1. Conservation Biology and Global Change
Chapter 56
Conservation Biology and Global Change

2. Overview: Striking Gold
Scientists have named and described 1.8 million species
Biologists estimate 10–100 million species exist on Earth
Tropical forests contain some of the greatest concentrations of species and are being destroyed at an alarming rate
Humans are rapidly pushing many species toward extinction
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3. Figure 56.1
Figure 56.1 What will be the fate of this newly described bird species?

4. Figure 56.2
Figure 56.2 Tropical deforestation in West Kalimantan, an Indonesian province.

5. Conservation biology, which seeks to preserve life, integrates several fields
Ecology
Physiology
Molecular biology
Genetics
Evolutionary biology
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6. Concept 56.1: Human activities threaten Earth’s biodiversity
Rates of species extinction are difficult to determine under natural conditions
The high rate of species extinction is largely a result of ecosystem degradation by humans
Humans are threatening Earth’s biodiversity
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7. Three Levels of Biodiversity
Biodiversity has three main components
Genetic diversity
Species diversity
Ecosystem diversity
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8. Genetic diversity in a vole population Species diversity in a coastal
Figure 56.3
Genetic diversity
in a vole population
Species diversity
in a coastal
redwood ecosystem
Figure 56.3 Three levels of biodiversity.
Community and
ecosystem diversity
across the
landscape of
an entire region

9. Genetic Diversity
Genetic diversity comprises genetic variation within a population and between populations
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10. Species Diversity
Species diversity is the variety of species in an ecosystem or throughout the biosphere
According to the U.S. Endangered Species Act
An endangered species is “in danger of becoming extinct throughout all or a significant portion of its range”
A threatened species is likely to become endangered in the foreseeable future
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11. Extinction may be local or global
Conservation biologists are concerned about species loss because of alarming statistics regarding extinction and biodiversity
Globally, 12% of birds, 21% of mammals, and 32% of amphibians are threatened with extinction
Extinction may be local or global
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12. Philippine eagle Yangtze River dolphin Javan rhinoceros Figure 56.4
Figure 56.4 A hundred heartbeats from extinction.
Javan
rhinoceros

13. Philippine eagle Figure 56.4a
Figure 56.4 A hundred heartbeats from extinction.
Philippine eagle

14. Yangtze River dolphin Figure 56.4b
Figure 56.4 A hundred heartbeats from extinction.
Yangtze River dolphin

15. Javan rhinoceros Figure 56.4c
Figure 56.4 A hundred heartbeats from extinction.
Javan rhinoceros

16. Ecosystem Diversity
Human activity is reducing ecosystem diversity, the variety of ecosystems in the biosphere
More than 50% of wetlands in the contiguous United States have been drained and converted to other ecosystems
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17. The local extinction of one species can have a negative impact on other species in an ecosystem
For example, flying foxes (bats) are important pollinators and seed dispersers in the Pacific Islands
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18. Figure 56.5
Figure 56.5 The endangered Marianas “flying fox” bat (Pteropus mariannus), an important pollinator.

19. Biodiversity and Human Welfare
Human biophilia allows us to recognize the value of biodiversity for its own sake
Species diversity brings humans practical benefits
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20. Benefits of Species and Genetic Diversity
Species related to agricultural crops can have important genetic qualities
For example, plant breeders bred virus-resistant commercial rice by crossing it with a wild population
In the United States, 25% of prescriptions contain substances originally derived from plants
For example, the rosy periwinkle contains alkaloids that inhibit cancer growth
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21. Figure 56.6
Figure 56.6 The rosy periwinkle (Catharanthus roseus), a plant that saves lives.

22. The loss of species also means loss of genes and genetic diversity
The enormous genetic diversity of organisms has potential for great human benefit
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23. Ecosystem Services
Ecosystem services encompass all the processes through which natural ecosystems and their species help sustain human life
Some examples of ecosystem services
Purification of air and water
Detoxification and decomposition of wastes
Cycling of nutrients
Moderation of weather extremes
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24. Threats to Biodiversity
Most species loss can be traced to four major threats
Habitat destruction
Introduced species
Overharvesting
Global change
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25. Habitat Loss
Human alteration of habitat is the greatest threat to biodiversity throughout the biosphere
In almost all cases, habitat fragmentation and destruction lead to loss of biodiversity
For example
In Wisconsin, prairie occupies <0.1% of its original area
About 93% of coral reefs have been damaged by human activities
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26. Figure 56.7
Figure 56.7 Habitat fragmentation in the foothills of Los Angeles.

27. Introduced Species
Introduced species are those that humans move from native locations to new geographic regions
Without their native predators, parasites, and pathogens, introduced species may spread rapidly
Introduced species that gain a foothold in a new habitat usually disrupt their adopted community
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28. Sometimes humans introduce species by accident
For example, the brown tree snake arrived in Guam as a cargo ship “stowaway” and led to extinction of some local species
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29. (a) Brown tree snake (b) Kudzu Figure 56.8
Figure 56.8 Two introduced species.
(b) Kudzu

30. Figure 56.8a
Figure 56.8 Two introduced species.
(a) Brown tree snake

31. Humans have deliberately introduced some species with good intentions but disastrous effects
For example, kudzu was intentionally introduced to the southern United States
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32. Figure 56.8b
Figure 56.8 Two introduced species.
(b) Kudzu

33. Overharvesting
Overharvesting is human harvesting of wild plants or animals at rates exceeding the ability of populations of those species to rebound
Large organisms with low reproductive rates are especially vulnerable to overharvesting
For example, elephant populations declined because of harvesting for ivory
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34. DNA analysis can help conservation biologists identify the source of illegally obtained animal products
For example, DNA from illegally harvested ivory can be used to trace the original population of elephants to within a few hundred kilometers
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35. Figure 56.9
Figure 56.9 Impact: Forensic Ecology and Elephant Poaching

36. Overfishing has decimated wild fish populations
For example, the North Atlantic bluefin tuna population decreased by 80% in ten years
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37. Figure 56.10
Figure Overharvesting.

38. Global Change
Global change includes alterations in climate, atmospheric chemistry, and broad ecological systems
Acid precipitation contains sulfuric acid and nitric acid from the burning of wood and fossil fuels
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39. Acid precipitation kills fish and other lake-dwelling organisms
Air pollution from one region can result in acid precipitation downwind
For example, industrial pollution in the midwestern United States caused acid rain in eastern Canada in the 1960s
Acid precipitation kills fish and other lake-dwelling organisms
Environmental regulations have helped to decrease acid precipitation
For example, sulfur dioxide emissions in the United States decreased 31% between 1993 and 2002
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40. Figure 56.11
4.7
4.6
4.5
4.4 pH
4.3
4.2
4.1
Figure Changes in the pH of precipitation at Hubbard Brook, New Hampshire.
4.0
1960
‘65
‘70
‘75
‘80
‘85
‘90
‘95
2000
‘05
‘10
Year

41. Concept 56.2: Population conservation focuses on population size, genetic diversity, and critical habitat
Biologists focusing on conservation at the population and species levels follow two main approaches
The small-population approach
The declining-population approach
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42. Small-Population Approach
The small-population approach studies processes that can make small populations become extinct
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43. The Extinction Vortex: Evolutionary Implications of Small Population Size
A small population is prone to inbreeding and genetic drift, which draw it down an extinction vortex
The key factor driving the extinction vortex is loss of the genetic variation necessary to enable evolutionary responses to environmental change
Small populations and low genetic diversity do not always lead to extinction
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44. Small population Genetic Inbreeding drift Lower reproduction Higher
Figure 56.12
Small
population
Genetic
drift
Inbreeding
Lower
reproduction
Higher
mortality
Loss of
genetic
variability
Figure Processes driving an extinction vortex.
Reduction in
individual
fitness and
population
adaptability
Smaller
population

45. Case Study: The Greater Prairie Chicken and the Extinction Vortex
Populations of the greater prairie chicken were fragmented by agriculture and later found to exhibit decreased fertility
To test the extinction vortex hypothesis, scientists imported genetic variation by transplanting birds from larger populations
The declining population rebounded, confirming that low genetic variation had been causing an extinction vortex
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46. (a) Population dynamics
Figure 56.13
RESULTS
200
150
Number of male birds
100
Translocation 50
1970
1975
1980
1985
1990
1995
Year
(a) Population dynamics
100 90 80 70 60 50 40 30
Figure Inquiry: What caused the drastic decline of the Illinois greater prairie chicken population?
Eggs hatched (%)
1970–‘74
‘75–‘79
‘80–‘84
‘85–‘89
‘90
‘93–‘97
Year
(b) Hatching rate

47. (a) Population dynamics
Figure 56.13a
RESULTS
200
150
Number of male birds
100
Translocation 50
Figure Inquiry: What caused the drastic decline of the Illinois greater prairie chicken population?
1970
1975
1980
1985
1990
1995
Year
(a) Population dynamics

48. 100 90 80 70 60 50 40 30 Eggs hatched (%) 1970–‘74 ‘75–‘79 ‘80–‘84
Figure 56.13b
RESULTS
100 90 80 70 60 50 40 30
Eggs hatched (%)
Figure Inquiry: What caused the drastic decline of the Illinois greater prairie chicken population?
1970–‘74
‘75–‘79
‘80–‘84
‘85–‘89
‘90
‘93–‘97
Year
(b) Hatching rate

49. Figure 56.13c
Figure Inquiry: What caused the drastic decline of the Illinois greater prairie chicken population?

50. Minimum Viable Population Size
Minimum viable population (MVP) is the minimum population size at which a species can survive
The MVP depends on factors that affect a population’s chances for survival over a particular time
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51. Effective Population Size
A meaningful estimate of MVP requires determining the effective population size, which is based on the population’s breeding potential
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52. Ne = Nf + Nm Effective population size (Ne) is estimated by 4NfNm
where Nf and Nm are the number of females and the number of males, respectively, that breed successfully
Viability analysis is used to predict a population’s chances for survival over a particular time interval
4NfNm
Nf + Nm
Ne =
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53. Case Study: Analysis of Grizzly Bear Populations
One of the first population viability analyses was conducted as part of a long-term study of grizzly bears in Yellowstone National Park
It is estimated that a population of 100 bears would have a 95% chance of surviving about 200 years
This grizzly population is about 400, but the Ne is about 100
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54. Figure 56.14
Figure Long-term monitoring of a grizzly bear population.

55. The Yellowstone grizzly population has low genetic variability compared with other grizzly populations
Introducing individuals from other populations would increase the numbers and genetic variation
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56. Declining-Population Approach
The declining-population approach
Focuses on threatened and endangered populations that show a downward trend, regardless of population size
Emphasizes the environmental factors that caused a population to decline
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57. Steps for Analysis and Intervention
The declining-population approach involves several steps
Confirm that the population is in decline
Study the species’ natural history
Develop hypotheses for all possible causes of decline
Test the hypotheses in order of likeliness
Apply the results of the diagnosis to manage for recovery
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58. Case Study: Decline of the Red-Cockaded Woodpecker
Red-cockaded woodpeckers require living trees in mature pine forests
These woodpeckers require forests with little undergrowth
Logging, agriculture, and fire suppression have reduced suitable habitat
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59. Red-cockaded woodpecker
Figure 56.15
Red-cockaded woodpecker
Figure A habitat requirement of the red-cockaded woodpecker.
(a) Forests with low undergrowth
(b) Forests with high, dense undergrowth

60. (a) Forests with low undergrowth
Figure 56.15a
Figure A habitat requirement of the red-cockaded woodpecker.
(a) Forests with low undergrowth

61. They have a complex social structure where one breeding pair has up to four “helper” individuals
Individuals often have a better chance of reproducing by helping and waiting for an available cavity, instead of excavating new cavities
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62. (b) Forests with high, dense undergrowth
Figure 56.15b
Figure A habitat requirement of the red-cockaded woodpecker.
(b) Forests with high, dense undergrowth

63. Red-cockaded woodpecker Figure 56.15c
Figure A habitat requirement of the red-cockaded woodpecker.
Red-cockaded
woodpecker

64. In a study where breeding cavities were constructed, new breeding groups formed only in these sites
Based on this experiment, a combination of habitat maintenance and excavation of breeding cavities enabled this endangered species to rebound
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65. Weighing Conflicting Demands
Conserving species often requires resolving conflicts between habitat needs of endangered species and human demands
For example, in the U.S. Pacific Northwest, habitat preservation for many species is at odds with timber and mining industries
Managing habitat for one species might have positive or negative effects on other species
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66. Concept 56.3: Landscape and regional conservation help sustain biodiversity
Conservation biology has attempted to sustain the biodiversity of entire communities, ecosystems, and landscapes
Ecosystem management is part of landscape ecology, which seeks to make biodiversity conservation part of land-use planning
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67. Landscape Structure and Biodiversity
The structure of a landscape can strongly influence biodiversity
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68. Fragmentation and Edges
The boundaries, or edges, between ecosystems are defining features of landscapes
Some species take advantage of edge communities to access resources from both adjacent areas
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69. (b) Edges created by human activity
Figure 56.16
(a) Natural edges
Figure Edges between ecosystems.
(b) Edges created by human activity

70. Figure 56.16a
Figure Edges between ecosystems.
(a) Natural edges

71. (b) Edges created by human activity
Figure 56.16b
Figure Edges between ecosystems.
(b) Edges created by human activity

72. The Biological Dynamics of Forest Fragments Project in the Amazon examines the effects of fragmentation on biodiversity
Landscapes dominated by fragmented habitats support fewer species due to a loss of species adapted to habitat interiors
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73. Figure 56.17
Figure Amazon rain forest fragments created as part of the Biological Dynamics of Forest Fragments Project.

74. Corridors That Connect Habitat Fragments
A movement corridor is a narrow strip of quality habitat connecting otherwise isolated patches
Movement corridors promote dispersal and help sustain populations
In areas of heavy human use, artificial corridors are sometimes constructed
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75. Figure 56.18
Figure An artificial corridor.

76. Establishing Protected Areas
Conservation biologists apply understanding of ecological dynamics in establishing protected areas to slow the loss of biodiversity
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77. Preserving Biodiversity Hot Spots
A biodiversity hot spot is a relatively small area with a great concentration of endemic species and many endangered and threatened species
Biodiversity hot spots are good choices for nature reserves, but identifying them is not always easy
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78. Hot spots can change with climate change
Designation of hot spots is often biased toward saving vertebrates and plants
Hot spots can change with climate change
Video: Coral Reef
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79. Terrestrial biodiversity hot spots Marine biodiversity hot spots
Figure 56.19
Terrestrial biodiversity
hot spots
Marine biodiversity
hot spots
Equator
Figure Earth’s terrestrial and marine biodiversity hot spots.

80. Philosophy of Nature Reserves
Nature reserves are biodiversity islands in a sea of habitat degraded by human activity
Nature reserves must consider disturbances as a functional component of all ecosystems
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81. An important question is whether to create fewer large reserves or more numerous small reserves
One argument for large reserves is that large, far-ranging animals with low-density populations require extensive habitats
Smaller reserves may be more realistic and may slow the spread of disease throughout a population
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82. 50 100 Kilometers ows R. Yell tone MONTANA ne Sho sho R. WYOMING
Figure 56.20 50
100
Kilometers
ows R.
Yell
tone
MONTANA ne
Sho
sho R.
WYOMING
Yellowstone
National
Park
MONTANA
IDAHO
Figure Biotic boundaries for grizzly bears in Yellowstone and Grand Teton National Parks.
Grand Teton
National Park
Snake R.
Biotic boundary for
short-term survival;
MVP is 50 individuals.
IDAHO
WYOMING
Biotic boundary for
long-term survival;
MVP is 500 individuals.

83. Zoned Reserves
The zoned reserve model recognizes that conservation often involves working in landscapes that are largely human dominated
A zoned reserve includes relatively undisturbed areas and the modified areas that surround them and that serve as buffer zones
Zoned reserves are often established as “conservation areas”
Costa Rica has become a world leader in establishing zoned reserves
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84. Figure 56.21 Zoned reserves in Costa Rica.
Nicaragua
CARIBBEAN SEA
Costa
Rica
National park land
Buffer zone
Pan
ama
PACIFIC OCEAN
(a) Zoned reserves in Costa Rica
Figure Zoned reserves in Costa Rica.
(b) Tourists in one of Costa Rica’s zoned reserves

85. (a) Zoned reserves in Costa Rica
Figure 56.21a
Nicaragua
CARIBBEAN SEA
Costa
Rica
National park land
Buffer zone
Pan
ama
Figure Zoned reserves in Costa Rica.
PACIFIC OCEAN
(a) Zoned reserves in Costa Rica

86. (b) Tourists in one of Costa Rica’s zoned reserves
Figure 56.21b
Figure Zoned reserves in Costa Rica.
(b) Tourists in one of Costa Rica’s zoned reserves

87. Some zoned reserves in the Fiji islands are closed to fishing, which actually improves fishing success in nearby areas
The United States has adopted a similar zoned reserve system with the Florida Keys National Marine Sanctuary
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88. GULF OF MEXICO FLORIDA Florida Keys National Marine Sanctuary 50 km
Figure 56.22
GULF OF MEXICO
FLORIDA
Florida Keys National
Marine Sanctuary
50 km
Figure A diver measuring coral in the Florida Keys National Marine Sanctuary.

89. Figure 56.22a
Figure A diver measuring coral in the Florida Keys National Marine Sanctuary.

90. Concept 56.4: Earth is changing rapidly as a result of human actions
The locations of preserves today may be unsuitable for their species in the future
Human-caused changes in the environment include
Nutrient enrichment
Accumulation of toxins
Climate change
Ozone depletion
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91. Nutrient Enrichment
In addition to transporting nutrients from one location to another, humans have added new materials, some of them toxins, to ecosystems
Harvest of agricultural crops exports nutrients from the agricultural ecosystem
Agriculture leads to the depletion of nutrients in the soil
Fertilizers add nitrogen and other nutrients to the agricultural ecosystem
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92. Figure 56.23
Figure Fertilization of a corn (maize) crop.

93. Critical load is the amount of added nutrient that can be absorbed by plants without damaging ecosystem integrity
Nutrients that exceed the critical load leach into groundwater or run off into aquatic ecosystems
Agricultural runoff and sewage lead to phytoplankton blooms in the Atlantic Ocean
Decomposition of phytoplankton blooms causes “dead zones” due to low oxygen levels
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94. Figure 56.24
Figure A phytoplankton bloom arising from nitrogen pollution in the Mississippi basin that leads to a dead zone.
Winter
Summer

95. Figure 56.24a
Figure A phytoplankton bloom arising from nitrogen pollution in the Mississippi basin that leads to a dead zone.
Winter

96. Figure 56.24b
Figure A phytoplankton bloom arising from nitrogen pollution in the Mississippi basin that leads to a dead zone.
Summer

97. Toxins in the Environment
Humans release many toxic chemicals, including synthetics previously unknown to nature
In some cases, harmful substances persist for long periods in an ecosystem
One reason toxins are harmful is that they become more concentrated in successive trophic levels
Biological magnification concentrates toxins at higher trophic levels, where biomass is lower
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98. PCBs and many pesticides such as DDT are subject to biological magnification in ecosystems
Herring gulls of the Great Lakes lay eggs with PCB levels 5,000 times greater than in phytoplankton
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99. Herring gull eggs 124 ppm Concentration of PCBs Lake trout 4.83 ppm
Figure 56.25
Herring gull eggs
124 ppm
Concentration of PCBs
Lake trout
4.83 ppm
Smelt
1.04 ppm
Figure Biological magnification of PCBs in a Great Lakes food web.
Zooplankton
0.123 ppm
Phytoplankton
0.025 ppm

100. DDT was banned in the United States in 1971
In the 1960s Rachel Carson brought attention to the biomagnification of DDT in birds in her book Silent Spring
DDT was banned in the United States in 1971
Countries with malaria face a trade-off between killing mosquitoes (malarial vectors) and protecting other species
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101. Figure 56.26
Figure Rachel Carson.

102. Greenhouse Gases and Global Warming
One pressing problem caused by human activities is the rising level of atmospheric CO2
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103. Rising Atmospheric CO2 Levels
Due to burning of fossil fuels and other human activities, the concentration of atmospheric CO2 has been steadily increasing
Most plants grow faster when CO2 concentrations increase
C3 plants (for example, wheat and soybeans) are more limited by CO2 than C4 plants (for example, corn)
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104. CO2 concentration (ppm) Average global temperature (°C)
Figure 56.27
14.9
14.8
14.7
14.6
14.5
14.4
14.3
14.2
14.1
14.0
13.9
13.8
13.7
13.6
390
380
370
360
350
340
330
320
310
300
Temperature
CO2 concentration (ppm)
Average global temperature (°C)
CO2
Figure Increase in atmospheric carbon dioxide concentration at Mauna Loa, Hawaii, and average global temperatures.
Year

105. How Elevated CO2 Levels Affect Forest Ecology: The FACTS-I Experiment
The FACTS-I experiment is testing how elevated CO2 influences tree growth, carbon concentration in soils, insect populations, soil moisture, and other factors
The CO2-enriched plots produced more wood than the control plots, though less than expected
The availability of nitrogen and other nutrients appears to limit tree growth and uptake of CO2
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106. Figure 56.28
Figure Large-scale experiment on the effects of elevated CO2 concentration.

107. The Greenhouse Effect and Climate
CO2, water vapor, and other greenhouse gases reflect infrared radiation back toward Earth; this is the greenhouse effect
This effect is important for keeping Earth’s surface at a habitable temperature
Increasing concentration of atmospheric CO2 is linked to increasing global temperature
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108. Climatologists can make inferences about past environments and their climates
Pollen and fossil plant records reveal past vegetation
CO2 levels are inferred from bubbles trapped in glacial ice
Chemical isotope analysis is used to infer past temperature
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109. Northern coniferous forests and tundra show the strongest effects of global warming
For example, in 2007 the extent of Arctic sea ice was the smallest on record
A warming trend would also affect the geographic distribution of precipitation
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110. Many organisms may not be able to survive rapid climate change
Some ecologists support assisted migration, the translocation of a species to a favorable habitat beyond its native range
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111. Stabilizing CO2 emissions will require an international effort
Global warming can be slowed by reducing energy needs and converting to renewable sources of energy
Stabilizing CO2 emissions will require an international effort
Recent international negotiations have yet to reach a consensus on a global strategy to reduce greenhouse gas emissions
Reduced deforestation would also decrease greenhouse gas emissions
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112. Depletion of Atmospheric Ozone
Life on Earth is protected from damaging effects of UV radiation by a protective layer of ozone molecules in the atmosphere
Satellite studies suggest that the ozone layer has been gradually thinning since the mid-1970s
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113. Ozone layer thickness (Dobsons)
Figure 56.29
350
300
250
200
150
100
Ozone layer thickness (Dobsons)
Figure Thickness of the October ozone layer over Antarctica in units called Dobsons.
1955 ‘60
‘65 ‘70 ‘75
‘80
‘85
‘90 ‘ ‘05 ‘10
Year

114. CFCs contain chlorine, which reacts with ozone to make O2
Destruction of atmospheric ozone results mainly from chlorofluorocarbons (CFCs) produced by human activity
CFCs contain chlorine, which reacts with ozone to make O2
This decreases the amount of ozone in the atmosphere
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115. Chlorine atom O2 Chlorine O3 CIO O2 CIO CI2O2 Sunlight Figure 56.30
Figure How free chlorine in the atmosphere destroys ozone.
CI2O2
Sunlight

116. The ozone layer is thinnest over Antarctica and southern Australia, New Zealand, and South America
Ozone levels have decreased 2–10% at mid-latitudes during the past 20 years
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117. September 1979 September 2009 Figure 56.31
Figure Erosion of Earth’s ozone shield.
September 1979
September 2009

118. Figure 56.31a
Figure Erosion of Earth’s ozone shield.
September 1979

119. Figure 56.31b
Figure Erosion of Earth’s ozone shield.
September 2009

120. Ozone depletion causes DNA damage in plants and poorer phytoplankton growth
An international agreement signed in 1987 has resulted in a decrease in ozone depletion
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121. Concept 56.5: Sustainable development can improve human lives while conserving biodiversity
The concept of sustainability helps ecologists establish long-term conservation priorities
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122. Sustainable Biosphere Initiative
Sustainable development is development that meets the needs of people today without limiting the ability of future generations to meet their needs
The goal of the Sustainable Biosphere Initiative is to define and acquire basic ecological information for responsible development, management, and conservation of Earth’s resources
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123. Sustainable development requires connections between life sciences, social sciences, economics, and humanities
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124. Case Study: Sustainable Development in Costa Rica
Costa Rica’s conservation of tropical biodiversity involves partnerships between the government, nongovernmental organizations (NGOs), and private citizens
Human living conditions (infant mortality, life expectancy, literacy rate) in Costa Rica have improved along with ecological conservation
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125. Life expectancy (years) Infant mortality (per 1,000 live births)
Figure 56.32
200
150
100 50 80 70 60 50 40 30
Life expectancy
Infant mortality
Life expectancy (years)
Infant mortality (per 1,000 live births)
Figure Infant mortality and life expectancy at birth in Costa Rica.
Year

126. The Future of the Biosphere
Our lives differ greatly from those of early humans, who hunted and gathered and painted on cave walls
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127. (a) Detail of animals in a 36,000- year-old cave painting,
Figure 56.33
(a) Detail of animals in a 36,000-
year-old cave painting,
Lascaux, France
(b) A 30,000-year-old ivory
carving of a water bird,
found in Germany
Figure Biophilia, past and present.
(c) Nature lovers on a wildlife-
watching expedition
(d) A young biologist holding
a songbird

128. Detail of animals in a 36,000-year-old cave painting, Lascaux, France
Figure 56.33a
Figure Biophilia, past and present.
Detail of animals in a 36,000-year-old
cave painting, Lascaux, France

129. (b) A 30,000-year-old ivory carving of a water bird, found in Germany
Figure 56.33b
(b) A 30,000-year-old ivory carving of a water bird, found in Germany
Figure Biophilia, past and present.

130. (c) Nature lovers on a wildlife-watching expedition
Figure 56.33c
Figure Biophilia, past and present.
(c) Nature lovers on a wildlife-watching expedition

131. (d) A young biologist holding a songbird
Figure 56.33d
Figure Biophilia, past and present.
(d) A young biologist holding a songbird

132. Our behavior reflects remnants of our ancestral attachment to nature and the diversity of life—the concept of biophilia
Our sense of connection to nature may motivate realignment of our environmental priorities
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133. Genetic diversity: source of variations that enable
Figure 56.UN01
Genetic diversity: source of variations that enable
populations to adapt to environmental changes
Species diversity: important in maintaining structure
of communities and food webs
Figure 56.UN01 Summary figure, Concept 56.1
Ecosystem diversity: provides life-sustaining services
such as nutrient cycling and waste decomposition

134. Figure 56.UN02-1
Figure 56.UN02-1 Appendix A: answer to Test Your Understanding, question 7

135. Figure 56.UN02-2
Figure 56.UN02-2 Appendix A: answer to Test Your Understanding, question 9