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Water Resources Chapter 13
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What would you do Exercise in the future of the Middle east
Many analysts list the 3 most serious environmental problems the world faces Climate change Biodiversity loss Emerging water shortages
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Core Case Study: Water Conflicts in the Middle East: A Preview of the Future
Water shortages in the Middle East: hydrological poverty Nile River Jordan Basin Tigris and Euphrates Rivers Peacefully solving the problems
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Three Major River Basins in the Middle East
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13-1 Will We Have Enough Usable Water?
Concept 13-1A We are using available freshwater unsustainably by wasting it, polluting it, and charging too little for this irreplaceable natural resource. Concept 13-1B One of every six people does not have sufficient access to clean water, and this situation will almost certainly get worse.
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Freshwater Is an Irreplaceable Resource That We Are Managing Poorly (1)
Why is water so important? Earth as a watery world: 71% Freshwater availability: 0.024% Poorly managed resource Hydrologic cycle Water pollution
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Freshwater Is an Irreplaceable Resource That We Are Managing Poorly (2)
Access to water is A global health issue An economic issue A women’s and children’s issue A national and global security issue
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Girl Carrying Well Water over Dried Out Earth during a Severe Drought in India
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Most of the Earth’s Freshwater Is Not Available to Us
Hydrologic cycle Movement of water in the seas, land, and air Driven by solar energy and gravity People divided into Water haves Water have-nots
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Natural Capital: Groundwater System: Unconfined and Confined Aquifer
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Flowing artesian well Well requiring a pump Water table
Unconfined Aquifer Recharge Area Evaporation and transpiration Evaporation Precipitation Confined Recharge Area Runoff Flowing artesian well Well requiring a pump Stream Figure 13.3 Natural capital: groundwater system. An unconfined aquifer is an aquifer with a permeable water table. A confined aquifer is bounded above and below by less permeable beds of rock, and its water is confined under pressure. Some aquifers are replenished by precipitation; others are not. Water table Infiltration Lake Infiltration Unconfined aquifer Less permeable material such as clay Confined aquifer Confining impermeable rock layer Fig. 13-3, p. 316
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We Get Freshwater from Groundwater and Surface Water (1)
Zone of saturation Water table Aquifers Natural recharge Lateral recharge
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We Get Freshwater from Groundwater and Surface Water (2)
Surface runoff Watershed (drainage) basin Reliable runoff 1/3 of total
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We Use a Large and Growing Portion of the World’s Reliable Runoff
2/3 of the surface runoff: lost by seasonal floods 1/3 runoff usable Domestic: 10% Agriculture: 70% Industrial use: 20% Fred Pearce, author of When the Rivers Run Dry
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Case Study: Freshwater Resources in the United States
More than enough renewable freshwater, unevenly distributed (east vs west) Effect of Floods Pollution Drought 2007: U.S. Geological Survey projection Water hotspots
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Average Annual Precipitation and Major Rivers, Water-Deficit Regions in U.S.
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Figure 13.4 Average annual precipitation and major rivers (top) and water-deficit regions in the continental United States and their proximity to metropolitan areas having populations greater than 1 million (bottom). Question: Why do you think some areas with moderate precipitation still suffer from water shortages? (Data from U.S. Water Resources Council and U.S. Geological Survey) Fig. 13-4a, p. 317
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Average annual precipitation (centimeters)
Less than 41 81–122 41–81 More than 122 Figure 13.4 Average annual precipitation and major rivers (top) and water-deficit regions in the continental United States and their proximity to metropolitan areas having populations greater than 1 million (bottom). Question: Why do you think some areas with moderate precipitation still suffer from water shortages? (Data from U.S. Water Resources Council and U.S. Geological Survey) Fig. 13-4a, p. 317
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Figure 13.4 Average annual precipitation and major rivers (top) and water-deficit regions in the continental United States and their proximity to metropolitan areas having populations greater than 1 million (bottom). Question: Why do you think some areas with moderate precipitation still suffer from water shortages? (Data from U.S. Water Resources Council and U.S. Geological Survey) Fig. 13-4b, p. 317
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Metropolitan regions with population greater than 1 million
Figure 13.4 Average annual precipitation and major rivers (top) and water-deficit regions in the continental United States and their proximity to metropolitan areas having populations greater than 1 million (bottom). Question: Why do you think some areas with moderate precipitation still suffer from water shortages? (Data from U.S. Water Resources Council and U.S. Geological Survey) Acute shortage Shortage Adequate supply Metropolitan regions with population greater than 1 million Fig. 13-4b, p. 317
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Water Hotspots in 17 Western U.S. States
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Highly likely conflict potential
Washington North Dakota Montana Oregon Idaho South Dakota Wyoming Nevada Nebraska Utah Colorado Kansas California Oklahoma New Mexico Arizona Figure 13.5 Water hotspots in 17 western states that, by 2025, could face intense conflicts over scarce water needed for urban growth, irrigation, recreation, and wildlife. Some analysts suggest that this is a map of places not to live during the next 25 years. Question: If you live in one of these hotspot areas, have you noticed any signs of conflict over water supplies? (Data from U.S. Department of the Interior) Texas Highly likely conflict potential Substantial conflict potential Moderate conflict potential Unmet rural water needs Fig. 13-5, p. 318
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Water Shortages Will Grow (1)
Dry climate Drought Too many people using a normal supply of water
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Water Shortages Will Grow (2)
Wasteful use of water China and urbanization (2/3rds faced water shortages in 2006) Hydrological poverty
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Natural Capital Degradation: Stress on the World’s Major River Basins
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Asia Europe North America Africa South America Australia Stress High
Figure 13.6 Natural capital degradation: stress on the world’s major river basins, based on a comparison of the amount of water available with the amount used by humans (Concept 13-1B). Questions: If you live in a water-stressed area, what signs of stress have you noticed? In what ways, if any, has it affected your life? (Data from World Commission on Water Use in the 21st Century) Stress High None Fig. 13-6, p. 319
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Long-Term Severe Drought Is Increasing
Causes Extended period of below-normal rainfall Diminished groundwater Harmful environmental effects Dries out soils Reduces stream flows Decreases tree growth and biomass Lowers net primary productivity and crop yields Shift in biomes
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In Water-Short Areas Farmers and Cities Compete for Water Resources
2007: National Academy of Science study Increased corn production in the U.S. to make ethanol as an alternative fuel Decreasing water supplies Aquifer depletion Increase in pollution of streams and aquifers
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Who Should Own and Manage Freshwater Resources? (1)
Most water resources Owned by governments Managed as publicly owned resources Veolia and Suez: French companies Buy and manage water resources Successful outcomes in many areas (china)
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Who Should Own and Manage Freshwater Resources? (2)
Bechtel Corporation Poor water management in Bolivia A subsidiary of Bechtel Corporation Poor water management in Ecuador Potential problems with full privatization of water resources Financial incentive to sell water; not conserve it Poor will still be left out
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Who should own the water resources?
How can more water be produced?
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In America 85% of Americans get their water from publically owned utilities Within 10 years the 2 European companies aim to control 70% of the water supply in the US
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Assignment: Where do you get your water from? If a company, which one?
If your family receives a water bill, ask to see it. Record the following: Amount of water used (in gallons) Period of time recorded amount was used (months) Cost in dollars for that water
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Pros and Cons for privately owned water companies
Companies have money and expertise to manage these resources better (more efficiently) than the government Con: Companies motive is money, which may dictate their customer service Cost of reacquiring water resources is high Incentive is to sell water not conserve it Poor will be left out
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Exit Questions 1) How can some areas that receive a moderate amount of rainfall still suffer from water shortages? 2) Between farmers and city dwellers, which group should have greater access to water in water-short areas? 3) How might the scarcity of water in the Middle east affect nations that are dependent on oil from the Middle East?
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What can we do to guarantee our water security?
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Possible choices for sources of water
Extract more Groundwater Build More Dams Transfer water from one place to another Convert Seawater to Freshwater Reduce the amount of water needed
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13-2 Is Extracting Groundwater the Answer?
Concept Groundwater that is used to supply cities and grow food is being pumped from aquifers in some areas faster than it is renewed by precipitation.
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Aquifers Can be renewable resources unless;
Water becomes contaminated (salt or pollution) Removed faster than replaced Aquifers provide water for nearly ½ the world’s people In US aquifers supply almost all drinking water in rural areas 1/5th of urban areas about 40% of irrigation
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Water Tables Fall When Groundwater Is Withdrawn Faster Than It Is Replenished
India, China, and the United States Three largest grain producers Overpumping aquifers for irrigation of crops India and China Small farmers drilling tubewells Effect on water table (drops, requiring more expensive equip) Saudi Arabia Aquifer depletion and irrigation Irrigated farming will disappear in SA in years
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Natural Capital Degradation: Irrigation in Saudi Arabia Using an Aquifer
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What happens to the global food market once cheap groundwater runs out?
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TRADE-OFFS Withdrawing Groundwater Advantages Disadvantages
Useful for drinking and irrigation Aquifer depletion from overpumping Sinking of land (subsidence) from overpumping Available year-round Aquifers polluted for decades or centuries Exists almost everywhere Saltwater intrusion into drinking water supplies near coastal areas Renewable if not overpumped or contaminated Figure 13.7 Advantages and disadvantages of withdrawing groundwater. Question: Which two advantages and which two disadvantages do you think are the most important? Why? Reduced water flows into surface waters No evaporation losses Increased cost and contamination from deeper wells Cheaper to extract than most surface waters Fig. 13-7, p. 321
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Case Study: Aquifer Depletion in the United States
Ogallala aquifer: largest known aquifer Irrigates the Great Plains Water table lowered more than 30m Cost of high pumping has eliminated some of the farmers Government subsidies to continue farming deplete the aquifer further Biodiversity threatened in some areas (loss of wetlands derived from springs) California Central Valley: serious water depletion
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Natural Capital Degradation: Areas of Greatest Aquifer Depletion in the U.S.
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Groundwater Overdrafts:
Figure 13.9 Natural capital degradation: areas of greatest aquifer depletion from groundwater overdraft in the continental United States, including the vast, central Ogallala aquifer. Aquifer depletion is also high in Hawaii and Puerto Rico (not shown on map). See an animation based on this figure at CengageNOW™. Question: If you live in the United States, how is your lifestyle affected directly or indirectly by water withdrawn from the essentially nonrenewable Ogallala aquifer? (Data from U.S. Water Resources Council and U.S. Geological Survey) High Moderate Minor or none Fig. 13-9, p. 322
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Natural Capital Degradation: The Ogallala is the World’s Largest Known Aquifer
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SOUTH DAKOTA WYOMING NEBRASKA COLORADO KANSAS OKLAHOMA NEW MEXICO
Figure 13.10 Natural capital degradation: The Ogallala is the world’s largest known aquifer. If the water in this aquifer were above ground, it could cover all of the lower 48 states with 0.5 meter (1.5 feet) of water. Water withdrawn from this aquifer is used to grow crops, raise cattle, and provide cities and industries with water. As a result, this aquifer, which is renewed very slowly, is being depleted, especially at its thin southern end in parts of Texas, New Mexico, Oklahoma, and Kansas. (Data from U.S. Geological Survey) Miles TEXAS 100 160 Kilometers Saturated thickness of Ogallala Aquifer Less than 61 meters (200 ft.) 61–183 meters (200–600 ft.) More than 183 meters (600 ft.) (as much as 370 meters or 1,200 ft. in places) Fig , p. 323
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Other effects of ground water pumping
Lower water table requires greater cost to farmers to continue to pump Land subsidence: Take water out, allows land to compact (shrink). Compaction prohibits future recharge Sinkholes: underground cavern collapse after being drained of water Contamination of the groundwater with saltwater. Undrinkable and unusable for irrigation
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Sinkholes
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Sinkholes New sinkholes have been correlated to land-use practices, especially from ground-water pumping and from construction and development practices. Sinkholes can also form when natural water-drainage patterns are changed and new water-diversion systems are developed. Some sinkholes form when the land surface is changed, such as when industrial and runoff-storage ponds are created. The substantial weight of the new material can trigger an underground collapse of supporting material, thus causing a sinkhole. The overburden sediments that cover buried cavities in the aquifer systems are delicately balanced by ground-water fluid pressure. The water below ground is actually helping to keep the surface soil in place. Groundwater pumping for urban water supply and for irrigation can produce new sinkholes In sinkhole-prone areas. If pumping results in a lowering of ground-water levels, then underground structural failure, and thus, sinkholes, can occur.
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SOLUTIONS Groundwater Depletion Prevention Control Waste less water
Raise price of water to discourage waste Subsidize water conservation Tax water pumped from wells near surface waters Limit number of wells Figure 13.11 Ways to prevent or slow groundwater depletion by using water more sustainably. Question: Which two of these solutions do you think are the most important? Why? Set and enforce minimum stream flow levels Do not grow water-intensive crops in dry areas Divert surface water in wet years to recharge aquifers Fig , p. 324
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Science Focus: Are Deep Aquifers the Answer?
Locate the deep aquifers; determine if they contain freshwater or saline water Major concerns Geological and ecological impact of pumping water from them Flow beneath more than one country Who has rights to it?
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Exit Questions 13-2 List 3 disadvantages to over using groundwater
One of the control solutions is to raise the price of water to discourage waste. Do you agree with the solution? What suggestions would you give in order to make this choices more agreeable to the average taxpayer.
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How much water does your family use a month?
Identify source of water used in home Determine the amount of water used by month/day Determine cost for water Daily/Monthly Water weights 14 lbs per gallon Estimates?
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Possible choices for sources of water
Extract more Groundwater Build More Dams Transfer water from one place to another Convert Seawater to Freshwater Reduce the amount of water needed
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13-3 Is Building More Dams the Answer?
Concept 13-3 Building dam and reservoir systems has greatly increased water supplies in some areas, but it has disrupted ecosystems and displaced people.
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Large Dams and Reservoirs Have Advantages and Disadvantages (1)
Main goals of a dam and reservoir system Capture and store runoff Release runoff as needed to control: Floods Generate electricity Supply irrigation water Recreation (reservoirs)
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Large Dams and Reservoirs Have Advantages and Disadvantages (2)
Increase the reliable runoff available for farming/drinking Reduce flooding Grow crops in arid regions Recreation
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Large Dams and Reservoirs Have Advantages and Disadvantages (3)
Displaces people Flooded regions Impaired ecological services of rivers Loss of plant and animal species Fill up with sediment within 50 years
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Advantages and Disadvantages of Large Dams and Reservoirs
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Hoopes Reservoir
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The Ataturk Dam Project in Eastern Turkey
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San Clemente dam - California
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San Clemente Dam- California
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The 89-year old, 106-foot high dam, which once helped bring water to residents of Monterey County, is at risk of failing during a significant earthquake or flood. Sediment has been building up behind the dam for years, making it a hazard for those living below it and almost useless as a water storage reservoir. If the dam were to fail, an estimated 2½ million cubic yards of sediment and more than 40 million gallons of water could rush downstream with potentially disastrous consequences. The dam removal will also aid in the recovery of steelhead trout by opening up access to more than 25 square miles of spawning and rearing habitat. Steelhead in Carmel River were listed as threatened under the Endangered Species Act in 1997. “The removal of the San Clemente Dam will help restore richness to the entire ecosystem of the Carmel River while eliminating this major safety threat to the people and their property along it,” said Rodney McInnis, NOAA’s Fisheries Service southwest regional administrator. “The dam removal is vital to the recovery of this important steelhead trout run.”
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Some Rivers Are Running Dry and Some Lakes Are Shrinking
Dams disrupt the hydrologic cycle Major rivers running dry part of the year Colorado and Rio Grande, U.S. Yangtze and Yellow, China Indus, India Danube, Europe Nile River-Lake Victoria, Egypt Lake Chad Africa: disappearing
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The Colorado River Basin
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Case Study: The Colorado River Basin— An Overtapped Resource (1)
2,300 km through 7 U.S. states 14 Dams and reservoirs Located in a desert area within the rain shadow of the Rocky Mountains Water supplied mostly from snowmelt of the Rocky Mountains
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Case Study: The Colorado River Basin— An Overtapped Resource (2)
Supplies water and electricity for more than 25 million people Irrigation of crops, cheap water from dams Recreation
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Case Study: The Colorado River Basin— An Overtapped Resource (3)
Four Major problems Colorado River basin has very dry lands Modest flow of water for its size Legal pacts allocated more water for human use than it can supply Amount of water flowing to the mouth of the river has dropped Silt buildup because of slowing water- filling up the resevoirs
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Case Study: The Colorado River Basin— An Overtapped Resource (4)
What will happen if some of the reservoirs empty out? Economic and ecological catastrophe Political and legal battles over water
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What can be done Enact and enforce strict water conservation measures
Sharply increase the price of water Slow population growth/urban development Stop subsidizing use of water for agriculture in the region Stop building golf courses/green lawns
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Aerial View of Glen Canyon Dam Across the Colorado River and Lake Powell
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The Flow of the Colorado River Measured at Its Mouth Has Dropped Sharply
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Hoover Dam completed (1935)
30 Hoover Dam completed (1935) 25 20 Flow (billion cubic meters) 15 Glen Canyon Dam completed (1963) 10 Figure 13.16 The flow of the Colorado River measured at its mouth has dropped sharply since 1905 as a result of multiple dams, water withdrawals for agriculture and urban areas, and prolonged drought. (Data from U.S. Geological Survey) 5 1910 1920 1930 1940 1950 1960 1970 1980 1990 2000 Year Fig , p. 328
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Case Study: China’s Three Gorges Dam (1)
World’s largest hydroelectric dam and reservoir 2 km long across the Yangtze River Benefits Electricity-producing potential is huge Holds back the Yangtze River floodwaters Allows cargo-carrying ships
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Three Gorges Dam
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Flooding Natural and Cultural Icons
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Trash at the dam
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Case Study: China’s Three Gorges Dam (2)
Harmful effects Displaces about 5.4 million people Built over a seismic fault Significance? Rotting plant and animal matter producing (Methane) CH4 Worse than CO2 emissions as a greenhouse gas Will the Yangtze River become a sewer?
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Exit questions 6) Do the advantages (name some) outweigh the disadvantages (name some) of large dams? 7) List the top 3 measures you would make to deal with the water problems of the Colorado River
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13-4 Is Transferring Water from One Place to Another the Answer?
Concept Transferring water from one place to another has greatly increased water supplies in some areas, but it has also disrupted ecosystems.
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CA, U.S., Transfers Water from Water-Rich Areas to Water-Poor Areas
Water transferred by Tunnels Aqueducts Underground pipes May cause environmental problems California Water Project
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The California Water Project and the Central Arizona Project
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Oroville Dam and Reservoir
CALIFORNIA Shasta Lake NEVADA UTAH Sacramento River Oroville Dam and Reservoir Feather River North Bay Aqueduct Lake Tahoe Sacramento San Francisco Hoover Dam and Reservoir (Lake Mead) South Bay Aqueduct Fresno San Luis Dam and Reservoir San Joaquin Valley Colorado River Los Angeles Aqueduct California Aqueduct ARIZONA Colorado River Aqueduct Santa Barbara Figure 13.17 The California Water Project and the Central Arizona Project. These projects involve large-scale water transfers from one watershed to another. Arrows show the general direction of water flow. Central Arizona Project Los Angeles Phoenix Salton Sea San Diego Tucson MEXICO Fig , p. 330
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Case Study: The Aral Sea Disaster (1)
Large-scale water transfers in dry central Asia Water diverted from rivers Wetland destruction and wildlife (85%) Fish extinctions and fishing industry collapse
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Case Study: The Aral Sea Disaster (2)
Wind-blown salt (salinization of the land) Farmer’s response to poorer yields…resulting health problems Water pollution (concentrated, dumped) Climatic changes (thermal buffer, now hotter drier summers)
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Natural Capital Degradation: The Aral Sea, Shrinking Freshwater Lake
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1976 2006 Figure 13.18 Natural capital degradation: the Aral Sea was once the world’s fourth largest freshwater lake. Since 1960, it has been shrinking and getting saltier because most of the water from the rivers that replenish it has been diverted to grow cotton and food crops (Concept 13-4). These satellite photos show the sea in 1976 and in It has split into two major parts, little Aral on the left and big Aral on the right. As the lake shrank, it left behind a salty desert, economic ruin, increasing health problems, and severe ecological disruption. Question: What do you think should be done to help prevent further shrinkage of the Aral Sea? Stepped Art Fig a, p. 331
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Ship Stranded in Desert Formed by Shrinkage of the Aral Sea
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The threat of anthrax Buried 100’s of metric tons of anthrax spores and other deadly toxins on island Water level is reduced to point that island is not connected to mainland Rats, fleas could carry disease to humans
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China Plans a Massive Transfer of Water
South-North Water Transfer Project Water from three rivers to supply 0.5 billion people Completion in about 2050 Impact Economic Health Environmental
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Tibet : The water tower of the world
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Global Warming its possible effect on the projects
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Exit questions for 13.4 Water transport
Describe the California water project Describe the Aral Sea disaster Describe the proposed China South-North water project What are common benefits of transporting water What are common problems involved with transporting water
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13-5 Is Converting Salty Seawater to Freshwater the Answer?
Concept We can convert salty ocean water to freshwater, but the cost is high, and the resulting salty brine must be disposed of without harming aquatic or terrestrial ecosystems.
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Removing Salt from Seawater Seems Promising but Is Costly (1)
Desalination (2 main methods) Distillation Reverse osmosis, microfiltration Already used to produce water 15,000 plants in 125 countries Saudi Arabia: highest number (who is 2nd?) Mainly wealthy, energy rich countries
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Distillation - Boiling
Heating separates water from salts Use cool incoming water to condense vapor
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Reverse Osmosis: Screens and Pressure
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Desalination steps Bring seawater into plant Remove solids
Desalinate water Get rid of waste brine Treat freshwater Store and use
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Cost comparison of methods
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Microfilters
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Benefits Adding usable water to system Huge potential resource
Most countries have access to the ocean
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Removing Salt from Seawater Seems Promising but Is Costly (2)
Problems High cost and energy footprint Use chemicals to keep down algal growth potential to kill many marine organisms, if released Large quantity of chemically contaminated brine( highly concentrated salt water) where do you dispose of it? Water may be too pure, minerals have to me added back into water for it to be useful
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Science Focus: The Search for Improved Desalination Technology
Desalination on offshore ships (what is the advantage?) Solar or wind/wave energy Better membranes Better disposal options for the brine waste Reduce water needs, conserve water
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Exit questions for 13.5 What does desalination mean?
What is the difference between the Distillation process and the Reverse Osmosis process? What solutions were presented to overcome the problems associated with desalination?
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13-6 How Can We Use Water More Sustainably?
Concept We can use water more sustainably by cutting water waste, raising water prices, slowing population growth, and protecting aquifers, forests, and other ecosystems that store and release water.
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Reducing Water Waste Has Many Benefits (1)
We have the potential the impending global water shortage just by not wasting (conserving) water we already use. Water conservation Improves irrigation efficiency Improves collection efficiency Uses less in homes and businesses
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Reducing Water Waste Has Many Benefits (2)
Worldwide: 65–70% loss Two largest sources of waste: Evaporation, leaks Big reason for waste Water prices: low cost to user Government subsidies: more needed? What should government support with your money?
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We Can Cut Water Waste in Irrigation
Flood irrigation Wasteful Center pivot, low pressure sprinklers Low-energy, precision application sprinklers Drip or trickle irrigation, micro-irrigation Costly; less water waste
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Flood Irrigation
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Center pivot irrigation
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Drip irrigation
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(efficiency 60% and 80% with surge valves)
Figure 13.20 Major irrigation systems. Because of high initial costs, center-pivot irrigation and drip irrigation are not widely used. The development of new, low-cost, drip-irrigation systems may change this situation. Center pivot (efficiency 80% with low-pressure sprinkler and 90–95% with LEPA sprinkler) Drip irrigation (efficiency 90–95%) Gravity flow (efficiency 60% and 80% with surge valves) Above- or below-ground pipes or tubes deliver water to individual plant roots. Water usually pumped from underground and sprayed from mobile boom with sprinklers. Water usually comes from an aqueduct system or a nearby river. Fig , p. 335
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Effluent spray system
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Major Irrigation Systems
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(efficiency 60% and 80% with surge valves)
Center pivot (efficiency 80% with low-pressure sprinkler and 90–95% with LEPA sprinkler) Water usually pumped from underground and sprayed from mobile boom with sprinklers. Drip irrigation (efficiency 90–95%) Above- or below-ground pipes or tubes deliver water to individual plant roots. Gravity flow (efficiency 60% and 80% with surge valves) Water usually comes from an aqueduct system or a nearby river. Figure 13.20 Major irrigation systems. Because of high initial costs, center-pivot irrigation and drip irrigation are not widely used. The development of new, low-cost, drip-irrigation systems may change this situation. Stepped Art Fig , p. 335
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Solutions: Reducing Irrigation Water Waste
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Developing Countries Use Low-Tech Methods for Irrigation
Human-powered treadle pumps Harvest and store rainwater Create a canopy over crops: reduces evaporation Fog-catcher nets
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Human Treadle Pumps
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Fog Catcher nets
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We Can Cut Water Waste in Industry and Homes
Recycle water in industry Fix leaks in the plumbing systems Use water-thrifty landscaping: xeriscaping Use gray water Pay-as-you-go water use
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Xeriscaping
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Solutions: Reducing Water Waste
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We Can Use Less Water to Remove Wastes
Can we mimic how nature deals with waste? Waterless composting toilets
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We Need to Use Water More Sustainably
“The frog does not drink up the pond in which it lives” Blue revolution What can cities, industries, governments do to reduce water consumption?
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SOLUTIONS Sustainable Water Use
Waste less water and subsidize water conservation Do not deplete aquifers Preserve water quality Protect forests, wetlands, mountain glaciers, watersheds, and other natural systems that store and release water Figure 13.23 Methods for achieving more sustainable use of the earth’s water resources (Concept 13-6). Question: Which two of these solutions do you think are the most important? Why? Get agreements among regions and countries sharing surface water resources Raise water prices Slow population growth Fig , p. 337
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What can you do to reduce water consumption
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What Can You Do? Water Use and Waste
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Why do you think people do not conserve water?
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Reasons Takes time Costs more money than doing nothing
Benefit is not immediate
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Exit questions 13.6 What actions can you take to reduce the amount of water that you consume? What methods of irrigation use the least amount of water? Which method could you use in your own garden? Name 3 important solutions in reducing water waste in cities.
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13-7 How Can We Reduce the Threat of Flooding?
Concept We can lessen the threat of flooding by protecting more wetlands and natural vegetation in watersheds and by not building in areas subject to frequent flooding.
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Some Areas Get Too Much Water from Flooding (1)
Flood plains Highly productive wetlands Provide natural flood and erosion control Maintain high water quality Recharge groundwater Benefits of floodplains Fertile soils Nearby rivers for use and recreation Flatlands for urbanization and farming
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Some Areas Get Too Much Water from Flooding (2)
Dangers of floodplains and floods Deadly and destructive Human activities worsen floods Failing dams and water diversion Hurricane Katrina and the Gulf Coast Removal of coastal wetlands
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Natural Capital Degradation: Hillside Before and After Deforestation
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Forested Hillside Oxygen released by vegetation
Diverse ecological habitat Evapotranspiration Trees reduce soil erosion from heavy rain and wind Agricultural land Figure 13.25 Natural capital degradation: hillside before and after deforestation. Once a hillside has been deforested for timber, fuelwood, livestock grazing, or unsustainable farming, water from precipitation rushes down the denuded slopes, erodes precious topsoil, and can increase flooding and pollution in local streams. Such deforestation can also increase landslides and mudflows. A 3,000-year-old Chinese proverb says, “To protect your rivers, protect your mountains.” See an animation based on this figure at CengageNOW. Question: How might a drought in this area make these effects even worse? Tree roots stabilize soil Vegetation releases water slowly and reduces flooding Forested Hillside Fig a, p. 339
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After Deforestation Tree plantation Evapotranspiration decreases
Roads destabilize hillsides Overgrazing accelerates soil erosion by water and wind Winds remove fragile topsoil Agricultural land is flooded and silted up Gullies and landslides Figure 13.25 Natural capital degradation: hillside before and after deforestation. Once a hillside has been deforested for timber, fuelwood, livestock grazing, or unsustainable farming, water from precipitation rushes down the denuded slopes, erodes precious topsoil, and can increase flooding and pollution in local streams. Such deforestation can also increase landslides and mudflows. A 3,000-year-old Chinese proverb says, “To protect your rivers, protect your mountains.” See an animation based on this figure at CengageNOW. Question: How might a drought in this area make these effects even worse? Heavy rain erodes topsoil Silt from erosion fills rivers and reservoirs Rapid runoff causes flooding After Deforestation Fig b, p. 339
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Forested Hillside After Deforestation Oxygen released by vegetation
Diverse ecological habitat Evapotranspiration Trees reduce soil erosion from heavy rain and wind Tree roots stabilize soil Vegetation releases water slowly and reduces flooding Forested Hillside Agricultural land Stepped Art Tree plantation Roads destabilize hillsides Overgrazing accelerates soil erosion by water and wind Winds remove fragile topsoil Agricultural land is flooded and silted up Gullies and landslides Heavy rain erodes topsoil Silt from erosion fills rivers and reservoirs Rapid runoff causes flooding After Deforestation Evapotranspiration decreases Figure 13.25 Natural capital degradation: hillside before and after deforestation. Once a hillside has been deforested for timber, fuelwood, livestock grazing, or unsustainable farming, water from precipitation rushes down the denuded slopes, erodes precious topsoil, and can increase flooding and pollution in local streams. Such deforestation can also increase landslides and mudflows. A 3,000-year-old Chinese proverb says, “To protect your rivers, protect your mountains.” See an animation based on this figure at CengageNOW. Question: How might a drought in this area make these effects even worse? Fig a, p. 339
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Case Study: Living Dangerously on Floodplains in Bangladesh
Dense population Located on coastal floodplain Moderate floods maintain fertile soil Increased frequency of large floods Effects of development in the Himalayan foothills Destruction of coastal wetlands
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We Can Reduce Flood Risks
Rely more on nature’s systems Wetlands Natural vegetation in watersheds Rely less on engineering devices Dams Levees
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Solutions: Reducing Flood Damage
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SOLUTIONS Reducing Flood Damage Prevention Control
Preserve forests on watersheds Straighten and deepen streams (channelization) Preserve and restore wetlands in floodplains Build levees or floodwalls along streams Tax development on floodplains Figure 13.26 Methods for reducing the harmful effects of flooding (Concept 13-7). Question: Which two of these solutions do you think are the most important? Why? Use floodplains primarily for recharging aquifers, sustainable agriculture and forestry Build dams Fig , p. 340
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Active Figure: Effects of deforestation
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