte Community. Journal of Hydrology, 325, pp. 2134.Google Scholar
Corbosiero, K., Dickinson, M., and Bosart, L. (2009). The Contribution of Eastern North Pacific Tropical Cyclones to the Rainfall Climatology of the Southwest United States. Monthly Weather Review, 137, pp. 24152435.Google Scholar
Cronin, T. M. (2010). Paleoclimates. New York: Columbia University Press.Google Scholar
Davis, J., Hudson, M., and Grauch, V. (2017). A Paleomagnetic Age Estimate for the Draining of Ancient Lake Alamosa, San Luis Valley, South-Central Colorado, U.S.A. Rocky Mountain Geology, 52(2), pp. 107117. https://doi.org/10.24872/rmgjournal.52.2.107Google Scholar
Dethier, D. P. (1999). Quaternary Evolution of the Rio Grande near Cochiti Lake, Northern Santo Domingo Basin, New Mexico. In Passaglia, F. and Lucas, S., eds., Albuquerque Geology. New Mexico Geological Society 50th Annual Fall Field Conference Guidebook, pp. 371–378.Google Scholar
Dickerson, P. E. (2013). Tascotal Mesa Transfer Zone: An Element of the Border Corridor Transform System, Rio Grande Rift of West Texas and Adjacent Mexico. In Hudson, M. and Grauch, V., eds., New Perspectives on Rio Grande Rift Basins: from Tectonics to Groundwater. Special Paper 494, Geological Society of America, pp. 475–500.Google Scholar
Dickinson, W. R. (2004). Evolution of the North American Cordillera. Annual Review of Earth and Planetary Sciences, 32, pp. 1345.Google Scholar
Dinatale Water Consultants (2015). Rio Grande Implementation Plan. Boulder, CO.Google Scholar
Douglas, M., Maddox, R., and Howard, K. (1993). The Mexican Monsoon. Journal of Climate, 6, pp. 16651677.Google Scholar
Duryea, E. and Haehl, H. (1916). A Study of the Depth of Annual Evaporation from Lake Conchos, Mexico. Paper No. 1376, Transactions ASCE 80, pp. 1829–2060.Google Scholar
Eastoe, C., Hawley, J., Hibbs, B., Hogan, J., and Hutchison, W. (2010). Interaction of a River with an Alluvial Basin Aquifer: Stable Isotopes, Salinity, and Water Budgets. Journal of Hydrology, 395, pp. 6778.Google Scholar
Everitt, B. (1991). Channel Responses to Declining Flow on the Rio Grande between Ft. Quitman and Presidio, Texas. Geomorphology, 6, pp. 225242.Google Scholar
Ewing, T. E. (2016). Texas through Time: Lone Star Geology, Landscapes, and Resources. Austin: Bureau of Economic Geology, University of Texas.Google Scholar
Fischer, A. F. (1981). Climatic Oscillations in the Biosphere. In Nitecki, M. H., ed., Biotic Crises in Ecological and Evolutionary Time. New York: Academic Press, pp. 103131.Google Scholar
Fox, D. G., Jamison, R., Potter, D. U., Valett, H. M., and Watts, R. (1995). Geology, Climate, Land, and Water Quality. In Finch, D. and Tainter, J., eds., Ecology, Diversity, and Sustainability of the Middle Rio Grande Basin. Report RM-GTR-268, Ft. Collins, CO: Forest Service, US Department of Agriculture, pp. 52–79.Google Scholar
Galloway, W., Whiteaker, T., and Ganey-Curry, P. (2011). History of Cenozoic North American Drainage Basin Evolution, Sediment Yield, and Accumulation in the Gulf of Mexico Basin. Geosphere, 7(4), pp. 938973.Google Scholar
George, P., Mace, R., and Petrossian, R. (2011). Aquifers of Texas. Report 380, Austin: Texas Water Development Board.Google Scholar
Gile, L., Hawley, J., and Grossman, R. (1981). Soils and Geomorphology in the Basin and Range Area of Southern New Mexico: Guidebook to the Desert Project. Memoir 39, Socorro: New Mexico Bureau of Mines & Mineral Resources.Google Scholar
Graham, A. (1999). Late Cretaceous and Cenozoic History of North American Vegetation North of Mexico. New York: Oxford University Press.Google Scholar
Griggs, J. (1907). Mines of Chihuahua, History, Geology, Statistics, Mining Companies. Chihuahua City.Google Scholar
Hawley, J. W. (1969). Notes on the Geomorphology and Late Cenozoic Geology of Northwestern Chihuahua. In Cordoba, D., Wengerd, S., and Shomaker, J., eds., Guidebook of the Border Region. Twentieth Field Conference, Socorro: New Mexico Geological Society, pp. 131142.Google Scholar
Hawley, J. and Haase, C. (1992). Hydrogeologic Framework of the Northern Albuquerque Basin. Open-file Report 387, Socorro: New Mexico Bureau of Mines and Mineral Resources.Google Scholar
Hawley, J. and Kennedy, J. (2004). Creation of a Digital Hydrogeologic Framework Model of the Mesilla Basin and Southern Jornada del Muerto Basin. Technical Completion Report 332, New Mexico State University, Las Cruces: New Mexico Water Resources Research Institute.Google Scholar
Hawley, J. and Kernodle, M. (1999). Overview of the Hydrogeology and Geohydrology of the Northern Rio Grande Basin: Colorado, New Mexico, and Texas. Forty-fourth Annual New Mexico Water Conference, Santa Fe, Las Cruces: New Mexico Water Resources Research Institute.Google Scholar
Hearne, G. and Dewey, J. (1988). Hydrologic Analysis of the Rio Grande Basin North of Embudo, New Mexico, Colorado and New Mexico. Water-Resources Investigations Report 86-4113, Denver, CO: US Geological Survey.Google Scholar
Herzog, L. A. (1990). Where North Meets South: Cities, Space, and Politics on the U.S.–Mexico Border. Austin: Center for Mexican-American Studies, University of Texas.Google Scholar
Hibbs, B. and Darling, B. (2005). Revisiting a Classification Scheme for U.S.-Mexico Alluvial Basin-Fill Aquifers. Ground Water, 43 (5), pp. 750763.Google Scholar
Higgins, R. and Shi, W. (2000). Dominant Factors Responsible for Interannual Variability of the Summer Monsoon in the Southwestern United States. Journal of Climate, 13, pp. 759776.Google Scholar
Hill, R. T. (1900). Physical Geography of the Texas Region. Folio 3, Topographic Atlas of the United States. Washington, DC: US Geological Survey.Google Scholar
Hufstetler, M. and Johnson, L. (1993). Watering the Land: The Turbulent History of the Carlsbad Irrigation District. Rocky Mountain Region, Denver, CO: National Park Service.Google Scholar
Hutchins, W. (1928). The Community Acequia: Its Origins and Development. Southwestern Historical Quarterly, 31(3), pp. 261184.Google Scholar
IBWC (1998). Transboundary Aquifers and Binational Ground Water Database for the City of El Paso/Ciudad Juárez Area. Available at www.ibwc.state.gov/Water_Data/binational_waters.htm.Google Scholar
IBWC (1995). Minute 293: Emergency Cooperative Measures to Supply Municipal Needs of Mexican Communities Located Along the Rio Grande Downstream of Amistad Dam.Google Scholar
Ingersoll, R. V. (2001). Structural and Stratigraphic Evolution of the Rio Grande Rift, Northern New Mexico, and Southern Colorado. International Geology Review, 43, pp. 867891.Google Scholar
Kammerer, J. C. (1990). Largest rivers in the United States. Open-file Report 87-242 (revised 1990), Reston, VA: US Geological Survey.Google Scholar
Keller, G. and Baldridge, W. (1999). The Rio Grande Rift: A Geological and Geophysical Overview. Rocky Mountain Geology, 34(1), pp. 121130.Google Scholar
Keller, G. and Cather, S. (1994). Introduction. In Keller, G. and Cather, S., eds., Basins of the Rio Grande Rift: Structure, Stratigraphy, and Tectonic Setting. Special Paper 291, Boulder, CO: Geological Society of America, pp. 13.Google Scholar
Kelley, P. (1986). River of Lost Dreams: Navigation on the Rio Grande. Lincoln: University of Nebraska Press.Google Scholar
Kelley, V. C. (1969). Albuquerque: Its Mountains, Valley, Water, and Volcanoes. Scenic Trips to the Geologic Past No. 9, Socorro: New Mexico Institute of Mining & Technology.Google Scholar
Kelley, V. C. (1977). Geology of Albuquerque Basin, New Mexico. Memoir 33, Socorro: New Mexico Bureau of Mines & Mineral Resources.Google Scholar
Kelley, S. and Chamberlin, R. (2012). Our Growing Understanding of the Rio Grande Rift. New Mexico Earth Matters, 12(2), pp. 14. New Mexico Bureau of Geology and Mineral Resources.Google Scholar
Ladwig, W. and Stensrud, D. (2009). Relationship between Tropical Easterly Waves and Precipitation during the North American Monsoon. Journal of Climate, 22, pp. 258271.Google Scholar
Land, L. (2016). Overview of Fresh and Brackish Water Quality in New Mexico. Open-file Report 583, Socorro: New Mexico Bureau of Geology and Mineral Resources.Google Scholar
Langman, J. and Anderholm, S. (2004). Effects of Reservoir Installation, San Juan-Chama Project Water, and Reservoir Operation on Streamflow and Water Quality in the Rio Chama and Rio Grande, Northern and Central New Mexico, 1938–2000. Scientific Investigations Report 2004-5188, Denver, CO: US Geological Survey.Google Scholar
Llewellyn, D. and Vaddey, S. (2013). West-wide climate risk assessment: Upper Rio Grande impact assessment. Upper Colorado Region, Albuquerque: Bureau of Reclamation.Google Scholar
Lyle, M., Barron, J., and Bralower, T. et al. (2008). Pacific Ocean and Cenozoic Evolution of Climate. Reviews of Geophysics, 46. https://doi.org/10.1029/2005RG000190Google Scholar
Lyle, M., Heusser, C., and Ravelo, M. et al. (2012). Out of the Tropics: The Pacific, Great Basin Lakes, and Late Pleistocene Water Cycle in the Western United States. Science, 337, pp. 16291633.Google Scholar
Mace, R., Mullican, W., and Angle, E. (2001). Aquifers of West Texas. Report 356, Austin: Texas Water Development Board.Google Scholar
Machette, M., Marchetti, D., and Thompson, R. (2007). Ancient Lake Alamosa and the Pliocene to Middle Pleistocene Evolution of the Rio Grande. In Machette, M., Coates, M., and Johnson, M., eds., Rocky Mountain Section Friends of the Pleistocene Field Trip–Quaternary Geology of the San Luis Basin of Colorado and New Mexico. Open File Report 2007-1193, Reston, VA: US Geological Survey, pp. 157167.Google Scholar
Madden, R. and Julian, P. (1994). Observations of the 40-50-Day Tropical Oscillation: A Review. Monthly Weather Review, 122, pp. 814837.Google Scholar
Mann, P. (2007). Overview of the Tectonic History of Northern Central America. In Mann, P., ed., Geologic and Tectonic Development of the Caribbean Plate Boundary in Northern Central America. Special Paper 428, Geological Society of America, pp. 119.Google Scholar
Martinez-Sanchez, J. and Cavazos, T. (2014) Eastern Tropical Pacific Hurricane Variability and Landfalls on Mexican Coasts. Climate Research, 58, pp. 221234.Google Scholar
McAdie, C., Landsea, C., and Neumann, J. et al. (2009). Tropical Cyclones of the North Atlantic Ocean, 1851–2006. Historical Climatology Series 6-2, Asheville, NC: US National Oceanic and Atmospheric Administration.Google Scholar
Murphy, E. C. (1905). Failures of Lake Avalon Dam, near Carlsbad, N. M. Engineering News, 54(1), pp. 910.Google Scholar
Ortega-Ramírez, J. Urrutia-Fucugauchi, J. and Valiente-Banuet, A. (2000). The Laguna de Babícora Basin: A Late Quaternary Paleolake in Northwestern Mexico. In Gierlowski-Kordesch, E. and Kelts, K., eds., Lake Basins through Space and Time. Studies in Geology 46, American Association of Professional Geologists, pp. 569580.Google Scholar
Passaglia, F. J. (2005). River Responses to Ice Age (Quaternary) Climates in New Mexico. In Lucas, S., Morgan, G., and Zeigler, K., eds., New Mexico’s Ice Ages. Science Bulletin No. 28, New Mexico Museum of Natural History and Science, pp. 115124.Google Scholar
Pazzaglia, F. and Hawley, W. (2004). Neogene (Rift Flank) and Quaternary Geology and Geomorphology. In Mack, G. and Giles, K., eds., The Geology of New Mexico, a Geological History. Special Publication 11, Socorro: New Mexico Geological Society, pp. 407438.Google Scholar
Perdigón-Morales, J., Romero-Centeno, R., Barrett, B., and Ordoñez, P. (2019). Interseasonal Variability of Summer Precipitation in Mexico: MJO Influence on the Midsummer Drought. Journal of Climate, 32, pp. 23132327.Google Scholar
Perez-Arlucea, M., Mack, G., and Leeder, M. (2000). Reconstructing the Ancestral (Plio-Pleistocene) Rio Grande in Its Active Tectonic Setting, Southern Rio Grande Rift, New Mexico, USA. Sedimentology, 47, pp. 701720.Google Scholar
Petrie, M., Collins, S., Gutzler, D., and Moore, D. (2014). Regional Trends and Local Variability in Monsoon Precipitation in the Northern Chihuahuan Desert, USA. Journal of Arid Environments, 103, pp. 6370.Google Scholar
Plummer, L. L., Bexfield, S., Anderholm, S., Sanford, W., and Busenberg, E. (2004). Hydrochemical Tracers in the Middle Rio Grande Basin, USA: 1. Conceptualization of Groundwater Flow. Hydrogeology, 12, pp. 359388. https://doi.org/10.1007/s10040-004-0324-6Google Scholar
Rango, A. (2006). Snow: The Real Water Supply for the Rio Grande Basin. New Mexico Journal of Science, 44, pp. 99118.Google Scholar
Rasskazov, S., Yasnygina, T., Fefelov, N., and Saranina, E. (2010). Geochemical Evolution of Middle-Late Cenozoic Magmatism in the Northern Part of the Rio Grande Rift, Western United States. Russian Journal of Pacific Geology, 4(1), pp. 1340.Google Scholar
Repasch, M., Karlstrom, K., Heizler, M., and Pecha, M. (2017). Birth and Evolution of the Rio Grande Fluvial System in the Past 8 Ma: Progressive Downward Integration and the Influence of Tectonics, Volcanism, and Climate. Earth-Science Reviews, 168, pp. 113164.Google Scholar
Ricketts, J., Kelley, S., and Karlstrom, K. et al. (2016). Synchronous Opening of the Rio Grande Rift along Its Entire Length at 25-10 Ma Supported by Apatite (U-Th)/He and Fission-Track Thermochronology, and Evaluation of Possible Driving Mechanisms. GSA Bulletin 128 (3/4), pp. 397424.Google Scholar
Riecker, R. E., ed. (1979). Rio Grande Rift: Tectonics and Magmatism. Special Publication. Washington, DC: American Geophysical Union.Google Scholar
Ritchie, E., Wood, K., Gutzler, D., and White, S. (2011). The Influence of Eastern Pacific Tropical Cyclone Remnants on the Southwestern United States. Monthly Weather Review, 139, pp. 192210.Google Scholar
Rivera, J. A. (1998). Acequia Culture: Water, Land, and Community in the Southwest. Albuquerque: University of New Mexico Press.Google Scholar
Robson, S. and Banta, E. (1995). Arizona, Colorado, New Mexico, Utah. Section HA 730-C of Ground water atlas of the United States. Denver, CO: US Geological Survey. Available at https://water.usgs.gov/ogw/aquifer/atlas.htmlGoogle Scholar
Ruleman, C., Hudson, A., and Thompson, R. et al. (2019). Middle Pleistocene Formation of the Rio Grande Gorge, San Luis Valley, South-Central Colorado and North-Central New Mexico, USA: Process, Timing, and Downstream Implications. Quaternary Science Reviews, 223, https://doi.org/10.1016/j.quascirev.2019.07.028Google Scholar
Sandoval-Solis, S. (2015). Effect of Extreme Storms on Treaty Obligations in the Rio Conchos. Research Report, University of California, Davis: Water Management Research Laboratory.Google Scholar
Schmandt, J., North, G. R., and Ward, G. H. (2013). How Sustainable Are Engineered Rivers in Arid Lands? Journal of Sustainable Development of Energy, Water and Environment Systems, 1(2).Google Scholar
Schmidt, J., Everitt, B., and Richard, G. (2001). Hydrology and Geomorphology of the Rio Grande and Implications for River Rehabilitation. In Garrett, G. and Allan, N., eds., Aquatic Fauna of the Northern Chihuahuan Desert. Special Publications 46, Lubbock: Museum of Texas Tech University, pp. 2545.Google Scholar
Schmidt, R. H. (1986). Chihuahuan Climate. In Barlow, J., Powell, A., and Timmermann, B., eds., Chihuahuan Desert: U.S. and Mexico II. Alpine, Texas: Chichuahuan Desert Research Institute, Sul Ross State University, pp. 4063.Google Scholar
Schuyler, J. D. (1909). Reservoirs for Irrigation, Water-Power and Domestic Water-Supply, 2nd ed. New York: John Wiley & Sons.Google Scholar
Scurlock, D. (1998). From the Rio to the Sierra: An Environmental History of the Middle Rio Grande Basin. General Technical Report RMRS-GTR-5. Fort Collins, CO: US Department of Agriculture, Forest Service, Rocky Mountain Research Station.Google Scholar
Seager, R. (2007). The Turn of the Century North American Drought: Global Context, Dynamics and Past Analogs. Journal of Climate, 20, pp. 55275552.Google Scholar
Seager, R., Kushnir, Y., Herweijer, C., Naik, N., and Velez, J. (2005). Modeling of Tropical Forcing of Persistent Droughts and Pluvials over Western North America: 1856–2000. Journal of Climate, 18, pp. 40654088.Google Scholar
Seager, W., Shafiqullah, M., Hawley, J., and Marvin, R. (1984). New K-Ar Dates from Basalts and the Evolution of the Southern Rio Grande Rift. Geological Society of America Bulletin, 95, pp. 8799.Google Scholar
Senay, G., Schauer, M., and Velpuri, N. et al. (2019). Long-Term (1986–2015) Crop Water Use Characterization over the Upper Rio Grande Basin of United States and Mexico Using Landsat-Based Evapotranspiration. Remote Sensing Journal, 11, pp. 15871611. https://doi.org/10.3390/rs11131587Google Scholar
Sheppard, P., Comrie, A., Packin, G., Angersbach, K., and Hughes, K. (2002). The Climate of the US Southwest. Climate Research 21, 219238.Google Scholar
Stahle, D. W., Cook, E. R., and Burnette, D. J. et al. (2016). The Mexican Drought Atlas: Tree-Ring Reconstructions of the Soil Moisture Balance during the Late Pre-Hispanic, Colonial, and Modern Eras. Quaternary Science Reviews, 149, pp. 3460.Google Scholar
Stearns, C. E. (1953). Tertiary Geology of the Galisteo-Tonque Area, New Mexico. Bulletin of the Geological Society of America, 64, pp. 459508.Google Scholar
Strain, W. S. (1971). Late Cenozoic Bolson Integration in the Chihuahua Tectonic Belt. In Hoffer, J., ed., The Geologic Framework of the Chihuahua Tectonic Belt. Publication 71-59, West Texas Geological Society, pp. 167173.Google Scholar
Texas Water Development Board (TWDB) (2012). 2012 State Water Plan. Available at www.twdb.texas.gov/waterplanning/swp/2012/indGoogle Scholar
Thiros, S., Bexfield, L., Anning, D., and Huntington, J., eds. (2010). Conceptual Understanding and Groundwater Quality of Selected Basin-Fill Aquifers in the Southwestern United States. Professional Paper 1781, Reston, VA: US Geological Survey.Google Scholar
Tipton, R., Mills, E., and Woods, B. et. al. (1942). Pecos River Joint Investigation–Summary, analysis, and findings. Part X, Regional Planning, National Resources Planning Board. Washington, DC: Government Printing Office.Google Scholar
Titus, F. B. (1961). Ground-Water Geology of the Rio Grande Trough in North-Central New Mexico, with Sections on the Jemez Caldera and the Lucero Uplift. In Northrop, S., ed., New Mexico Geological Society 12th Annual Fall Field Conference Guidebook, pp. 186–192.Google Scholar
Trenberth, K. and Branstator, G. (1992). Issues in Establishing Causes of the 1988 Drought over North America. Journal of Climate, 5, 159172.Google Scholar
Umoff, A. A. (2008). An Analysis of the 1944 U.S.–Mexico Water Treaty: Its Past, Present, and Future. Environs, 32, pp. 6998.Google Scholar
Ward, G. H. (2004). Texas Water at the Century’s Turn: Perspectives, Reflections, and a Comfort Bag. In Norwine, J., Giardino, J., and Krishnamurthy, S., eds., Water for Texas. College Station: Texas A&M Press, pp. 1743.Google Scholar
Weiss, J., Castro, C., and Overpeck, J. (2009). Distinguishing Pronounced Droughts in the Southwestern United States: Seasonality and Effects of Warmer Temperatures. Journal of Climate, 22, pp. 59185932.Google Scholar
Wilkins, D. W. (1986). Geohydrology of the Southwest Alluvial Basin’s Regional Aquifer—Systems Analysis, Parts of Colorado, New Mexico, and Texas. Water-Resources Investigations Report 84-4224, Albuquerque, NM: US Geological Survey.Google Scholar
Wilson, B., Lucero, A., Romero, J., and Romero, P. (2003). Water Use by Categories in New Mexico Counties and River Basins, and Irrigated Acreage in 2000. Technical Report 51, Santa Fe: New Mexico Office of the State Engineer.Google Scholar
Wilson, L. (1999). Surface Water Hydrology of the Rio Grande Basin. New Mexico Water Rights Course, Forty-fourth Annual New Mexico Water Conference, Santa Fe, Las Cruces: New Mexico Water Resources Research Institute.Google Scholar
Wozniak, F. E. (1998). Irrigation in the Rio Grande Valley, New Mexico: A study and Annotated Bibliography of the Development of Irrigation Systems. Report RMRS-P-2. Fort Collins, CO: Rocky Mountain Research Station, Forest Service, US Department of Agriculture.Google Scholar
Zachos, J., Pagani, M., Sloan, L., Thomas, E., and Billups, K. (2001). Trends, Rhythms, and Aberrations in Global Climate 65 Ma to Present. Science, 292(5517), pp. 686693.Google Scholar

References

Albiac, J., Esteban, E., Tapia, J., and Rivas, E. (2013). Water Scarcity and Droughts in Spain: Impacts and Policy Measures. In Schwabe, K., Albiac, J., Connor, J., Hassan, R., and Meza, L., eds., Drought in Arid and Semi-Arid Environments: A Multi-Disciplinary and Cross-Country Perspective. Dordrecht: Springer.Google Scholar
Alexandratos, N. and Bruinsma, J. (2012). World Agriculture towards 2030/2050: The 2012 Revision, Global Perspective Studies Team, FAO Agricultural Development Economics Division, ESA Working Paper No. 12-03. Rome: FAO.Google Scholar
Booker, J., Michelsen, A., and Ward, F. (2005). Economic Impacts of Alternative Policy Responses to Prolonged and Severe Drought in the Rio Grande Basin. Water Resources Research, 41, pp. 115.Google Scholar
Booker, J., Howitt, R., Michelsen, A., and Young, R. (2012). Economics and the Modeling of Water Resources and Policies. Natural Resource Modeling, 25(1), pp. 168218.Google Scholar
Calatrava, J. and Garrido, A. (2005). Modelling Water Markets under Uncertain Water Supply. European Review of Agricultural Economics, 32(2), pp. 119142.Google Scholar
Calatrava, J., Guillem, A., and Martinez-Granados, D. (2011). Análisis de alternativas para la eliminación de la sobreexplotación de acuíferos en el Valle del Guadalentín [Analysis of Alternatives for the Elimination of Overexploitation of Aquifers in the Guadalentín Valley]. Journal of Agricultural Economics, 11, pp. 3362.Google Scholar
Comprehensive Assessment of Water Management in Agriculture (CAWMA). (2007). Water for Food Water for Life: A Comprehensive Assessment of Water Management in Agriculture. London: Earthscan-International Water Management Institute.Google Scholar
Confederacion Hidrografica del Jucar [Hydrographic Confederation of the Jucar] (CHJ) (2015). Plan Hidrologico de la Demarcacion Hidrografica del Jucar [Hydrological Plan of the Jucar Hydrographic Demarcation]. Memoria. Ciclo de planificación hidrológica [Memory. Hydrological Planning Cycle] 2015–2021. Valencia: CHJ.Google Scholar
Connor, J. and Kaczan, D., (2013). Principles for Economically Efficient and Environmentally Sustainable Water Markets: The Australian Experience. In Schwabe, K., Albiac, J., Connor, J., Hassan, R., and Meza, L., eds., Drought in Arid and Semi-arid Environments: A Multidisciplinary and Cross-country Perspective. Dordrecht: Springer.Google Scholar
Cornish, G., Bosworth, B., Perry, C., and Burke, J. (2004). Water Charging in Irrigated Agriculture: An Analysis of international Experience. FAO Water Report No. 28. Rome: FAO.Google Scholar
Elliott, J., Deryng, D., Muller, C. et al. (2014). Constraints and Potentials of Future Irrigation Water Availability on Agricultural Production under Climate Change. PNAS, 9, pp. 32393244. https://doi.org/10.1073/pnas.1222474110Google Scholar
Esteban, E. and Albiac, J. (2012). The Problem of Sustainable Groundwater Management: The Case of La Mancha Aquifers, Spain. Hydrogeology Journal, 20, pp. 851863. https://doi.org/10.1007/s10040-012-0853-3Google Scholar
Esteban, E., Dinar, J., Albiac, J. et al. (2016). The Political Economy of Water Policy Design and Implementation in the Jucar Basin, Spain. UCR SPP Working Paper Series WP#16-04. Riverside: University of California.Google Scholar
European Commission (EC) (2007). Communication from the Commission to the European Parliament and the Council, Addressing the Challenge of Water Scarcity and Droughts in the European Union, COM 414/2007. Brussels: European Commission.Google Scholar
Garcia-Molla, M., Sanchis-Ibor, C., Ortega-Reig, M. V., and Avella-Reus, L. (2013). Irrigation Associations Coping with Drought: The Case of Four Irrigation Districts in Eastern Spain. In Schwabe, K., Albiac, J., Connor, J. D., Hassan, R. M., and Gonzalez, L. M., eds., Drought in Arid and Semi-Arid Regions. Dordrecht: Springer.Google Scholar
Garrido, A. and Calatrava, J. (2009). Trends in Water Pricing and Markets. In Garrido, A. and Llamas, M., eds., Water Policy in Spain. Leiden: CRC Press.Google Scholar
Gohar, A. and Ward, F. (2010). Gains from Expanded Irrigation Water Trading in Egypt: An Integrated Basin Approach. Ecological Economics, 69, pp. 25352548.Google Scholar
Grafton, R., Williams, J., Perry, C., Molle, F., Ringler, C. et al. (2018). The Paradox of Irrigation Efficiency. Science, 381(6404), pp. 748750.Google Scholar
Instituto Nacional de Estadística [National Institute of Statistics] (INE) (2014). Cuentas satélites del agua en España [Satellite Water Accounts in Spain]. Madrid: INE.Google Scholar
Instituto Nacional de Estadística [National Institute of Statistics] (INE) (2016). Encuesta sobre el suministro y saneamiento del agua [Survey of Water Supply and Sanitation]. Madrid: INE.Google Scholar
International Groundwater Resources Assessment Center (IGRAC) (2010). Global Groundwater Information System. Delft: IGRAC.Google Scholar
Intergovernmental Panel on Climate Change (IPCC) (2014a). Summary for Policymakers. In Climate Change 2014. In Pachauri, R. and core team, eds., Synthesis Report. Geneva: IPCC.Google Scholar
Intergovernmental Panel on Climate Change (IPCC) (2014b). Summary for Policy Makers. In Field, C., Barros, V., Dokken, D. et al., eds., 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: Cambridge University Press.Google Scholar
Kahil, M. T., Connor, J. D., and Albiac, J. (2015b). Efficient Water Management Policies for Irrigation Adaptation to Climate Change in Southern Europe. Ecological Economics, 120, pp. 226233.Google Scholar
Kahil, M. T., Dinar, A., and Albiac, J. (2015a). Modeling Water Scarcity and Droughts for Policy Adaptation to Climate Change in Arid and Semiarid Regions. Journal of Hydrology, 522, pp. 95109.Google Scholar
Kahil, M. T., Albiac, J., Dinar, A. et al. (2016b). Improving the Performance of Water Policies: Evidence from Drought in Spain. Water, 8(2), p. 34.Google Scholar
Kahil, M. T., Dinar, A., and Albiac, J. (2016a). Cooperative Water Management and Ecosystem Protection under Scarcity and Drought in Arid and Semiarid Regions. Water Resources and Economics, 13, pp. 6074.Google Scholar
Kirby, M., Bark, R., Connor, J., Qureshi, E., and Keyworth, S. (2014). Sustainable Irrigation: How Did Irrigated Agriculture in Australia’s Murray–Darling Basin Adapt in the Millennium Drought? Agricultural Water Management, 145, pp. 154162.Google Scholar
Konikow, L. (2011). Contribution of Global Groundwater Depletion since 1900 to Sea-Level Rise. Geophysical Research Letters, 38. https://doi.org/10.1029/2011GL048604Google Scholar
MARM (2008). Instrucción de Planificación Hidrologica [Hydrological Planning Instruction]. Orden ARM 2656, 38472–38582.Google Scholar
Medellin, J., Howitt, R., and Lund, J. (2013). Modeling Economic-Engineering Responses to Drought: The California Case. In Schwabe, K., Albiac, J., Connor, J., Hassan, R., Meza, L., eds., Drought in Arid and Semi-arid Environments: A Multi-disciplinary and Cross-country Perspective. Dordrecht: Springer.Google Scholar
Ministerio de Medio Ambiente [ Ministry of the Environment] (MIMAM) (2000). Libro blanco del agua en España, Dirección General de Obras Hidráulicas y Calidad de las Aguas [White Paper on Water in Spain, General Directorate of Hydraulic Works and Water Quality]. Secretaría de Estado de Aguas y Costas [Secretary of State for Waters and Coasts]. Madrid: MIMAM.Google Scholar
Ministerio de Medio Ambiente [ Ministry of the Environment] (MIMAM) (2004). Programa A.G.U.A.: Actuaciones para la Gestión y Utilización del Agua [A.G.U.A. Program: Actions for the Management and Use of Water]. Madrid: MIMAM.Google Scholar
Ministerio de Obras Públicas y Transportes [Ministry of Public Works and Transport] (MOPT) (1993). Plan Hidrológico Nacional [National Hydrological Plan]. Memoria y Anteproyecto de Ley [Memorandum and Draft Law]. Madrid: MOPT.Google Scholar
Ministerio para la Transición Ecológica [Ministry for Ecological Transition] (MITECO) (2020). Delimitación de las demarcaciones hidrográficas [Delimitation of Hydrographic Demarcations]. Dirección General del Agua [General Water Management]. MITECO. Madrid.Google Scholar
Montilla-López, N. M., Gutiérrez-Martín, C., and Gómez-Limón, J. A. (2016). Water Banks: What Have We Learnt from the International Experience? Water, 8(10), p. 466.Google Scholar
Moore, M. (1991). The Bureau of Reclamations New Mandate for Irrigation Water Conservation: Purposes and Policy Alternatives. Water Resources Research, 27, pp. 145155.Google Scholar
National Oceanic and Atmospheric Administration (NOAA) (2008). Summary of National Hazard Statistics for 2008 in the United States, National Weather Service. Washington, DC: NOAA.Google Scholar
Organisation for Economic Co-operation and Development (OECD) (2014). Climate Change, Water and Agriculture: Towards Resilient Systems, OECD Studies on Water. Paris: OECD Publishing.Google Scholar
Perez-Martin, M., Batan, A., Del-Amo, P., and Moll, S. (2015). Climate Change Impact on Water Resources and Droughts of AR5 Scenarios in the Jucar River, Spain. In Andreu, J., Solera, A., Paredes, J., Haro, D., and Van Lanen, H., eds., Drought: Research and Science-Policy Interfacing. Leiden: CRC Press/Bakelma.Google Scholar
Perez-Martin, M., Estrela, T., Andreu, J., and Ferrer, J. (2014). Modeling Water Resources and River-Aquifer Interaction in the Júcar River Basin, Spain. Water Resources Management, 28, pp. 43374358.Google Scholar
Playan, E., Lecinia, S., Isidoro, D. et al. (2013). Living with Drought in the Irrigated Agriculture of the Ebro Basin (Spain): Structural and Water Management Actions. In Schwabe, K., Albiac, J., Connor, J. D., Hassan, R. M., and Gonzalez, L. M., eds., Drought in Arid and Semi-Arid Regions. Dordrecht: Springer.Google Scholar
Qureshi, M., Schwabe, K., Connor, J., and Kirby, M. (2010). Environmental Water Incentive Policy and Return Flows. Water Resources Research, 46, pp. 112.Google Scholar
Rausser, G., Swinnen, J., and Zusman, P. (2011). Political Power and Economic Policy. Theory, Analysis and Empirical Applications. New York: Cambridge University Press.Google Scholar
Scheierling, S. and Treguer, D. (2016). Investing in Adaptation: The Challenge of Responding to Water Scarcity in Irrigated Agriculture. Federal Reserve Bank of Kansas City Economic Review, Special Issue 2016.Google Scholar
Scheierling, S., Young, R., and Cardon, G. (2004). Determining the Price Responsiveness of Demands for Irrigation Water Deliveries versus Consumptive Use. Journal of Agricultural and Resource Economics, 29, pp. 328345.Google Scholar
Siebert, S., Henrich, V., Frenken, K., and Burke, J. (2013). Update of the Digital Global Map of Irrigation Areas (GMIA) to Version 5. Institute of Crop Science and Resource Conservation, Bonn: University of Bonn.Google Scholar
United States Department of Agriculture (USDA) (2012). Climate Change and Agriculture in the United States: Effects and Adaptation, Agriculture Research Service, USDA Technical Bulletin 1935. Washington, DC: USDA.Google Scholar
Varela, C. and Hernández, N. (2010). Institutions and Institutional Reform in the Spanish Water Sector: A Historical Perspective. In Garrido, A. and Llamas, R., eds., Water Policy in Spain. Abingdon: CRC Press.Google Scholar
Vörösmarty, C. et al. (2010). Global Threats to Human Water Security and River Biodiversity. Nature, 467, pp. 555561.Google Scholar
Wada, Y. et al. (2010). Global Depletion of Groundwater Resources. Geophysical Research Letters, 37, pp. 15.Google Scholar
Winemiller, K. et al. (2016). Balancing Hydropower and Biodiversity in the Amazon, Congo, and Mekong. Science, 351(6269), pp. 128129.Google Scholar
World Water Assessment Programme (WWAP) (2006). Water: A Shared Responsibility. New York: UNESCO-Berghahn Books.Google Scholar
World Water Council (WWC) (2000). World Water Vision. London: Earthscan.Google Scholar
Zilberman, D., Dunarm, A., MacDougal, N. et al. (2002). Individual and Institutional Responses to the Drought: The Case of California Agriculture. Journal of Contemporary Water Research and Education, 121, pp. 1723.Google Scholar

Save book to Kindle

To save this book to your Kindle, first ensure [email protected] is added to your Approved Personal Document E-mail List under your Personal Document Settings on the Manage Your Content and Devices page of your Amazon account. Then enter the ‘name’ part of your Kindle email address below. Find out more about saving to your Kindle.

Note you can select to save to either the @free.kindle.com or @kindle.com variations. ‘@free.kindle.com’ emails are free but can only be saved to your device when it is connected to wi-fi. ‘@kindle.com’ emails can be delivered even when you are not connected to wi-fi, but note that service fees apply.

Find out more about the Kindle Personal Document Service.

Available formats
×

Save book to Dropbox

To save content items to your account, please confirm that you agree to abide by our usage policies. If this is the first time you use this feature, you will be asked to authorise Cambridge Core to connect with your account. Find out more about saving content to Dropbox.

Available formats
×

Save book to Google Drive

To save content items to your account, please confirm that you agree to abide by our usage policies. If this is the first time you use this feature, you will be asked to authorise Cambridge Core to connect with your account. Find out more about saving content to Google Drive.

Available formats
×