Adamson, D. and Loch, A. (2014). Possible Negative Feedbacks from ‘Gold-Plating’ Irrigation Infrastructure. Agricultural Water Management, 145, pp. 134–144.Google Scholar

Alexandra, J. (2017). Risks, Uncertainty and Climate Confusion in the Murray–Darling Basin Reforms. Water Economics and Policy, 3(3).Google Scholar

Berbel, J., Gutierrez-Martin, C., Rodriguez-Diaz, J. A., Camacho, E., and Montesinos, P. (2014). Literature Review on Rebound Effect of Water Saving Measures and Analysis of a Spanish Case Study. Water Resources Management, 29, pp. 663–678. https://doi.org/10.1007/s11269-014-0839-0Google Scholar

CBHSF (2015). Plano de recursos hídricos da bacia hidrográfica do rio São Francisco [Water Resources Plan for the São Francisco River Basin]. Volume I.Google Scholar

Chao, N., Luo, Z., Wang, Z., and Jin, T. (2017). Retrieving Groundwater Depletion and Drought in the Tigris–Euphrates Basin between 2003 and 2015. Groundwater, 56(5).Google Scholar

Confederacion Hydrografica del Júcar [Hydrographic Confederation of the Jucar] (CHJ) (2014). Memoria-Anejo 10. Programa de medidas. Demarcación Hidrográfica Del Júcar. [Memory-Annex 10. Program of Measures. Júcar River Basin District.Google Scholar

Crase, L. and O’Keefe, S. (2009). The Paradox of National Water Savings: A Critique of ‘Water for the Future’. Agenda: A Journal of Policy Analysis and Reform, 16(1), pp. 45–60.Google Scholar

De Stefano, L., Welch, C., Urquijo, J., and Garrick, D. E. (2018). Groundwater Governance in the Rio Grande: Co-evolution of Local and Intergovernmental Management. Water Alternatives, 11(3), pp. 824–846.Google Scholar

Döll, P. and Siebert, S. (2002) Global Modeling of Irrigation Water Requirements. Water Resources Research, 38(4), p. 1037.CrossRefGoogle Scholar

Esteban, E., Dinar, A., Albiac, A. et al. (2016). The Political Economy of Water Policy Design and Implementation in the Jucar Basin, Spain. UCR SPP Working papers.Google Scholar

Evans, R. (2004). River–Groundwater Interaction in the Murray–Darling Basin: Technical Status and Management Options. In 9th Murray–Darling Basin Groundwater Workshop, Bendigo, 12–19 February.Google Scholar

FAO (Food and Agriculture Organization) (2011). Water Balance in the Nile Basin. Available at www.fao.org/nr/water/faonileGoogle Scholar

Feng, X. et al. (2016). Revegetation in China’s Loess Plateau Is Approaching Sustainable Water Resource Limits. Nature Climate Change. https://doi.org/10.1038/NCLIMATE3092CrossRefGoogle Scholar

Fernald, A. G. and Guldan, S. J. (2006). Surface Water–Groundwater Interactions between Irrigation Ditches, Alluvial Aquifers, and Streams. Reviews in Fisheries Science, 14(1–2), pp. 79–89. https://doi.org/10.1080/10641260500341320Google Scholar

Gleick, P. (2001). Making Every Drop Count. Scientific American, 284(2), pp. 40–45.Google Scholar

González-Cebollada, C. (2015). Water and Energy Consumption after the Modernization of Irrigation in Spain. WIT Transactions on the Built Environment, 168, pp. 457–465.Google Scholar

Grafton, R. Q. (2017). Water Reform and Planning in the Murray–Darling Basin, Australia. Water Economics and Policy, 3(3).Google Scholar

Grafton, R. Q. et al. (2012). Global Insights into Water Resources, Climate Change and Governance. Nature Climate Change. https://doi.org/10.1038/nclimate1746Google Scholar

Grafton, R. Q., Williams, J., Perry, C. J. et al. (2018). Paradox of Irrigation Efficiency and the Global Water Crisis. Science, 361(6404), pp. 748–750.Google Scholar

Grafton, R. Q., Colloff, M. J., Marshall, V., and Williams, J. (2020). Confronting a ‘Post-Truth Water World’ in the Murray–Darling Basin, Australia. Water Alternatives, 13(1), pp. 1–28.Google Scholar

Hancock, G. and Pietsch, T. (2008). Sediment Tracing and Dating Techniques Employed at CSIRO Land and Water. CSIRO Land and Water Science Report, CSIRO.Google Scholar

Horne, J. (2014). The 2012 Murray–Darling Basin Plan: Issues to Watch. International Journal of Water Resources Development, 30(1), pp. 152–163.Google Scholar

Hu, Q., Yang, Y., Han, S. et al. (2017). Identifying Changes in Irrigation Return Flow with Gradually Intensified Water-Saving Technology Using HYDRUS for Regional Water Resources Management. Agricultural Water Management, 194, pp. 33–47.Google Scholar

Huffaker, R. and Whittlesey, N. (2003). A Theoretical Analysis of Economic Incentive Policies Encouraging Agricultural Water Conservation. Water Resource Development, 19(1), pp. 37–53.Google Scholar

Huffaker, R., Whittlesey, N., and Hamilton, J. R. (2000). The Role of Prior Appropriation in Allocating Water Resources into the 21st Century. Water Resource Development, 16(2), pp. 265–273.Google Scholar

Kendy, E., Molden, D. J., Steenhuis, T. S., Liu, C. M., and Wang, J. (2003). Policies Drain the North China Plain: Agricultural Policy and Groundwater Depletion in Luancheng County, 1949–2000. Research Report 71. Colombo: International Water Management Institute.Google Scholar

Kucukmehmetoglu, M. and Geymen, A. (2014). Transboundary Water Resources Allocation under Various Parametric Conditions: The Case of the Euphrates & Tigris River Basin. Water Resources Management, 28, pp. 3515–3538.Google Scholar

Maganda, C. (2005). Collateral Damage: How the San Diego-Imperial Valley Water Agreement Affects the Mexican Side of the Border. The Journal of Environment & Development, 14(4), pp. 486–506.CrossRefGoogle Scholar

MDBA (2010). Guide to the Proposed Basin Plan.Google Scholar

MDBA (2016). The Murray–Darling Basin at a Glance.Google Scholar

Meng, F., Su, F., Yang, D., Tong, K., and Hao, Z. (2016). Impacts of Recent Climate Change on the Hydrology in the Source Region of the Yellow River Basin. Journal of Hydrology: Regional Studies, 6, pp. 66–81.Google Scholar

Molden, D., Oweis, T., Steduto, P. et al. (2010). Improving Agricultural Water Productivity: Between Optimism and Caution. Agricultural Water Management, 97, pp. 528–535.Google Scholar

Molle, F. (2008). Why Enough Is Never Enough: The Societal Determinants of River Basin Closure. International Journal of Water Resource Development, 24(2), pp. 247–256.Google Scholar

Molle, F. and Closas, A. (2020). Groundwater Management and the Pitfalls of Licensing. Journal of Hydrogeology.Google Scholar

Molle, F. and Sanchis-Ibor, C. (2019). Irrigation Policies in the Mediterranean: Trends and Challenges. In Molle, F., Sanchis-Ibor, C., and Avella, L., eds., Irrigation in the Mediterranean: Technologies, Institutions and Policies. Global Issues in Water Policy Series. Dordrecht: Springer.Google Scholar

Molle, F. and Wester, P. (2009). River Basin Trajectories: An Inquiry into Changing Waterscapes. In Molle, F. and Wester, P., eds., River Basins Trajectories: Societies, Environments and Development. Wallingford and Cambridge, MA: CABI, pp. 1–19.Google Scholar

Molle, F., Wester, P., and Hirsch, P. (2010). River Basin Closure: Processes, Implications, and Responses. Agricultural Water Management, 97, pp. 569–577.Google Scholar

Molle, F., Wester, P., and Mollinga, P. P. (2009). Hydraulic Bureaucracies: Flows of Water, Flows of Power. Water Alternatives, 2(3), pp. 328–349. Available at www.water-alternatives.orgGoogle Scholar

Molle, F., Gafaar, I., Al-Agha, D. E., and Rap, E. (2018). The Nile Delta’s Water and Salt Balances and Implications for Management. Agricultural Water Management, 197(15), pp. 110–121.Google Scholar

Ortega-Reig, M., Sanchis-Ibor, C., and Garcia-Molla, M. (2017). Drip Irrigation in Eastern Spain. Diverging Goals in a Converging Process. In Venot, J. P., Kuper, M., and Zwareveen, M., eds., Drip Irrigation for Agriculture: Untold Stories of Efficiency, Innovation and Development. Abingdon: Earthscan from Routledge.Google Scholar

Pereira, L. S., Goncalves, J. M., Dong, B., Mao, Z., and Fang, S. X. (2007). Assessing Basin Irrigation and Scheduling Strategies for Saving Irrigation Water and Controlling Salinity in the Upper Yellow River Basin, China. Agricultural Water Management, 93(3), pp. 109–122.Google Scholar

Perez-Martin, M. A., 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-Arquiola, J., Haro-Monteagudo, D., and Van Lanen, H., eds., Drought: Research and Science-Policy Interfacing. London: CRC Press, pp. 189–196.Google Scholar

Perry, C. and Steduto, P. (2017). Does Improved Irrigation Technology Save Water. Cairo: FAO.Google Scholar

Pittock, J., Williams, J., and Grafton, R. Q. (2015). The Murray–Darling Basin Plan Fails to Deal Adequately with Climate Change. Water: Journal of the Australian Water Association, 42(6), p. 28.Google Scholar

Playán, E. and Mateos, L. (2006). Modernization and Optimization of Irrigation Systems to Increase Water Productivity. Agricultural Water Management, 80(1–3), pp. 100–116.Google Scholar

Postel, S. (1997). Last Oasis: Facing Water Scarcity. New York: World Watch Institute.Google Scholar

Rahi, K. A. (2018). Salinity Management in the Shatt Al-Arab River. International Journal of Engineering & Technology, 7(4.20), pp. 128–133.Google Scholar

Reisner, M. (1986). Cadillac Desert: The American West and Its Disappearing Water. New York: Penguin Books.Google Scholar

Richter, B. D. et al. (2017). Opportunities for Saving and Reallocating Agricultural Water to Alleviate Water Scarcity. Water Policy, 19, pp. 886–907.Google Scholar

Sabadini-Santos, E., Knoppers, B. A., Padua Oliveira, E., and Leipe, T. (2009). Regional Geochemical Baselines for Sedimentary Metals of the Tropical São Francisco Estuary, NE-Brazil. Marine Pollution Bulletin, 58, pp. 601–634. https://doi.org/10.1016/j.marpolbul.2009.01.011Google Scholar

Sanchis-Ibor, C., Garcia-Molla, M., and Avella-Reus, L. (2017a). Effects of Drip Irrigation Promotion Policies on Water Use and Irrigation Costs in Valencia, Spain. Water Policy, 19(1), pp. 165–180.Google Scholar

Sanchis-Ibor, C., Macian-Sorribes, H., Garcia-Molla, M., and Pulido-Velazquez, M. (2015). Effects of Drip Irrigation on Water Consumption at Basin Scale (Mijares River, Spain). 26th Euro-mediterranean Regional Conference and Workshops: Innovate to Improve Irrigation performances, Montpellier, France.Google Scholar

Sanchis-Ibor, C. et al. (2019). Spain. In Molle, F., Sanchis-Ibor, C., and Avella, L., eds., Irrigation in the Mediterranean: Technologies, Institutions and Policies. Global Issues in Water Policy Series. Dordrecht: Springer.Google Scholar

Sese-Minguez, S., Boesveld, H., Asisns-Velis, S., van der Kooij, S., and Maroulis, J. (2017). Transformations Accompanying a Shift from Surface to Drip Irrigation in the Semi-arid Cànyoles Watershed, Valencia, Spain. Water Alternatives, 10(1).Google Scholar

Shiklomanov, I. A., ed. (1997). Assessment of Water Resources and Water Availability in the World, Comprehensive Assessment of the Freshwater Resources of the World. Stockholm: Stockholm Environment Institute.Google Scholar

Soto-Garcia, M., Martinez-Alvarez, V., Garcia-Bastida, P. A., Alcon, F., and Martin-Gorriz, B. (2013). Effect of Water Scarcity and Modernisation on the Performance of Irrigation Districts in South-Eastern Spain. Agricultural Water Management, 124, pp. 11–19.Google Scholar

Tanouti, O. and Molle, F. (2013). Réappropriations de l’eau dans les bassins versants surexploités: le cas du bassin du Tensift (Maroc) [Reappropriation of Water in Overexploited Watersheds: The Case of the Tensift Basin (Morocco)]. Etudes Rurales [Rural Studies], 192(2), pp. 79–96.CrossRefGoogle Scholar

Voss, K. A., Famiglietti, J. S., Lo, M. et al. (2013). Groundwater Depletion in the Middle East from GRACE with Implications for Transboundary Water Management in the Tigris–Euphrates–Western Iran Region. Water Resources Research, 49. https://doi.org/10.1002/wrcr.20078Google Scholar

Wang, Q. J., Walker, G., and Horne, A. (2018). Potential Impacts of Groundwater Sustainable Diversion Limits and Irrigation Efficiency Projects on River Flow Volume under the Murray–Darling Basin Plan. An Independent Review. Melbourne School of Engineering.Google Scholar

Ward, F. and Pulido-Velázquez, M. (2008). Water Conservation in Irrigation Can Increase Water Use. PNAS, 105, pp. 18215–18220.Google Scholar

Willardson, L. S., Allen, R. G., and Fredericksen, H. D. (1994). Elimination of Irrigation Efficiencies. 13th Tech. Conference USCID, Denver, CO.Google Scholar

Wittwer, G. and Dixon, J.(2013). Effective Use of Public Funding in the Murray–Darling Basin: A Comparison of Buybacks and Infrastructure Upgrades. Australian Journal of Agricultural and Resource Economics, 57(3), pp. 399–421.Google Scholar

World Bank (2015). Project Performance Assessment Report Peopleʼs Republic of China Irrigated Agriculture Intensification Project. Mainstreaming Climate Change Adaptation in Irrigated Agriculture Project. Hai Basin Integrated Water and Environment Management Project. IEG Public Sector Evaluation, Independent Evaluation Group.Google Scholar

Worster, D. (1985). Rivers of Empire. Water, Aridity, and the Growth of the American West. New York: Panthenon Books.Google Scholar

WWF/Adena (2015). Modernización de Regadíos: Un mal negocio para la naturaleza y la sociedad [Irrigation Modernization: A Bad Business for Nature and Society]. Madrid: WWF/Adena. Available at http://awsassets.wwf.es/downloads/modernizacion_regadios.pdfGoogle Scholar

Yan, N., Wu, B., Perry, C., and Zeng, H. (2015). Assessing Potential Water Savings in Agriculture on the Hai Basin Plain, China. Agricultural Water Management, 154, pp. 11–19.CrossRefGoogle Scholar

Yang, H. and Jia, S. (2008). Meeting the Basin Closure of the Yellow River in China. Water Resources Development, 24(2), pp. 265–274.CrossRefGoogle Scholar

Young, W. J. and Chiew, F. H. S. (2011). Climate Change in the Murray–Darling Basin: Implications for Water Use and Environmental Consequences. In Grafton, R. Q. and Hussey, K., eds., Water Resources Planning and Management. Cambridge: Cambridge University Press.Google Scholar

Yu, Y., Wang, H., Shi, X. et al. (2013). New Discharge Regime of the Huanghe (Yellow River): Causes and Implications. Continental Shelf Research, 69, pp. 62–72.Google Scholar

Zhang, H.. Singh, V. P., Sun, D., Yu, Q., and Cao, W. (2017). Has Water-Saving Irrigation Recovered Groundwater in the Hebei Province Plains of China? International Journal of Water Resources Development, 33(4), pp. 534–552.Google Scholar

Zhong, K., Sun, L., Fischer, G. et al. (2017). Mission Impossible? Maintaining Regional Grain Production Level and Recovering Local Groundwater Table by Cropping System Adaptation across the North China Plain. Agricultural Water Management, 193, pp. 1–12.Google Scholar

Abu-Zeid, M. (1983). The River Nile: Main Water Transfer Projects in Egypt and Impacts on Egyptian Agriculture. In Biswas, A. K., Zuo, D., Nickum, J. E., and Liu, C., eds., Long-Distance Water Transfer: A Chinese Case Study and International Experiences. United Nations University.Google Scholar

Aguirre, C. and Drinot, P. (2017). The Peculiar Revolution: Rethinking the Peruvian Experiment under Military Rule. Paperback. Austin: University of Texas Press, p. 353.Google Scholar

Azevedo, L. G. T. de, Porto, R. L. L., Mello, A. V. Jr et al. (2005). Inter-Basin Water Transfers. World Bank – Water Series, 7, p. 93.Google Scholar

Ballestero, E. (2004). Inter-Basin Water Transfer Public Agreements: A Decision Approach to Quantity and Price. Water Resources Management, 18, pp. 75–88.CrossRefGoogle Scholar

Beijing Qingnianbao [Beijing Youth News] (2017). Caofeidian baiwan dun danhua haishui jiang jinjing [曹妃甸百万吨淡化海水将进京 (Caofeidian Will Provide a Million Tonnes of Desalinated Seawater to Beijing)]. Available at www.bj.xinhuanet.com/bjyw/2017-12/08/c_1122079691.htmGoogle Scholar

Biswas, A. K., Liu, C., Zuo, D., and Nickum, J. E. (1983). Long-Distance Water Transfer: A Chinese Case Study and International Experiences. United Nations University, p. 432.Google Scholar

Casana, A. C. (2005). Rationalize the Use of Water Demand: Chavimochic Project. Available at www.laindustria.com/satelliteGoogle Scholar

Cox, William E. (1999). Determining when Interbasin Water Transfer Is Justified: Criteria for Evaluation. In Inter-basin Water Transfer: Looking for Solutions for the Future, Technical Documents in Hydrology Vol. 28. Paris: UNESCO.Google Scholar

Donia, N. S. (2012). Development of El-Salam Canal Automation System. Journal of Water Resource and Protection, 4, pp. 597–604. https://doi.org/10.4236/jwarp.2012.48069Google Scholar

Ghassemi, F. and White, I. (2007). Inter-Basin Water Transfer: Case Studies from Australia, United States, Canada, China, and India. Cambridge: Cambridge University Press, pp. 1–463.Google Scholar

Gichuki, F. and McCornick, P. G. (2008). International Experiences of Water Tranfers: Relevance to India. In Amarasinghe, U. A. and Sharma, B. R., eds., Strategic Analyses of the National River Linking Project (NRLP) of India - Proceedings of the Workshop on Analyses of Hydrological, Social and Ecological Issues of the NRLP, pp. 345–371.Google Scholar

Hafez, A. (2005). Investigation of El-Salam Canal Project in Northern Sinai, Egypt – Phase I: Environmental Baseline, Soil and Water Quality Studies. Proceedings of the Ninth International Water Technology Conference, Sharm El-Sheikh, Egypt: IWTC9 2005, pp. 953–970.Google Scholar

Jia, S. and Liu, J. (2014). Daguo Shuiqing: Zhongguo Shui Wenti Baogao [The Water Regime of a Large Country: A Report On China’s Water Problems]. Wuhan: Huazhong Keji Daxue chubanshe.Google Scholar

Kuo, L. (2014). China Is Moving More than a River Thames of Water across the Country to Deal with Water Scarcity, Quartz. Available at qz.com/158815/chinas-so-bad-at-water-conservation-that-it-had-to-launch-the-most-impressive-water-pipeline-project-ever-builtGoogle Scholar

Lund, J. R. and Israel, M. (1995). Water Transfers in Water Resources Systems. 1–16. Available at https://watershed.ucdavis.edu/shed/lund/ftp/Transfers.docGoogle Scholar

Lynch, B. (2013). River of Contention: Scarcity Discourse and Water Competition in Highland Peru. Georgia Journal of International and Comparative Law, 42, pp. 69–92.Google Scholar

Magalhães, A. R. and Martins, E. S. P. R. (2019). The Case of the São Francisco River. In Engineered Rivers in Arid Lands: Searching for Sustainability in Theory and Practice. Philadelphia: CRC.Google Scholar

MWRI of Egypt (2003). North Sinai Development Project: The Project Achievements.Google Scholar

National Academy Press (2017). Water Conservation, Reuse, and Recycling, p. 293. https://doi.org/10.17226/11241Google Scholar

Quosy, D. E. (2005). Agricultural Development in Egypt across Two Millenniums. Virtual Global Super Project Conference, 2001: World Development Federation. Available at www.wdf.org/gspcGoogle Scholar

Roman, P. (2017). The São Francisco Interbasin Water Transfer in Brazil: Tribulations of a Megaproject through Constraints and Controversy. Water Alternatives, 10(2), pp. 395–419.Google Scholar

UNESCO (1999). Interbasin Water Transfer: Looking for Solutions for the Future. Proceedings of the International Workshop, Technical Documents in Hydrology Vol. 28, Paris.Google Scholar

USAID (2011). Peru Climate Change Vulnerability and Adaptation Desktop Study, p. 72.Google Scholar

USDI (2004). Bureau of Reclamation. Colorado – Big Thompson Project. Available at www.usbr.gov/dataweb.htmlGoogle Scholar

Wang, J. and Liu, Y. (1983). An Investigation of the Water Quality and Pollution in the Rivers of the Proposed Water Transfer Region. In Biswas et al., Long-Distance Water Transfer, pp. 361–371.Google Scholar

Wang, K. and Zhang, A. (2018). Climate Change, Natural Disasters, and Adaptation Investments: Inter- and Intra-port Competition and Cooperation. Transportation Research Part B: Methodological, 117, pp. 158–189. https://doi.org/10.1016/j.trb.2018.08.003Google Scholar

World Commission on Dams (2000). Dams and Development, A New Framework for Decision Making.CrossRefGoogle Scholar

WWF (2007). Pipedreams? Interbasin Water Transfers and Water Shortages. Global Freshwater Programme, WWF, p. 49.Google Scholar

Yang, H. and Zehnder, A. J. B. (2005). The South-North Water Transfer Project in China: An Analysis of Water Demand Uncertainty and Environmental Objectives In Decision Making. Water International, 30(3), pp. 339–349.Google Scholar

Yao, B. and Chen, Q. (1983). South-North Water Transfer Project plans. In Biswas et al., Long-Distance Water Transfer, pp. 127–149.Google Scholar

Zimbelman, D. D. and Werner, B. R. (2001). Water Management in the Northern Colorado Water Conservation District. In Schaack, J. and Anderson, S. S., eds., Transbasin Water Transfers. Proceedings of the 2001 USCID Water Management Conference, Denver, Colorado, 27–30 June 2001. Denver, CO: US Committee on Irrigation and Drainage, pp. 331–339.Google Scholar

Anatolian Agency (2019). GAP kapsamındaki illerde içme suyu problemine son [An End to the Drinking Water Problem in the Provinces Covered by the GAP]. Available at www.aa.com.tr/tr/turkiye/gap-kapsamindaki-illerde-icme-suyu-problemine-son/1549063Google Scholar

Carter, K. et al. (2018). Stakeholder Engagement. In Sustainable River Management on the US–Mexico Border. Policy Research Project Report, Number 202. LBJ School of Public Affairs, University of Texas at Austin.Google Scholar

Centro de Estudios del Medio Ambiente, Universidad Autónoma de Cd. Juárez [Center for Environmental Studies, Autonomous University of Cd. Juárez] (2000). Planeación del Recurso Agua: Comparación de Planes de Administración del Agua en Cd. Juárez, Chihuahua [Water Resource Planning: Comparison of Water Management Plans in Cd. Juárez, Chihuahua].Google Scholar

Delipinar, S. and Karpuzcu, M. (2017). Policy, Legislative and Institutional Assessments for Integrated River Basin Management in Turkey. Environmental Science & Policy, 72, pp. 20–29.Google Scholar

Dixon, S., Moreno, E. R., and Sadozai, A. (2015). Syrian Civil Society and the Swiss Humanitarian Community. Geneva: The Graduate Institute Geneva. Available at https://docs.water-security.org/document/syrian-civil-society-and-the-swiss-humanitarian-communityGoogle Scholar

Divrak, B. B. and Demirayak, F. (2011). NGOs Promote Integrated River Basin Management in Turkey: A Case-Study of the Konya Closed Basin. In Kibaroglu, A., Scheumann, W., and Kramer, A., eds., Turkey’s Water Policy: National Frameworks and International. Verlag Berlin Heidelberg: Springer.Google Scholar

Draper, M. (2014). Envisioning the Farms of the Future: In Pursuit of Sustainable Agriculture in the Rio Grande Valley. University of New Mexico Digital Repository Online. Available at http://digitalrepository.unm.edu/cgi/viewcontent.cgi?article =1006&context=ltam.etdsGoogle Scholar

El Paso Water Utility (2018). Conservation. Available at www.epwater.org/conservationGoogle Scholar

ESCWA (2003). Sectoral Water Allocation Policies in Selected ESCWA Member Countries, An Evaluation of the Economic, Social and Drought Related Impact. New York: United Nations.Google Scholar

ETIC (2019). Available at https://euphratestigrisinitiativeforcooperation.wordpress.com/Google Scholar

European Commission (2000). Water Framework Directive (2000/60/EC). Official Journal, 22 December 2000.Google Scholar

European Parliament and The Council of the European Union (2000). Directive 2000/60/EC of the European Parliament and of the Council of 23 October 2000 Establishing a Framework for Community Action in the Field of Water Policy. Official Journal of the European Communities. L327, 22.12.2000.Google Scholar

FAO (2008). Water Reports 34, Irrigation in the Middle East Region in Figures, Aquastat Survey.Google Scholar

International Boundary and Water Commission (IBWC) (2018). About the Rio Grande. Available at https://ibwc/CRP/riogrande.htmGoogle Scholar

Khalaf, R. (2015) Governance without Government in Syria: Civil Society and State Building during Conflict. St Andrews University: Syria Studies Journal.Google Scholar

Kibaroglu, A. (2002). Building a Regime for the Waters of the Euphrates–Tigris River Basin. London, The Hague, New York: Kluwer Law International.Google Scholar

Kibaroglu, A. (2020). The Role of Irrigation Associations and Privatization Policies in Irrigation Management in Turkey. Water International, pp. 1–8.Google 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(2), pp. 279–307.Google Scholar

Kibaroglu, A. and Schmandt, J. (2016). Sustainability of Engineered Rivers in Arid Lands: Euphrates–Tigris and Rio Grande/Brávo. Policy Research Project Report, Number 190. LBJ School of Public Affairs, University of Texas at Austin.Google Scholar

Kuczmanski, L. (2018) Public Affairs Officer, IBWC/US Section. Phone interview. Available at www.ibwc.gov/Citizens_Forums/citizens_forums.htmlGoogle Scholar

LBJ School of Public Affairs (2000). Water Planning Initiatives in the Paso del Norte: A Review of El Paso, Las Cruces, Doña Ana County and Far West Texas Planning Region.Google Scholar

LBJ School of Public Affairs (2001). Water Planning in the Paso del Norte: Toward Regional Coordination.Google Scholar

Nava, L. (2020). The Transboundary Paso del Norte Region: Stakeholders’ Preferences Allowing Water Resource Adaptation. Available at www.springerprofessional.de/en/the-transboundary-paso-del-norte-region/16802426Google Scholar

Neto, S. (2017). The OECD Principles on Water Governance. Water International, Special Issue, 43(1).Google Scholar

Organization for Economic Cooperation and Development (OECD) (2015). Stakeholder Engagement for Inclusive Water Governance. OECD Studies on Water. Paris: OECD PublishingGoogle Scholar

Saade-Sbeih, M. et al. (2016). Post Conflict Water Management: Learning from the Past for Recovery Planning in the Orontes River Basin. Proceedings of the International Association of Hydrological Sciences, 374, pp. 17–21.Google Scholar

Stolp, C. and Schmandt, J. (2018). Sustainable River Management on the US/Mexico Border: Recommendations for the Paso del Norte. Policy Research Project Report, Number 202. LBJ School of Public Affairs, University of Texas at Austin.Google Scholar

Stockholm International Water Management Institute-SIWI (2006). Beyond the River, Sharing Benefits and Responsibilities: Final Programme. World Water Week. Available at www.yumpu.com/en/document/read/24632793/final-programme-beyond-the-river-world-water-weekGoogle Scholar

Svoboda, E. and Pantuliano, S. (2015). International and Local/Diaspora Actors in the Syria Response: A Diverging Set of Systems? Humanitarian Policy Group (HPG) Working Paper. Overseas Development Institute.Google Scholar

Texas Water Development Board (TWDB) (2018). Historical Water Use Estimates. Available at www.twdb.texas.gov/waterplanning/waterusesurvey/estimates/index.aspGoogle Scholar

Turner, C., Hamlyn, E., and Ibanez, O. (2018). The Challenge of Balancing Water Supply and Demand in the Paso del Norte.Google Scholar

UN Environment (2018). Progress on Integrated Water Resources Management. Global Baseline for SDG 6 Indicator 6.5.1: Degree of IWRM Implementation.Google Scholar