1. Aquatic Biodiversity
Chapter 8

2. Core Case Study: Why Should We Care about Coral Reefs? (1)
Biodiversity
Formation
Important ecological and economic services
Moderate atmospheric temperatures
Act as natural barriers protecting coasts from erosion
Provide habitats
Support fishing and tourism businesses
Provide jobs and building materials
Studied and enjoyed

3. Core Case Study: Why Should We Care about Coral Reefs? (2)
Degradation and decline
Coastal development
Pollution
Overfishing
Warmer ocean temperatures leading to coral bleaching
Increasing ocean acidity

4. A Healthy Coral Reef in the Red Sea

5. 8-1 What Is the General Nature of Aquatic Systems?
Concept 8-1A Saltwater and freshwater aquatic life zones cover almost three-fourths of the earth’s surface with oceans dominating the planet.
Concept 8-1B The key factors determining biodiversity in aquatic systems are temperature, dissolved oxygen content, availability of food and availability of light and nutrients necessary for photosynthesis.

6. Most of the Earth Is Covered with Water (1)
Saltwater: global ocean divided into 4 areas
Atlantic
Pacific
Arctic
Indian
Freshwater

7. Most of the Earth Is Covered with Water (2)
Aquatic life zones
Saltwater: marine
Oceans and estuaries
Coastlands and shorelines
Coral reefs
Mangrove forests
Freshwater
Lakes
Rivers and streams
Inland wetlands

8. The Ocean Planet

9. Land–ocean hemisphere
Figure 8.2
The ocean planet. The salty oceans cover 71% of the earth’s surface. Almost all of the earth’s water is in the interconnected oceans, which cover 90% of the planet’s mostly ocean hemisphere (left) and half of its land–ocean hemisphere (right). Freshwater systems cover less than 2.2% of the earth’s surface (Concept 8-1A).
Ocean hemisphere
Land–ocean hemisphere
Fig. 8-2, p. 163

10. Distribution of the World’s Major Saltwater and Freshwater Sources

11. Most Aquatic Species Live in Top, Middle, or Bottom Layers of Water (1)
Plankton
Phytoplankton
Zooplankton
Ultraplankton
Nekton
Benthos
Decomposers

12. Most Aquatic Species Live in Top, Middle, or Bottom Layers of Water (2)
Key factors in the distribution of organisms
Temperature
Dissolved oxygen content
Availability of food
Availability of light and nutrients needed for photosynthesis in the euphotic, or photic, zone

13. 8-2 Why Are Marine Aquatic Systems Important?
Concept 8-2 Saltwater ecosystems are irreplaceable reservoirs of biodiversity and provide major ecological and economic services.

14. Oceans Provide Important Ecological and Economic Resources
Reservoirs of diversity in three major life zones
Coastal zone
Usually high NPP
Open sea
Ocean bottom

15. Major Ecological and Economic Services Provided by Marine Systems

16. NATURAL CAPITAL Marine Ecosystems Ecological Services
Economic Services
Climate moderation
Food
CO2 absorption
Animal and pet feed
Nutrient cycling
Pharmaceuticals
Waste treatment
Harbors and transportation routes
Reduced storm impact (mangroves, barrier islands, coastal wetlands)
Coastal habitats for humans
Figure 8.4
Major ecological and economic services provided by marine systems (Concept 8-2). Question: Which two ecological services and which two economic services do you think are the most important? Why?
Recreation
Habitats and nursery areas
Employment
Oil and natural gas
Genetic resources and biodiversity
Minerals
Scientific information
Building materials
Fig. 8-4, p. 165

17. Natural Capital: Major Life Zones and Vertical Zones in an Ocean

18. Euphotic Zone Continental shelf
High tide
Low tide
Sun
Depth in meters
Coastal Zone
Open Sea
Sea level
Photosynthesis 50
Euphotic Zone
Estuarine Zone
100
Continental shelf
200
500
Bathyal Zone
Twilight
1,000
1,500
2,000
Water temperature drops rapidly between the euphotic zone and the abyssal zone in an area called the thermocline .
Abyssal Zone
3,000
Figure 8.5
Natural capital: major life zones and vertical zones (not drawn to scale) in an ocean. Actual depths of zones may vary. Available light determines the euphotic, bathyal and abyssal zones. Temperature zones also vary with depth, shown here by the red curve. Question: How is an ocean like a rain forest? (Hint: see Figure 7-17, p. 156.)
Darkness
4,000
5,000
10,000 5 10 15 20 25 30
Water temperature (°C)
Fig. 8-5, p. 166

19. Estuaries and Coastal Wetlands Are Highly Productive (1)
River mouths
Inlets
Bays
Sounds
Salt marshes
Mangrove forests
Seagrass Beds
Support a variety of marine species
Stabilize shorelines
Reduce wave impact

20. Estuaries and Coastal Wetlands Are Highly Productive (2)
Important ecological and economic services
Coastal aquatic systems maintain water quality by filtering
Toxic pollutants
Excess plant nutrients
Sediments
Absorb other pollutants
Provide food, timber, fuelwood, and habitats
Reduce storm damage and coast erosion

21. View of an Estuary from Space

22. Some Components and Interactions in a Salt Marsh Ecosystem in a Temperate Area

23. Short-billed dowitcher
Herring gulls
Peregrine falcon
Snowy egret
Cordgrass
Short-billed dowitcher
Phytoplankton
Marsh periwinkle
Smelt
Figure 8.7
Some components and interactions in a salt marsh ecosystem in a temperate area such as the United States. When these organisms die, decomposers break down their organic matter into minerals used by plants. Colored arrows indicate transfers of matter and energy between consumers (herbivores), secondary or higher-level consumers (carnivores), and decomposers. Organisms are not drawn to scale. The photo shows a salt marsh in Peru.
Zooplankton and small crustaceans
Soft-shelled clam
Bacteria
Clamworm
Producer to primary consumer
Primary to secondary consumer
Secondary to higher-level consumer
All consumers and producers to decomposers
Fig. 8-7a, p. 167

24. Figure 8.7
Some components and interactions in a salt marsh ecosystem in a temperate area such as the United States. When these organisms die, decomposers break down their organic matter into minerals used by plants. Colored arrows indicate transfers of matter and energy between consumers (herbivores), secondary or higher-level consumers (carnivores), and decomposers. Organisms are not drawn to scale. The photo shows a salt marsh in Peru.
Fig. 8-7b, p. 167

25. Mangrove Forest in Daintree National Park in Queensland, Australia

26. Rocky and Sandy Shores Host Different Types of Organisms
Intertidal zone
Rocky shores
Sandy shores: barrier beaches
Organism adaptations necessary to deal with daily salinity and moisture changes
Importance of sand dunes

27. Living between the Tides

28. Rocky Shore Beach Barrier Beach Sea star Hermit crab Shore crab
High tide
Periwinkle
Sea urchin
Anemone
Mussel
Low tide
Sculpin
Barnacles
Kelp
Sea lettuce
Rocky Shore Beach
Monterey flatworm
Beach flea
Nudibranch
Peanut worm
Tiger beetle
Blue crab
Clam
Dwarf olive
High tide
Figure 8.9
Living between the tides. Some organisms with specialized niches found in various zones on rocky shore beaches (top) and barrier or sandy beaches (bottom). Organisms are not drawn to scale.
Sandpiper
Ghost shrimp
Silversides
Low tide
Mole shrimp
Barrier Beach
White sand macoma
Sand dollar
Moon snail
Fig. 8-9, p. 169

29. Rocky Shore Beach Barrier Beach Sea star Hermit crab Shore crab
High tide
Periwinkle
Sea urchin
Anemone
Mussel
Low tide
Sculpin
Barnacles
Kelp
Sea lettuce
Monterey flatworm
Nudibranch
Beach flea
Peanut worm
Tiger beetle
Barrier Beach
Blue crab
Clam
Dwarf olive
High tide
Sandpiper
Ghost shrimp
Silversides
Low tide
Mole shrimp
White sand macoma
Sand dollar
Moon snail
Figure 8.9
Living between the tides. Some organisms with specialized niches found in various zones on rocky shore beaches (top) and barrier or sandy beaches (bottom). Organisms are not drawn to scale.
Stepped Art
Fig. 8-9, p. 169

30. Primary and Secondary Dunes

31. Limited recreation and walkways Most suitable for development
Ocean
Beach
Primary Dune
Trough
Secondary Dune
Back Dune
Bay or Lagoon
Recreation, no building
Walkways, no building
Limited recreation and walkways
Walkways, no building
Most suitable for development
Recreation
Bay shore
Grasses or shrubs
Taller shrubs
Figure 8.10
Primary and secondary dunes on gently sloping sandy barrier beaches help protect land from erosion by the sea. The roots of grasses that colonize the dunes hold the sand in place. Ideally, construction is allowed only behind the second strip of dunes, and walkways to the ocean beach are built so as not to damage the dunes. This helps to preserve barrier beaches and to protect buildings from damage by wind, high tides, beach erosion, and flooding from storm surges. Such protection is rare in some coastal areas because the short-term economic value of oceanfront land is considered much higher than its long-term ecological value. Rising sea levels from global warming may put many barrier beaches under water by the end of this century. Question: Do you think that the long and short-term ecological values of oceanfront dunes outweigh the short-term economic value of removing them for coastal development? Explain.
Taller shrubs and trees
Fig. 8-10, p. 170

32. Coral Reefs Are Amazing Centers of Biodiversity
Marine equivalent of tropical rain forests
Habitats for one-fourth of all marine species

33. Natural Capital: Some Components and Interactions in a Coral Reef Ecosystem

34. Green sea turtle Banded coral shrimp Symbiotic algae
Gray reef shark
Sea nettle
Green sea turtle
Parrot fish
Blue tang
Fairy basslet
Sergeant major
Algae
Brittle star
Hard corals
Banded coral shrimp
Phytoplankton
Coney
Symbiotic algae
Coney
Zooplankton
Figure 8.11
Natural capital: some components and interactions in a coral reef ecosystem. When these organisms die, decomposers break down their organic matter into minerals used by plants. Colored arrows indicate transfers of matter and energy between producers, primary consumers (herbivores), secondary or higher-level consumers (carnivores), and decomposers. Organisms are not drawn to scale.
Blackcap basslet
Sponges
Moray eel
Bacteria
Producer to primary consumer
Primary to secondary consumer
Secondary to higher-level consumer
All consumers and producers to decomposers
Fig. 8-11, p. 171

35. The Open Sea and Ocean Floor Host a Variety of Species
Vertical zones of the open sea
Euphotic zone
Bathyal zone
Abyssal zone: receives marine snow
Deposit feeders
Filter feeders
Upwellings
Primary productivity and NPP

36. Animation: Ocean provinces

37. Video: Elephant seals

38. Video: Florida reefs

39. Video: Giant clam

40. Video: Reef fish (Bahamas)

41. Video: Schooling fish

42. Video: Sea anemones

43. Video: Sea lions

44. Video: Sting rays

45. 8-3 How Have Human Activities Affected Marine Ecosystems?
Concept 8-3 Human activities threaten aquatic biodiversity and disrupt ecological and economic services provided by saltwater systems.

46. Human Activities Are Disrupting and Degrading Marine Systems
Major threats to marine systems
Coastal development
Overfishing
Runoff of nonpoint source pollution
Point source pollution
Habitat destruction
Introduction of invasive species
Climate change from human activities
Pollution of coastal wetlands and estuaries

47. Case Study: The Chesapeake Bay—an Estuary in Trouble (1)
Largest estuary in the US; polluted since 1960
Population increased
Point and nonpoint sources raised pollution
Phosphate and nitrate levels too high

48. Case Study: The Chesapeake Bay—an Estuary in Trouble (2)
Overfishing
1983: Chesapeake Bay Program
Update on recovery of the Bay
Should we introduce an Asian oyster? 48

49. Chesapeake Bay

50. Video: ABC News: Beach pollution

51. 8-4 Why Are Freshwater Ecosystems Important?
Concept 8-4 Freshwater ecosystems provide major ecological and economic services and are irreplaceable reservoirs of biodiversity.

52. Water Stands in Some Freshwater Systems and Flows in Others (1)
Standing (lentic) bodies of freshwater
Lakes
Ponds
Inland wetlands
Flowing (lotic) systems of freshwater
Streams
Rivers

53. Water Stands in Some Freshwater Systems and Flows in Others (2)
Formation of lakes
Four zones based on depth and distance from shore
Littoral zone
Limnetic zone
Profundal zone
Benthic zone

54. Major Ecological and Economic Services Provided by Freshwater Systems

55. NATURAL CAPITAL Freshwater Systems Ecological Services
Economic Services
Climate moderation
Food
Nutrient cycling
Drinking water
Waste treatment
Irrigation water
Flood control
Hydroelectricity
Figure 8.14
Major ecological and economic services provided by freshwater systems (Concept 8-4). Question: Which two ecological services and which two economic services do you think are the most important? Why?
Groundwater recharge
Habitats for many species
Transportation corridors
Genetic resources and biodiversity
Recreation
Scientific information
Employment
Fig. 8-14, p. 174

56. Distinct Zones of Life in a Fairly Deep Temperate Zone Lake

57. Sunlight Blue-winged teal Painted turtle Green frog Muskrat Pond snail
Littoral zone
Plankton
Figure 8.15
Distinct zones of life in a fairly deep temperate zone lake. See an animation based on this figure at CengageNOW. Question: How are deep lakes like tropical rain forests? (Hint: See Figure 7-17, p. 156)
Limnetic zone
Diving beetle
Profundal zone
Northern pike
Benthic zone
Yellow perch
Bloodworms
Fig. 8-15, p. 175

58. Some Lakes Have More Nutrients Than Others
Oligotrophic lakes
Low levels of nutrients and low NPP
Eutrophic lakes
High levels of nutrients and high NPP
Mesotrophic lakes
Cultural eutrophication leads to hypereutrophic lakes

59. The Effect of Nutrient Enrichment on a Lake

60. Figure 8.16
The effect of nutrient enrichment on a lake. Crater Lake in the U.S. state of Oregon (left) is an example of an oligotrophic lake that is low in nutrients. Because of the low density of plankton, its water is quite clear. The lake on the right, found in western New York State, is a eutrophic lake. Because of an excess of plant nutrients, its surface is covered with mats of algae and cyanobacteria.
Stepped Art
Fig. 8-16a, p. 175

61. Freshwater Streams and Rivers Carry Water from the Mountains to the Oceans
Surface water
Runoff
Watershed, drainage basin
Three aquatic life zones
Source zone
Transition zone
Floodplain zone

62. Three Zones in the Downhill Flow of Water

63. Lake Rain and snow Glacier Rapids Waterfall Tributary Flood plain
Oxbow lake
Salt marsh
Deposited sediment
Delta
Ocean
Source Zone
Transition Zone
Figure 8.17
Three zones in the downhill flow of water: source zone containing mountain (headwater) streams; transition zone containing wider, lower-elevation streams; and floodplain zone containing rivers, which empty into the ocean.
Water
Sediment
Floodplain Zone
Fig. 8-17, p. 176

64. Lake Rain and snow Glacier Rapids Waterfall Tributary Flood plain
Source Zone
Transition Zone
Tributary
Flood plain
Oxbow lake
Salt marsh
Delta
Deposited sediment
Ocean
Water
Sediment
Floodplain Zone
Figure 8.17
Three zones in the downhill flow of water: source zone containing mountain (headwater) streams; transition zone containing wider, lower-elevation streams; and floodplain zone containing rivers, which empty into the ocean.
Stepped Art
Fig. 8-17, p. 176

65. Case Study: Dams, Deltas, Wetlands, Hurricanes, and New Orleans
Coastal deltas, mangrove forests, and coastal wetlands: natural protection against storms
Dams and levees reduce sediments in deltas: significance?
New Orleans, Louisiana, and Hurricane Katrina: August 29, 2005
Global warming, sea rise, and New Orleans

66. New Orleans, Louisiana, (U.S.) and Hurricane Katrina

67. Projection of New Orleans if the Sea Level Rises 0.9 Meter

68. Freshwater Inland Wetlands Are Vital Sponges (1)
Marshes
Swamps
Prairie potholes
Floodplains
Arctic tundra in summer

69. Freshwater Inland Wetlands Are Vital Sponges (2)
Provide free ecological and economic services
Filter and degrade toxic wastes
Reduce flooding and erosion
Help to replenish streams and recharge groundwater aquifers
Biodiversity
Food and timber
Recreation areas

70. Active Figure: Lake zonation

71. Animation: Lake turnover

72. Animation: Trophic natures of lakes

73. Video: River flyover

74. 8-5 How Have Human Activities Affected Freshwater Ecosystems?
Concept 8-5 Human activities threaten biodiversity and disrupt ecological and economic services provided by freshwater lakes, rivers, and wetlands.

75. Human Activities Are Disrupting and Degrading Freshwater Systems
Impact of dams and canals on rivers
Impact of flood control levees and dikes along rivers
Impact of pollutants from cities and farms on rivers
Impact of drained wetlands

76. Case Study: Inland Wetland Losses in the United States
Loss of wetlands has led to
Increased flood and drought damage
Lost due to
Growing crops
Mining
Forestry
Oil and gas extraction
Building highways
Urban development