1. Chapter 20 Water Pollution

2. The Seattle, Washington Area, U.S.
Figure 20.1: The U.S. city of Seattle, Washington, was founded on the shore of Puget Sound and quickly expanded eastward toward Lake Washington.
Fig. 20-1, p. 528

3. Core Case Study: Lake Washington
Sewage dumped into Lake Washington
1955: Edmondson discovered cyanobacteria in the lake
Role of phosphorus
Public pressure led to cleanup of the lake
Sewage treatment plant effluent to Puget Sound
New pollution challenges

4. Kayaker Enjoys Lake Washington
Figure 20.2: With the city of Seattle in the background, this kayaker enjoys the waters of Lake Washington. The once badly polluted lake has recovered, but population pressures and the resulting wastes are threatening it again.
Fig. 20-2, p. 528

5. 20-1 What Are the Causes and Effects of Water Pollution?
Concept 20-1A Water pollution causes illness and death in humans and other species, and disrupts ecosystems.
Concept 20-1B The chief sources of water pollution are agricultural activities, industrial facilities, and mining, but growth in population and resource use make it increasingly worse.

6. Water Pollution Comes from Point and Nonpoint Sources (1)
Change in water quality that can harm organisms or make water unfit for human uses
Contamination with chemicals
Excessive heat
Point sources
Located at specific places
Easy to identify, monitor, and regulate
Examples

7. Water Pollution Comes from Point and Nonpoint Sources (2)
Broad, diffuse areas
Difficult to identify and control
Expensive to clean up
Examples

8. Water Pollution Comes from Point and Nonpoint Sources (3)
Leading causes of water pollution
Agriculture activities
Sediment eroded from the lands
Fertilizers and pesticides
Bacteria from livestock and food processing wastes
Industrial facilities
Mining

9. Point Source of Polluted Water in Gargas, France
Figure 20.3: This point-source water pollution flows uncontrolled into a stream near Gargas, France.
Fig. 20-3, p. 530

10. Nonpoint Sediment from Unprotected Farmland Flows into Streams
Figure 20.4: Nonpoint sediment pollution eroded from farmland flows into streams and sometimes changes their courses or dams them up. As measured by weight, it is the largest source of water pollution. Question: What do you think the owner of this farm could have done to prevent such sediment pollution?
Fig. 20-4, p. 530

11. Lake Polluted with Mining Wastes
Figure 20.5: The water in this lake is polluted with mining wastes.
Fig. 20-5, p. 531

12. Plastic Wastes in Mountain Lake
Figure 20.6: Plastics and other forms of waste pollute this mountain lake as well as many bodies of water around the world, and can release harmful chemicals into the water.
Fig. 20-6, p. 531

13. Major Water Pollutants Have Harmful Effects
Infectious disease organisms: contaminated drinking water
The World Health Organization (WHO)
1.6 million people die every year, mostly under the age of 5

14. Major Water Pollutants and Their Sources
Table 20-1
Table 20-1, p. 532

15. Common Diseases Transmitted to Humans through Contaminated Drinking Water
Table 20-2
Table 20-2, p. 532

16. Science Focus: Testing Water for Pollutants (1)
Variety of tests to determine water quality
Coliform bacteria: Escherichia coli, significant levels
Level of dissolved oxygen (DO)
Chemical analysis

17. Science Focus: Testing Water for Pollutants (2)
Indicator species
Examples
Bacteria and yeast glow in the presence of a particular toxic chemical
Color and turbidity of the water

18. Water Quality as Measured by Dissolved Oxygen Content in Parts per Million
Figure 20.A: Scientists measure dissolved oxygen (DO) content in parts per million (ppm) at 20°C (68°F) as an indicator of water quality. Only a few fish species can survive in water with less than 4 ppm of dissolved oxygen at this temperature. Some warm-water species have evolved ways to tolerate low DO levels better than most cold-water species can. Question: Would you expect the dissolved oxygen content of polluted water to increase or decrease if the water is heated? Explain.
Fig. 20-A, p. 533

19. Water Quality DO (ppm) at 20°C 8–9 Good Slightly polluted 6.7–8
Moderately polluted
4.5–6.7
Heavily polluted
Figure 20.A: Scientists measure dissolved oxygen (DO) content in parts per million (ppm) at 20°C (68°F) as an indicator of water quality. Only a few fish species can survive in water with less than 4 ppm of dissolved oxygen at this temperature. Some warm-water species have evolved ways to tolerate low DO levels better than most cold-water species can. Question: Would you expect the dissolved oxygen content of polluted water to increase or decrease if the water is heated? Explain.
4–4.5
Gravely polluted
Below 4
Fig. 20-A, p. 533

20. 20-2 What Are the Major Water Pollution Problems in Streams and Lakes?
Concept 20-2A Streams and rivers around the world are extensively polluted, but they can cleanse themselves of many pollutants if we do not overload them or reduce their flows.
Concept 20-2B The addition of excessive nutrients to lakes from human activities can disrupt their ecosystems, and prevention of such pollution is more effective and less costly than cleaning it up.

21. Streams Can Cleanse Themselves If We Do Not Overload Them
Dilution
Biodegradation of wastes by bacteria takes time
Oxygen sag curve

22. Dilution and Decay of Degradable, Oxygen-Demanding Wastes in a Stream
Figure 20.7: Natural capital.
A stream can dilute and decay degradable, oxygen-demanding wastes, and it can also dilute heated water. This figure shows the oxygen sag curve (blue) and the curve of oxygen demand (red). Depending on flow rates and the amount of biodegradable pollutants, streams recover from oxygen-demanding wastes and from the injection of heated water if they are given enough time and are not overloaded (Concept 20-2a). See an animation based on this figure at CengageNOW™. Question: What would be the effect of putting another discharge pipe emitting biodegradable waste to the right of the one in this picture?
Fig. 20-7, p. 534

23. Point source
Normal clean water organisms (Trout, perch, bass, mayfly, stonefly)
Pollution- tolerant fishes (carp, gar)
Fish absent, fungi, sludge worms,
bacteria (anaerobic)
Pollution- tolerant fishes (carp, gar)
Normal clean water organisms (Trout, perch, bass, mayfly, stonefly)
8 ppm
Types of organisms
Dissolved oxygen (ppm)
8 ppm
Figure 20.7: Natural capital.
A stream can dilute and decay degradable, oxygen-demanding wastes, and it can also dilute heated water. This figure shows the oxygen sag curve (blue) and the curve of oxygen demand (red). Depending on flow rates and the amount of biodegradable pollutants, streams recover from oxygen-demanding wastes and from the injection of heated water if they are given enough time and are not overloaded (Concept 20-2a). See an animation based on this figure at CengageNOW™. Question: What would be the effect of putting another discharge pipe emitting biodegradable waste to the right of the one in this picture?
Biochemical oxygen demand
Clean Zone
Recovery Zone
Septic Zone
Decomposition Zone
Clean Zone
Fig. 20-7, p. 534

24. Stream Pollution in More Developed Countries
1970s: Water pollution control laws
Successful water clean-up stories
Ohio Cuyahoga River, U.S.
Thames River, Great Britain
Contamination of toxic inorganic and organic chemicals by industries and mines

25. Individuals Matter: The Man Who Planted Trees to Restore a Stream
John Beal: restoration of Hamm Creek, Seattle, WA, U.S.
Planted trees
Persuaded companies to stop dumping
Removed garbage

26. Global Outlook: Stream Pollution in Developing Countries
Half of the world’s 500 major rivers are polluted
Untreated sewage
Industrial waste
India’s rivers
China’s rivers

27. Natural Capital Degradation: Highly Polluted River in China
Figure 20.8: Natural capital degradation.
This highly polluted river in central China has been turned greenish-black by uncontrolled pollution from thousands of factories. In some parts of China, river water is too toxic to touch, much less drink. The cleanup and modernization of Chinese cities such as Beijing and Shanghai are forcing polluting refineries and factories to move to rural areas where two-thirds of China’s population resides. Liver and stomach cancers, linked in some cases to water pollution, are among the leading causes of death in the countryside. Farmers too poor to buy bottled water must often drink polluted well water.
Fig. 20-8, p. 535

28. Trash Truck Disposing of Garbage into a River in Peru
Figure 20.9: Global outlook: This garbage truck is dumping trash into a river in Peru.
Fig. 20-9, p. 536

29. Too Little Mixing and Low Water Flow Makes Lakes Vulnerable to Water Pollution
Less effective at diluting pollutants than streams
Stratified layers
Little vertical mixing
Little of no water flow
Can take up to 100 years to change the water in a lake
Biological magnification of pollutants

30. Lake Fish Killed by Water Pollution
Figure 20.10: Water pollution has killed the fish in this lake.
Fig , p. 536

31. Cultural Eutrophication Is Too Much of a Good Thing (1)
Natural enrichment of a shallow lake, estuary, or slow-moving stream
Caused by runoff into lake that contains nitrates and phosphates
Oligotrophic lake
Low nutrients, clear water

32. Cultural Eutrophication Is Too Much of a Good Thing (2)
Nitrates and phosphates from human sources
Farms, feedlots, streets, parking lots
Fertilized lawns, mining sites, sewage plants
During hot weather or droughts
Algal blooms
Increased bacteria
More nutrients
Anaerobic bacteria

33. Cultural Eutrophication Is Too Much of a Good Thing (3)
Prevent or reduce cultural eutrophication
Remove nitrates and phosphates
Diversion of lake water
Clean up lakes
Remove excess weeds
Use herbicides and algaecides; down-side?
Pump in air

34. Cultural Eutrophication of Chinese Lake
Figure 20.11: Global outlook: Severe cultural eutrophication has covered this lake near the Chinese city of Haozhou with algae.
Fig , p. 537

35. Revisiting Lake Washington and Puget Sound
Severe water pollution can be reversed
Citizen action combined with scientific research
Good solutions may not work forever
Wastewater treatment plant effluents sent into Puget Sound
Now what’s happening?

36. Case Study: Pollution in the Great Lakes (1)
1960s: Many areas with cultural eutrophication
1972: Canada and the United States: Great Lakes pollution control program
Decreased algal blooms
Increased dissolved oxygen
Increased fishing catches
Swimming beaches reopened
Better sewage treatment plants
Fewer industrial wastes
Bans on phosphate-containing household products

37. Case Study: Pollution in the Great Lakes (2)
Problems still exist
Raw sewage
Nonpoint runoff of pesticides and fertilizers
Biological pollution
Atmospheric deposition of pesticides and Hg

38. Case Study: Pollution in the Great Lakes (3)
2007 State of the Great Lakes report
New pollutants found
Wetland loss and degradation
Declining of some native species
Native carnivorous fish species declining
What should be done?

39. The Great Lakes of North America
Figure 20.12: The five Great Lakes of North America make up the world’s largest freshwater system. Dozens of major cities in the United States and Canada are located on their shores, and water pollution in the lakes is a growing problem.
Fig , p. 538

40. 20-3 Pollution Problems Affecting Groundwater, Other Water Sources
Concept 20-3A Chemicals used in agriculture, industry, transportation, and homes can spill and leak into groundwater and make it undrinkable.
Concept 20-3B There are both simple an complex ways to purify groundwater used as a source of drinking water, but protecting it through pollution prevention is the least expensive and most effective strategy.

41. Ground Water Cannot Cleanse Itself Very Well (1)
Source of drinking water
Common pollutants
Fertilizers and pesticides
Gasoline
Organic solvents
Pollutants dispersed in a widening plume

42. Ground Water Cannot Cleanse Itself Very Well (2)
Slower chemical reactions in groundwater due to
Slow flow: contaminants not diluted
Less dissolved oxygen
Fewer decomposing bacteria
Low temperatures

43. Principal Sources of Groundwater Contamination in the U.S.
Figure 20.13: Natural capital degradation.
These are the principal sources of groundwater contamination in the United States (Concept 20-3a). Another source in coastal areas is saltwater intrusion from excessive groundwater withdrawal. (Figure is not drawn to scale.) Question: What are three sources shown in this picture that might be affecting groundwater in your area?
Fig , p. 540

44. Leakage from faulty casing
Polluted air
Hazardous waste
injection well
Pesticides
and fertilizers
Coal strip mine runoff
Deicing road salt
Buried gasoline and solvent tanks
Cesspool, septic
tank
Pumping well
Gasoline station
Water pumping well
Waste lagoon
Sewer
Landfill
Accidental spills
Leakage from faulty casing
Figure 20.13: Natural capital degradation.
These are the principal sources of groundwater contamination in the United States (Concept 20-3a). Another source in coastal areas is saltwater intrusion from excessive groundwater withdrawal. (Figure is not drawn to scale.) Question: What are three sources shown in this picture that might be affecting groundwater in your area?
Discharge
Freshwater aquifer
Freshwater aquifer
Freshwater aquifer
Groundwater flow
Fig , p. 540

45. Groundwater Pollution Is a Serious Hidden Threat in Some Areas
China: 90% of urban aquifers are contaminated or overexploited
U.S.: FDA reports of toxins found in many aquifers
Threats
Gasoline, oil
Nitrate ions
Arsenic

46. Pollution Prevention Is the Only Effective Way to Protect Groundwater
Prevent contamination of groundwater
Cleanup: expensive and time consuming

47. Solutions: Groundwater Pollution, Prevention and Cleanup
Figure 20.14: There are ways to prevent and ways to clean up contamination of groundwater but prevention is the only effective approach (Concept 20-3B). Questions: Which two of these preventive solutions do you think are the most important? Why?
Fig , p. 541

48. Groundwater Pollution
Solutions
Groundwater Pollution
Prevention
Cleanup
Find substitutes for toxic chemicals
Pump to surface, clean, and return to aquifer (very expensive)
Keep toxic chemicals out of the environment
Install monitoring wells near landfills and underground tanks
Inject microorganisms to clean up contamination (less expensive but still costly)
Require leak detectors on underground tanks
Ban hazardous waste disposal in landfills and injection wells
Figure 20.14: There are ways to prevent and ways to clean up contamination of groundwater but prevention is the only effective approach (Concept 20-3B). Questions: Which two of these preventive solutions do you think are the most important? Why?
Store harmful liquids in aboveground tanks with leak detection and collection systems
Pump nanoparticles of inorganic compounds to remove pollutants (still being developed)
Fig , p. 541

49. There Are Many Ways to Purify Drinking Water
Reservoirs and purification plants
Process sewer water to drinking water
Expose clear plastic containers to sunlight (UV)
The LifeStraw
PUR: chlorine and iron sulfate powder

50. The LifeStraw: Personal Water Purification Device
Figure 20.15: The LifeStraw™, designed by Torben Vestergaard Frandsen, is a personal water purification device that gives many poor people access to safe drinking water. Here, four young men in Uganda demonstrate its use. Question: Do you think the development of such devices should make prevention of water pollution less of a priority? Explain.
Fig , p. 542

51. Case Study: Protecting Watersheds Instead of Building Water Purification Plants
New York City water
Reservoirs in the Catskill Mountains
Paid towns, farmers, and others in the watershed to restore forests, wetlands, and streams
Saved the cost of building a plant: $6 billion

52. Using Laws to Protect Drinking Water Quality
1974: U.S. Safe Drinking Water Act
Sets maximum contaminant levels for any pollutants that affect human health
Health scientists: strengthen the law
Water-polluting companies: weaken the law

53. Case Study: Is Bottled Water the Answer?
U.S.: some of the cleanest drinking water
Bottled water
Some from tap water
40% bacterial contamination
Fuel cost to manufacture the plastic bottles
Recycling of the plastic
240-10,000x the cost of tap water
Growing back-to-the-tap movement

54. 20-4 What Are the Major Water Pollution Problems Affecting Oceans?
Concept 20-4A The great majority of ocean pollution originates on land and includes oil and other toxic chemicals as well as solid waste, which threaten fish and wildlife and disrupt marine ecosystems.
Concept 20-4B The key to protecting the oceans is to reduce the flow of pollution from land and air and from streams emptying into these waters.

55. Ocean Pollution Is a Growing and Poorly Understood Problem (1)
2006: State of the Marine Environment
80% of marine pollution originates on land
Sewage
Coastal areas most affected
Deeper ocean waters
Dilution
Dispersion
Degradation

56. Ocean Pollution Is a Growing and Poorly Understood Problem (2)
Cruise line pollution: what is being dumped?
U.S. coastal waters
Raw sewage
Sewage and agricultural runoff: NO3- and PO43-
Harmful algal blooms
Oxygen-depleted zones
Huge mass of plastic in North Pacific Ocean

57. Residential Areas, Factories, and Farms Contribute to Pollution of Coastal Waters
Figure 20.16: Natural capital degradation.
Residential areas, factories, and farms all contribute to the pollution of coastal waters. According to the UN Environment Programme, coastal water pollution costs the world more than $30,000 a minute, primarily for health problems and premature deaths. Questions: What do you think are the three worst pollution problems shown here? For each one, how does it affect two or more of the ecological and economic services listed in Figure 8-5 (p. 172)?
Fig , p. 545

58. Industry
Nitrogen oxides
from autos and smokestacks, toxic chemicals, and heavy metals in effluents flow into bays and estuaries.
Cities
Toxic metals and oil from streets and parking lots pollute waters; sewage adds nitrogen and phosphorus.
Urban sprawl
Bacteria and viruses from sewers and septic tanks contaminate shellfish beds and close beaches; runoff of fertilizer from lawns adds nitrogen and phosphorus.
Construction sites Sediments are washed into waterways, choking fish and plants, clouding waters, and blocking sunlight.
Farms Runoff of pesticides, manure, and fertilizers adds toxins and excess nitrogen and phosphorus.
Red tides Excess nitrogen causes explosive growth of toxic microscopic
algae, poisoning fish
and marine mammals.
Closed
shellfish beds
Closed beach
Oxygen-depleted zone
Figure 20.16: Natural capital degradation.
Residential areas, factories, and farms all contribute to the pollution of coastal waters. According to the UN Environment Programme, coastal water pollution costs the world more than $30,000 a minute, primarily for health problems and premature deaths. Questions: What do you think are the three worst pollution problems shown here? For each one, how does it affect two or more of the ecological and economic services listed in Figure 8-5 (p. 172)?
Toxic sediments
Chemicals and toxic metals contaminate shellfish beds, kill spawning fish, and accumulate in the tissues of bottom feeders.
Oxygen-depleted zone
Sedimentation and algae overgrowth reduce sunlight, kill beneficial sea grasses,
use up oxygen, and degrade habitat.
Healthy zone
Clear, oxygen-rich waters promote growth of plankton and sea grasses, and support fish.
Fig , p. 545

59. Science Focus: Oxygen Depletion in the Northern Gulf Of Mexico
Severe cultural eutrophication
Oxygen-depleted zone
Overfertilized coastal area
Preventive measures
Will it reach a tipping point?

60. A Large Zone of Oxygen-Depleted Water in the Gulf of Mexico Due to Algal Blooms
Figure 20.B: Natural capital degradation.
A large zone of oxygen-depleted water (containing less than 2 ppm dissolved oxygen) forms each year in the Gulf of Mexico (lower right drawing) as a result of oxygen-depleting algal blooms caused primarily by high inputs of plant nutrients from the Mississippi River basin (top). The drawing (bottom left), based on a satellite image, shows how these inputs spread along the coast during the summer of In the image, reds and greens represent high concentrations of phytoplankton and river sediment. This problem is worsened by loss of wetlands, which would have filtered some of these plant nutrients. Question: Can you think of a product you used today that was directly connected to this sort of pollution? (Data from NASA)
Fig. 20-B, p. 546

61. Mississippi River Basin
Missouri River
Mississippi River Basin
Ohio River
Mississippi River MS
Figure 20.B: Natural capital degradation.
A large zone of oxygen-depleted water (containing less than 2 ppm dissolved oxygen) forms each year in the Gulf of Mexico (lower right drawing) as a result of oxygen-depleting algal blooms caused primarily by high inputs of plant nutrients from the Mississippi River basin (top). The drawing (bottom left), based on a satellite image, shows how these inputs spread along the coast during the summer of In the image, reds and greens represent high concentrations of phytoplankton and river sediment. This problem is worsened by loss of wetlands, which would have filtered some of these plant nutrients. Question: Can you think of a product you used today that was directly connected to this sort of pollution? (Data from NASA) LA
LOUISIANA
Mississippi River TX
Depleted oxygen
Gulf of Mexico
Gulf of Mexico
Fig. 20-B, p. 546

62. Missouri River Mississippi River Basin Ohio River Mississippi River
Depleted oxygen
Stepped Art
Fig. 20-B, p. 546

63. Ocean Pollution from Oil (1)
Crude and refined petroleum
Highly disruptive pollutants
Largest source of ocean oil pollution
Urban and industrial runoff from land
1989: Exxon Valdez, oil tanker
2010: BP explosion in the Gulf of Mexico

64. Ocean Pollution from Oil (2)
Volatile organic hydrocarbons
Kill many aquatic organisms
Tar-like globs on the ocean’s surface
Coat animals
Heavy oil components sink
Affect the bottom dwellers

65. Ocean Pollution from Oil (3)
Faster recovery from crude oil than refined oil
Cleanup procedures
Methods of preventing oil spills

66. Solutions: Coastal Water Pollution, Prevention and Cleanup
Figure 20.17: There are a number of methods for preventing or cleaning up excessive pollution of coastal waters (Concept 20-4B). Questions: Which two of these solutions do you think are the most important? Why?
Fig , p. 547

67. Coastal Water Pollution
Solutions
Coastal Water Pollution
Prevention
Cleanup
Reduce input of toxic pollutants
Improve oil-spill cleanup capabilities
Separate sewage and storm water lines
Use nanoparticles on sewage and oil spills to dissolve the oil or sewage (still under development)
Ban dumping of wastes and sewage by ships
in coastal waters
Ban dumping of hazardous material
Figure 20.17: There are a number of methods for preventing or cleaning up excessive pollution of coastal waters (Concept 20-4B). Questions: Which two of these solutions do you think are the most important? Why?
Require secondary treatment of coastal sewage
Strictly regulate coastal development, oil drilling, and oil shipping
Use wetlands, solar-aquatic, or other methods to treat sewage
Require double hulls for oil tankers
Fig , p. 547

68. Deepwater Horizon Blowout in the Gulf of Mexico, April 20, 2010
Figure 20.18: On April 20, 2010 oil and natural gas escaping from an oil-well borehole ignited and caused an explosion on the British Petroleum (BP) Deepwater Horizon drilling platform in the Gulf of Mexico. The accident sank the rig and killed 11 of its crewmembers. The ruptured wellhead released massive amounts of crude oil that contaminated ecologically vital coastal marshes (Figure 8-8, p. 174), mangroves (Figure 8-10, p. 175), sea-grass beds (Figure 8-9, p. 174) and deep ocean aquatic life. It also disrupted the livelihoods of people depending on the gulf’s coastal fisheries and caused large economic losses for the gulf’s tourism business. This disaster was caused by a combination of equipment failure, human error, failure by BP to prepare for a major oil release, and inadequate government regulation of oil drilling in the Gulf of Mexico.
Fig , p. 547

69. Case Study: The Exxon Valdez Oil Spill
1989: Alaska’s Prince William Sound
41 million liters of crude oil
5200 km of coastline
Killed 250,000 seabirds
$15 billion in damages to economy
Exxon paid $3.8 billion in damages and clean-up costs
Led to improvements in oil tanker safety and clean-up strategies

70. 20-5 How Can We Best Deal with Water Pollution?
Concept Reducing water pollution requires we prevent it, work with nature to treat sewage, cut resource use and waste, reduce poverty, and slow population growth.

71. Reducing Surface Water Pollution from Nonpoint Sources
Agriculture
Reduce erosion
Reduce the amount of fertilizers
Plant buffer zones of vegetation
Use organic farming techniques
Use pesticides prudently
Control runoff
Tougher pollution regulations for livestock operations
Deal better with animal waste

72. Laws Can Help Reduce Water Pollution from Point Sources
1972: Clean Water Act 1987: Water Quality Act
EPA: experimenting with a discharge trading policy that uses market forces
Cap and trade system
Could this allow pollutants to build up?

73. Case Study: The U.S. Experience with Reducing Point-Source Pollution (1)
Numerous improvements in water quality
Some lakes and streams are not safe for swimming or fishing
Treated wastewater still produces algal blooms
High levels of Hg, pesticides, and other toxic materials in fish

74. Case Study: The U.S. Experience with Reducing Point-Source Pollution (2)
Leakage of gasoline storage tanks into groundwater
Many violations of federal laws and regulations
Need to strengthen the Clean Water Act

75. Sewage Treatment Reduces Water Pollution (1)
Septic tank system
Wastewater or sewage treatment plants
Primary sewage treatment
Physical process
Secondary sewage treatment
Biological process with bacteria
Tertiary or advance sewage treatment
Special filtering processes
Bleaching, chlorination

76. Sewage Treatment Reduces Water Pollution (2)
Many cities violate federal standards for sewage treatment plants
Should there be separate pipes for sewage and storm runoff?
Health risks of swimming in water with blended sewage wastes

77. Solutions: Septic Tank System
Figure 20.19: Solutions.
Septic tank systems are often used for disposal of domestic sewage and wastewater in rural and suburban areas.
Fig , p. 550

78. Manhole cover (for cleanout) Septic tank Gas Distribution box Scum
Wastewater
Sludge
Drain field (gravel or crushed stone)
Figure 20.19: Solutions.
Septic tank systems are often used for disposal of domestic sewage and wastewater in rural and suburban areas.
Vent pipe
Perforated pipe
Fig , p. 550

79. Solutions: Primary and Secondary Sewage Treatment
Figure 20.20: Solutions.
Primary and secondary sewage treatment systems help to reduce water pollution. Question: What do you think should be done with the sludge produced by sewage treatment plants?
Fig , p. 551

80. Chlorine disinfection tank Bar screen Grit chamber Settling tank
Primary
Secondary
Chlorine disinfection tank
Bar screen
Grit chamber
Settling tank
Aeration tank
Settling tank
To river, lake, or ocean
Sludge
Raw sewage from sewers
Activated sludge
(kills bacteria)
Air pump
Figure 20.20: Solutions.
Primary and secondary sewage treatment systems help to reduce water pollution. Question: What do you think should be done with the sludge produced by sewage treatment plants?
Sludge digester
Disposed of
in landfill or ocean or applied to cropland, pasture, or rangeland
Sludge drying bed
Fig , p. 551

81. Sludge digester To river, lake, or ocean
Primary
Grit chamber
Bar screen
Settling tank
Secondary
Chlorine
disinfection tank
Aeration tank
Settling tank
Sludge
Disposed of in
landfill or ocean or applied to cropland,
pasture, or rangeland
Raw sewage
from sewers
Sludge digester
Sludge drying bed
(kills bacteria)
To river, lake,
or ocean
Activated sludge
Air pump
Stepped Art
Fig , p. 551

82. We Can Improve Conventional Sewage Treatment
Peter Montague: environmental scientist
Remove toxic wastes before water goes to the municipal sewage treatment plants
Reduce or eliminate use and waste of toxic chemicals
Use composting toilet systems
Wetland-based sewage treatment systems

83. Science Focus: Treating Sewage by Working with Nature
John Todd: biologist
Natural water purification system
Sewer water flows into a passive greenhouse
Solar energy and natural processes remove and recycle nutrients
Diversity of organisms used

84. Solutions: Ecological Wastewater Purification by a Living Machine, RI, U.S.
Figure 20.C: Solutions.
This is an ecological wastewater purification system called a living machine. This Solar Sewage Treatment Plant is in the U.S. city of Providence, Rhode Island. Biologist John Todd is demonstrating this ecological process he invented for purifying wastewater by using the sun and a series of tanks containing living organisms. Todd and others are conducting research to perfect such solar–aquatic sewage treatment systems based on working with nature.
Fig. 20-C, p. 553

85. There Are Sustainable Ways to Reduce and Prevent Water Pollution
Developed countries
Bottom-up political pressure to pass laws
Developing countries
Little has been done to reduce water pollution
China : ambitious plan

86. Solutions: Methods for Preventing and Reducing Water Pollution
Figure 20.21: There are a number of ways to prevent and reduce water pollution (Concept 20-5). Questions: Which two of these solutions do you think are the most important? Why?
Fig , p. 553

87. What Can You Do? Reducing Water Pollution
Figure 20.22: Individuals matter.
You can help reduce water pollution. Questions: Which three of these actions do you think are the most important? Why?
Fig , p. 554

88. Three Big Ideas
There are a number of ways to purify drinking water, but the most effective and cheapest strategy is pollution control.
The key to protecting the oceans is to reduce the flow of pollution from land and air, and from streams emptying into ocean waters.

89. Three Big Ideas
Reducing water pollution requires that we prevent it, work with nature in treating sewage, cut resource use and waste, reduce poverty, and slow population growth.