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19 - Managing and Mitigating Hydrologic Systems

from Part VI - Water

Published online by Cambridge University Press:  05 July 2018

Chadwick Dearing Oliver  and
Fatma Arf Oliver
Chadwick Dearing Oliver
Affiliation:
Yale University, Connecticut
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Summary

Sometimes hydrologic systems have been altered with unintended consequences. Agriculture and city drains have sent water to oceans without recharging the groundwater, thus allowing salt water intrusion into coastal aquifers. Large dams often block fish migrations, although fish ladders offer partial solutions; large dams also catch sediment and release sediment-free water which can scour and lower downstream alluvial floodplains. River diversions and irrigation systems sometimes take fish into irrigation ditches unless appropriate guards are installed. Watersheds not managed to protect erosion can cause a reservoir to fill with silt. All above consequences can be partially mitigated, although tradeoffs are incurred. Water shortages are mitigated by conserving water through efficient use; by recycling and treating/reusing water; and by obtaining more water sustainably. Rainwater rooftop harvesting is common in some places; artificial glaciers and tapping glacial lakes can provide water in mountain regions; and desalinization is becoming efficient. Water is occasionally shipped in pipelines. If fossil fuels become less used, some oil pipeline may be used to ship water instead.
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Global Resources and the Environment , pp. 298 - 310
Publisher: Cambridge University Press
Print publication year: 2018

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References

Micklin, P.. The Aral Sea Disaster. Annual Review of Earth and Planetary Sciences. 2007;35:4772.CrossRefGoogle Scholar
Nunn, J. A.. Seasonal Groundwater Withdrawal in Southwestern Louisiana: Implications for Land Subsidence and Resource Management. Gulf Coast Association of Geological Societies Transactions. 2010;60:515–24.Google Scholar
Simon, J. L.. The Ultimate Resource 2. (Princeton University Press, 1998).Google Scholar
Barten, P. K., Jones, J. A., Achterman, G. L., et al. Hydrologic Effects of a Changing Forest Landscape. (National Research Council of the National Academies of Science, USA, 2008).Google Scholar
Sun, H., Grandstaff, D., Shagam, R.. Land Subsidence Due to Groundwater Withdrawal: Potential Damage of Subsidence and Sea Level Rise in Southern New Jersey, USA. Environmental Geology. 1999;37(4):290–6.CrossRefGoogle Scholar
Postel, S., Richter, B.. Rivers for Life: Managing Water for People and Nature. (Island Press, 2012).Google Scholar
Adamo, N., Al-Ansari, N.. Mosul Dam Full Story: Safety Evaluations of Mosul Dam. Journal of Earth Sciences and Geotechnical Engineering. 2016;6(3):185212.Google Scholar
Nickson, R., McArthur, J., Burgess, W., et al. Arsenic Poisoning of Bangladesh Groundwater. Nature. 1998;395(6700):338–.CrossRefGoogle ScholarPubMed
Craig, J. R., Vaughan, D. J., Skinner, B. J.. Resources of the Earth: Origin, Use, and Environmental Impacts, fourth edition. (Prentice Hall, 2011).Google Scholar
Batu, V.. Aquifer Hydraulics: A Comprehensive Guide to Hydrogeologic Data Analysis. (John Wiley & Sons, 1998).Google Scholar
Brozović, N., Sunding, D., Zilberman, D.. Optimal Management of Groundwater over Space and Time. Frontiers in Water Resource Economics. (Springer, 2006), pp. 109–35.Google Scholar
Konikow, L. F., Kendy, E.. Groundwater Depletion: A Global Problem. Hydrogeology Journal. 2005;13(1):317–20.CrossRefGoogle Scholar
Wada, Y., van Beek, L. P., van Kempen, C. M., et al. Global Depletion of Groundwater Resources. Geophysical Research Letters. 2010;37(20).CrossRefGoogle Scholar
Rockström, J., Falkenmark, M., Allan, T., et al. The Unfolding Water Drama in the Anthropocene: Towards a Resilience‐Based Perspective on Water for Global Sustainability. Ecohydrology. 2014;7(5):1249–61.CrossRefGoogle Scholar
Shrestha, R. R., Shrestha, M. P., Upadhyay, N. P., et al. Groundwater Arsenic Contamination, Its Health Impact and Mitigation Program in Nepal. Journal of Environmental Science and Health, Part A. 2003;38(1):185200.CrossRefGoogle ScholarPubMed
McCully, P.. Silenced Rivers: The Ecology and Politics of Large Dams. (Zed Books, 2001).Google Scholar
Brismar, A.. River Systems as Providers of Goods and Services: A Basis for Comparing Desired and Undesired Effects of Large Dam Projects. Environmental Management. 2002;29(5):598609.CrossRefGoogle ScholarPubMed
Trussell, D., editor. The Social and Environmental Effects of Large Dams. (Pergamon, 1992).Google Scholar
Goldsmith, E., Hildyard, N.. The Social and Environmental Effects of Large Dams. Volume 2: Case Studies. (Wadebridge Ecological Centre, 1986).Google Scholar
World Commission on Dams. Dams and Development: A New Framework for Decision-Making: The Report of the World Commission on Dams. (Earthscan, 2000).Google Scholar
White, G. F.. The Environmental Effects of the High Dam at Aswan. Environment: Science and Policy for Sustainable Development. 1988;30(7):440.Google Scholar
Rosenberg, D. M., McCully, P., Pringle, C. M.. Global-Scale Environmental Effects of Hydrological Alterations: Introduction. BioScience. 2000;50(9):746–51.CrossRefGoogle Scholar
Čada, G., Loar, J., Garrison, L., Fisher, R. Jr., Neitzel, D.. Efforts to Reduce Mortality to Hydroelectric Turbine-Passed Fish: Locating and Quantifying Damaging Shear Stresses. Environmental Management. 2006;37(6):898906.CrossRefGoogle ScholarPubMed
Čada, G. F.. The Development of Advanced Hydroelectric Turbines to Improve Fish Passage Survival. Fisheries. 2001;26(9):1423.2.0.CO;2>CrossRefGoogle Scholar
Katopodis, C.. Developing a Toolkit for Fish Passage, Ecological Flow Management and Fish Habitat Works. Journal of Hydraulic Research. 2005;43(5):451–67.CrossRefGoogle Scholar
Poff, N. L., Hart, D. D.. How Dams Vary and Why It Matters for the Emerging Science of Dam Removal. BioScience. 2002;52(8):659–68.CrossRefGoogle Scholar
Richter, B. D., Thomas, G. A.. Restoring Environmental Flows by Modifying Dam Operations. Ecology and Society. 2007;12(1):12.CrossRefGoogle Scholar
Richter, B. D., Postel, S., Revenga, C., et al. Lost in Development’s Shadow: The Downstream Human Consequences of Dams. Water Alternatives. 2010;3(2):14.Google Scholar
Clarke, S. J., Bruce‐Burgess, L., Wharton, G.. Linking Form and Function: Towards an Eco‐Hydromorphic Approach to Sustainable River Restoration. Aquatic Conservation: Marine and Freshwater Ecosystems. 2003;13(5):439–50.CrossRefGoogle Scholar
Stanley, E. H., Doyle, M. W.. Trading Off: The Ecological Effects of Dam Removal. Frontiers in Ecology and the Environment. 2003;1(1):1522.CrossRefGoogle Scholar
Gleick, P. H.. Global Freshwater Resources: Soft-Path Solutions for the 21st Century. Science. 2003;302(5650):1524–8.CrossRefGoogle Scholar
Council, N. R.. New Strategies for America’s Watersheds. (National Academies Press, 1999).Google Scholar
Ice, G. G., Neary, D. G., Adams, P. W.. Effects of Wildfire on Soils and Watershed Processes. Journal of Forestry. 2004;102(6):1620.Google Scholar
Bowonder, B., Ramana, K., Rao, T. H.. Management of Watersheds and Water Resources Planning. Water International. 1985;10(3):121–31.CrossRefGoogle Scholar
Harmon, R. S.. An Introduction to the Panama Canal Watershed. in The Río Chagres, Panama. (Springer, 2005): pp. 1928.CrossRefGoogle Scholar
Gale, S. B., Zale, A. V., Clancy, C. G.. Effectiveness of Fish Screens to Prevent Entrainment of Westslope Cutthroat Trout into Irrigation Canals. North American Journal of Fisheries Management. 2008;28(5):1541–53.CrossRefGoogle Scholar
Richter, B. D., Mathews, R., Harrison, D. L., Wigington, R.. Ecologically Sustainable Water Management: Managing River Flows for Ecological Integrity. Ecological Applications. 2003;13(1):206–24.CrossRefGoogle Scholar
Howell, T. A.. Enhancing Water Use Efficiency in Irrigated Agriculture. Agronomy Journal. 2001;93(2):281–9.CrossRefGoogle Scholar
Swamee, P. K., Mishra, G. C., Chahar, B. R.. Design of Minimum Water-Loss Canal Sections. Journal of Hydraulic Research. 2002;40(2):215–20.CrossRefGoogle Scholar
Ruijs, A.. Welfare and Distribution Effects of Water Pricing Policies. Environmental and Resource Economics. 2009;43(2):161–82.CrossRefGoogle Scholar
Wallace, J.. Increasing Agricultural Water Use Efficiency to Meet Future Food Production. Agriculture, Ecosystems & Environment. 2000;82(1):105–19.CrossRefGoogle Scholar
Thorin, E., Sandberg, J., Yan., J. Combined Heat and Power. Handbook of Clean Energy Systems. 2015.CrossRefGoogle Scholar
Haarhoff, J., Van der Merwe, B.. Twenty-Five Years of Wastewater Reclamation in Windhoek, Namibia. Water Science and Technology. 1996;33(10):2535.CrossRefGoogle Scholar
Pedrero, F., Kalavrouziotis, I., Alarcón, J. J., Koukoulakis, P., Asano, T.. Use of Treated Municipal Wastewater in Irrigated Agriculture – Review of Some Practices in Spain and Greece. Agricultural Water Management. 2010;97(9):1233–41.CrossRefGoogle Scholar
Hermanowicz, S. W., Asano, T.. Abel Wolman’s “the Metabolism of Cities” Revisited: A Case for Water Recycling and Reuse. Water Science and Technology. 1999;40(4):2936.CrossRefGoogle Scholar
Meera, V., Ahammed, M. M.. Water Quality of Rooftop Rainwater Harvesting Systems: A Review. Journal of Water Supply: Research and Technology-AQUA. 2006;55(4):257–68.CrossRefGoogle Scholar
Freeberne, M.. Glacial Meltwater Resources in China. The Geographical Journal. 1965;131(1):5760.CrossRefGoogle Scholar
Norphel, C., editor. Artificial Glacier: A High Altitude Cold Desert Water Conservation Technique. In Defense of Liberty Conference Proceedings. (New Delhi: Defense of Liberty Conference, 2012).Google Scholar
Carey, M., Huggel, C., Bury, J., Portocarrero, C., Haeberli, W.. An Integrated Socio-Environmental Framework for Glacier Hazard Management and Climate Change Adaptation: Lessons from Lake 513, Cordillera Blanca, Peru. Climatic Change. 2012;112(3–4):733–67.CrossRefGoogle Scholar
Reynolds, J. M., Dolecki, A., Portocarrero, C.. The Construction of a Drainage Tunnel as Part of Glacial Lake Hazard Mitigation at Hualcán, Cordillera Blanca, Peru. Geological Society, London, Engineering Geology Special Publications. 1998;15(1):41–8.CrossRefGoogle Scholar
Byers, A., Recharte, J.. New Security Beat [Internet]. (Wilson Center Environmental Change and Security Program, 2015 [Accessed 2016]). Available from: www.newsecuritybeat.org/2015/04/glacial-floods-threaten-mountain-communities-global-exchange-fostering-adaptation/?q=1.Google Scholar
Tremblay, P.. Turkey’s Peace Pipe to Cyprus. (Al Monitor, 2015 [Accessed December 1, 2016]). Available from: www.al-monitor.com/pulse/originals/2015/10/turkey-cyprus-water-pipeline-delivers-fears.html.Google Scholar
Smakhtin, V., Ashton, P., Batchelor, A., et al. Unconventional Water Supply Options in South Africa: A Review of Possible Solutions. Water International. 2001;26(3):314–34.CrossRefGoogle Scholar
Allan., J. A. Virtual Water-the Water, Food, and Trade Nexus. Useful Concept or Misleading Metaphor? Water International. 2003;28(1):106–13.CrossRefGoogle Scholar
Galloway, J. N., Burke, M., Bradford, G. E., et al. International Trade in Meat: The Tip of the Pork Chop. AMBIO: A Journal of the Human Environment. 2007;36(8):622–9.CrossRefGoogle ScholarPubMed
Gleick, P. H.. The World’s Water 2000–2001. (Island Press, 2000).Google Scholar
Talbot, D.. Megascale Desalination. (Massachusetts Institute of Technology, 2015 [Accessed March 26, 2016]). Available from: www.technologyreview.com/s/534996/megascale-desalination.Google Scholar
Licht, S.. Efficient Solar‐Driven Synthesis, Carbon Capture, and Desalinization, Step: Solar Thermal Electrochemical Production of Fuels, Metals, Bleach. Advanced Materials. 2011;23(47):5592–612.CrossRefGoogle ScholarPubMed

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