Transcript Document

ENVIRONMENTAL SCIENCE 13e
CHAPTER 9:
Sustaining Biodiversity:
The Ecosystem Approach
Wangari Maathai and the Green
Belt Movement
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Began in Kenya in 1977
Organizes poor women in rural Kenya
50,000 members protect forests
Planted 20 million trees
– Fruits
– Building materials
– Firewood
• Similar programs in 30 African countries
• 2004: Nobel Peace Prize
http://www.greenbeltmovement.org/
Watch second video
9-1 What Are Major Threats to
Forest Ecosystems?
• Concept 9-1 Ecologically valuable
forest ecosystems are being cut and
burned at unsustainable rates in
many parts of the world.
Types of Forests
• Forests cover 30% of earth’s land surface
• Old-growth forests:
uncut or regenerated
primary forest that has not been seriously disturbed by human
activities or natural disasters for several hundred years or more
• Second-growth forests:
a stand of trees
resulting from secondary ecological succession. Develop after
trees have been removed by human activities such as clear
cutting for timber or cropland or by natural forces such as fire,
hurricanes, or volcanic eruption
• Tree plantation; tree farm; commercial forest
Old growth forest in the US state of Washington’s Olympic National Forest
Fig. 9-2, p. 180
Short (25- to 30- year rotation cycle of cutting and regrowth of a monoculture tree
plantation in modern industrial forestry. In tropical countries, trees grow more
rapidly year round so rotation cycle can be 6-10 years.
Fig. 9-3, p. 180
Old growth or second growth forest are clear cut to provide land for growing most
tree plantations
Fig. 9-3, p. 180
pFigure 9.4: Major ecological and economic services provided by forests (Concept 9-1).
Question: Which two ecological services and which two economic services do you
think are the most important?
ital
Forests
Ecological
Services
Economic
Services
Support energy flow and chemical cycling
Fuelwood
Reduce soil erosion
Lumber
Absorb and release water
Pulp to make
paper
Purify water and air
Mining
Influence local and regional climate
Livestock
grazing
Store atmospheric carbon
Recreation
Provide numerous wildlife habitats
Jobs
Fig. 9-4, p. 181
Science Focus: Putting a Price Tag
on Nature’s Ecological Services
• Estimated value of earth’s ecological
services
– $33.2 trillion per year
– $4.7 trillion per year for forests
• This is hundreds of times the economic value
• Need to start factoring values into land use
• Ecological services can be a sustainable
source of ecological income
Estimated annual global economic values of some ecological services provided by forests
compared to the raw materials they produce (in billions of dollars).
Fig. 9-A, p. 181
Harvest Methods
• Step one: build roads
– Erosion
– Invasive species
– Open up for human invasion
• Step two: logging operations
– Selective cutting: intermediate aged or mature trees
in an uneven aged forest are cut singly or in small
groups (Fig 9-6a)
– Clear cutting: remove all the trees from an area
– Strip cutting: involves clear cutting a strip of trees along the
contour of the land within a corridor narrow enough the allow
natural regeneration within a few years
Cleared plots
New highway for grazing
Cleared plots
for agriculture
Highway
Old growth
Fig. 9-5, p. 182
Major tree harvesting methods. If you were cutting trees in a forest you owned
which method would you choose and why?
(a) Selective
cutting
Clear
stream
Fig. 9-6, p. 182
(b) Clear-cutting
Muddy
stream
Fig. 9-6, p. 182
(c) Strip cutting
Uncut
Cut 1
year ago
Dirt road
Cut 3–10
years ago
Uncut
Clear
stream
Fig. 9-6, p. 182
Clear cut logging in the US state of Washington
Fig. 9-7, p. 182
Forests and Fires
• Surface fires
– Burn only undergrowth and leaf litter
– May kill seedlings and small trees but spare most
mature trees; allow most wild animals to escape
– Cool fire
– Ecological benefits: help prevent more destructive
fires, free mineral nutrients, release certain seeds and
stimulate germination of some tree seeds, help
control diseases and insects
• Crown fires
– Burn the entire tree
– Hot fire
– Occur in forests with lack of surface fires
Type of fire?
Fig. 9-8, p. 183
Type of
fire?
Fig. 9-8, p. 183
Loss of Original Forests
• Deforestation
• Over past 8,000 years, human activities have
reduced the earth’s forest by 46%, most of this
loss since since 1950
• Most in tropical areas, developing countries
• Estimated loss of 40% intact forests within next
20 years
Extreme tropical deforestation in Chiang Mai,Thailand.
What do you think will happen to the dried out topsoil when the winds come?
How does the term ecological tipping point apply here?
Fig. 9-9, p. 184
Fig. 9-10, p. 184
Good News on Forests
• 2000–2007 net total forested area
stabilized or increased
• Most of the increase due to tree
plantations
• Net loss of terrestrial biodiversity
Return of Forests in the United
States (1)
• U.S. forests
– Cover ~30% of land
– Contain ~80% of wildlife species
– Supply ~67% of nation’s surface water
• Forest cover greater now than in
1920
• Secondary succession
Return of Forests in the United
States (2)
• Second- and third-growth forests
fairly diverse
• More wood grown than cut
• 40% of forests in National Forest
System
• Some forests transformed into tree
plantations
Tropical Forests
• Cover 6% of earth’s land area
• Habitat for 50% of terrestrial plants
and animals
– Vulnerable to extinction – specialized
niches
• Rapid loss of 50,000–170,000 km2
per year
• Some second-growth forests
Causes of Tropical Forest
Deforestation and Degradation
• Population growth and poverty
• Economic reasons
– Logging
– Ranching
– Farming
• Government subsidies
• Fires raise temperatures and reduce
rainfall
Natural Capital Degradation
Major Causes of the Destruction and Degradation of Tropical Forests
Basic Causes
Secondary Causes
• Not valuing ecological services
• Roads
• Cattle ranching
• Crop and timber exports
• Fires
• Logging
• Government policies
• Settler farming
• Tree plantations
• Poverty
• Cash crops
• Population growth
Tree
plantations
Cattle
ranching
Logging
Cash crops
Settler
farming
Fires
Roads
Fig. 9-11, p. 186
Brazil’s Amazon basin
What’s going on in this picture?
Fig. 9-12, p. 187
9-2 How Should We Manage
and Sustain Forests?
• Concept 9-2 We can sustain forests
by emphasizing the economic value
of their ecological services, removing
government subsidies that hasten
their destruction, protecting oldgrowth forests, harvesting trees no
faster than they are replenished, and
planting trees.
Fig. 9-13, p. 188
Management of Forest Fires (1)
• Fire suppression in all types of forests
• Increased amounts of underbrush
• Increased probability of crown fires
Management of Forest Fires (2)
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Prescribed fires
Allow some fires to burn
Thin vegetation from forests
Thin around vulnerable homes
Decrease flammability of homes
Science Focus: Certifying
Sustainably Grown Timber
• Forest Steward Council certification of
forest operations
– Environmentally sound practices
– Sustainable yield harvest
– Minimal erosion from operations
– Retention of dead wood for wildlife
habitat
Trees and Paper
• Many trees are cut for paper
production
• Alternatives
– Pulp from rice straw and agricultural
residues (China)
– Kenaf (U.S.)
– Hemp
Kenaf
Fig. 9-14, p. 189
Ways to Reduce Tropical
Deforestation
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Debt-for-nature swaps
Conservation concessions
Gentler logging methods
Encourage use of wood substitutes
Solutions
Sustaining Tropical Forests
Prevention
Restoration
Protect the most diverse and
endangered areas
Encourage regrowth
through secondary
succession
Educate settlers about
sustainable agriculture and
forestry
Subsidize only sustainable
forest use
Protect forests with
debt-for-nature swaps and
conservation concessions
Rehabilitate degraded
areas
Certify sustainably grown
timber
Reduce poverty
Slow population growth
Concentrate farming
and ranching in
already-cleared areas
Fig. 9-15, p. 190
9-3 How Should We Manage
and Sustain Grasslands?
• Concept 9-3 We can sustain the
productivity of rangeland by
controlling the number and
distribution of grazing livestock and
by restoring degraded grasslands.
Grasslands
• Provide important ecological services
• Second most used and altered
ecosystem by humans
• 42% grazed by cattle, sheep, and
goats – rangeland (open) and
pasture (fenced)
• Overgrazing
What happens to overgrazed rangeland?
Fig. 9-16, p. 191
Manage Rangelands
Sustainably
• Practice rotational grazing
• Fence out riparian zone areas
• Suppress invader plants
– Herbicides
– Mechanical removal
– Controlled burning
– Short-term trampling
Fig. 9-17, p. 191
Fig. 9-17, p. 191
9-4 How Should We Manage and
Sustain Parks and Nature Reserves?
• Concept 9-4 We need to put more
resources into sustaining existing
parks and nature reserves and into
protecting much more of the earth’s
remaining undisturbed land area.
National Parks
• >1,100 national parks in 120
countries
• Only 1% of parks in developing
countries are protected
– Local people invade parks to survive
– Logging
– Mining
– Poaching
Problems Protecting National
Parks
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Illegal logging
Illegal mining
Wildlife poaching
Most parks too small to protect large
animals
• Invasion of nonnative species
Stresses on U.S. National Parks
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58 major national parks
Biggest problem is popularity
Damage from nonnative species
Threatened islands of biodiversity
Need $6 billion for overdue repairs
Nature Reserves Occupy a
Fraction of Earth
• 12% of earth’s land protected
• Only 5% fully protected – 95%
reserved for human use
• Need for conservation
– Minimum 20% of land in biodiversity
reserves
– Protection for all biomes
Solutions for Protection
• “Ecological insurance policy”
• Buffer zones around protected areas
• Locals to manage reserves and buffer
zones
• United Nations: 531 biosphere
reserves in 105 countries
Science Focus: Reintroducing the Gray
Wolf to Yellowstone National Park
• Reduced to a few hundred in lower 48 by
1973
• Keystone species
• Restoration proposal angered ranchers,
hunters, loggers
• 1995 - reintroduced in Yellowstone, 124 by
2008
• Positive ripple effect after reintroduction
The Gray Wolf and Yellowstone National Park
Fig. 9-B, p. 193
Case Study: Costa Rica
• Superpower of biodiversity
• Conserved 25% of its land, 8
megareserves
• Government eliminated deforestation
subsidies
• Paid landowners to maintain and
restore tree coverage
• Boosts ecotourism
Costa
Rica
Panama
Pacific Ocean
National parkland
Buffer zone
Fig. 9-18, p. 194
Protecting Wilderness Protects
Biodiversity
• Wilderness
• Preserves biodiversity
• Centers for evolution
Case Study: Controversy over
Wilderness Protection in the U.S.
• 1964 Wilderness Act
• Ten-fold increase from 1970 to 2008
• 4.6% of U.S. land protected, 75% of
that in Alaska
9-5 How Can We Help to
Sustain Terrestrial Biodiversity?
• Concept 9-5 We can help to sustain
terrestrial biodiversity by identifying
and protecting severely threatened
areas (biodiversity hotspots),
rehabilitating damaged ecosystems
(using restoration ecology), and
sharing with other species much of
the land we dominate (using
reconciliation ecology).
Three Principles to Protect
Ecosystems
1. Map and inventory the world’s
terrestrial and aquatic ecosystems
2. Locate and protect the most
endangered ecosystems, with a
focus on biodiversity
3. Seek to restore as many degraded
ecosystems as possible
Protecting Global Biodiversity
Hotspots
• 17 megadiversity countries, mostly in
tropics and subtropics
– Two-thirds of biodiversity
• Developing countries economically
poor and biodiversity rich
• Protect biodiversity hotspots
34 biodiversity hotspots identified by ecologists as important and endangered centers
of terrestrial biodiversity that contain a large number of species found nowhere else.
Identifying and saving these critical habitats requires a vital emergency response.
Fig. 9-19, p. 196
Supplement 4, Fig. 2, p. S16
Ecological Restoration
• Restoration: returning a particular degraded habitat or
ecosystem to a condition as similar as possible to its natural state
• Rehabilitation:
turning a degraded ecosystem into a
functional or useful ecosystem without trying to restore it to its
original condition ex. Removing pollutants and replanting to reduce
soil erosion in abandoned mining sites
• Replacement: replacing a degraded ecosystem with
another type of ecosystem ex. A degraded forest could be replaced
by a pasture or tree plantation
• Creating artificial ecosystems:
ex. Creating
artificial wetlands to help reduce flooding or treat sewage
Science-based Principles for
Restoration
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Identify cause of degradation
Stop abuse by reducing factors
Reintroduce species if necessary
Protect area from further degradation
Case Study: Ecological Restoration
of Tropical Dry Forest in Costa Rica
• One of world’s largest ecological
restoration projects
• Restore a degraded tropical dry forest
and reconnect it to adjacent forests
• Involve 40,000 people in the
surrounding area – biocultural
restoration
• Ecotourism
Restoration Ecology
• Creating new habitats to conserve
species diversity in areas where
people live, work, play
• People learn to protect local species
and ecosystems
• Sustainable ecotourism
• Golden Gate Park in San Francisco
Fig. 9-20, p. 198
9-6 How Can We Help to
Sustain Aquatic Biodiversity?
• Concept 9-6 We can help to sustain
aquatic biodiversity by establishing
protected sanctuaries, managing
coastal development, reducing water
pollution, and preventing overfishing.
Impacts on Aquatic Ecosystems
(1)
• Destroyed or degraded by human
activities
• Coastal habitats disappearing 2-10
times faster than tropical forest
• Rising sea levels will destroy coral
reefs and some low islands
• Ocean floor degradation 150 times
larger than area clear-cut annually
Impacts on Aquatic Ecosystems
(2)
• Freshwater habitat disruption
– Dams
– Water withdrawals from rivers
• Likely extinction
– 34% marine fish species
– 71% freshwater species
– Greater than any other group of species
Area of ocean bottom before a trawler net scraped it like a gigantic plow.
Fig. 9-21, p. 199
The same area after the trawler scraped the ocean bottom. According to marine biologist
Ellie Norse, “Bottom trawling is probably the largest human-caused disturbance to the
biosphere.” Trawler fishers disagree and claim that the ocean bottom life recovers after
trawling.
Fig. 9-21, p. 199
Overfishing
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Fishery
Fishprint
157% overfishing
90% of large open-ocean fishes have
disappeared since 1950
Collapse of Canada’s 500 year old Atlantic cod fishery off coast of Newfoundland
Fig. 9-22, p. 200
Case Study: Industrial Fish
Harvesting Methods
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Trawler fishing
Purse-seine fishing
Longlining
Drift-net fishing
Major commercial fishing methods
Fish farming
in cage
Trawler
fishing
Spotter airplane
Sonar
Purse-seine fishing
Drift-net fishing
Long line fishing
Float Buoy
lines with
hooks
Deep sea
aquaculture cage
Fish caught
by gills
Fig. 9-23, p. 201
Why Is Protection of Marine
Biodiversity So Difficult?
• Human aquatic ecological footprint
expanding
• Not visible to most people
• Viewed as an inexhaustible resource
• Most ocean areas outside jurisdiction
of a country
Solutions for Marine
Ecosystems
• Protect endangered and threatened
species
• Establish protected marine
sanctuaries
• Marine reserves – work well and
quickly
• Integrated coastal management
• Protect existing coastal wetlands
Solutions
Managing Fisheries
Fishery Regulations
Bycatch
Set catch limits well below the
maximum sustainable yield
Use wide-meshed nets to
allow escape of smaller fish
Improve monitoring and
enforcement of regulations
Use net escape devices for
seabirds and sea turtles
Economic Approaches
Ban throwing edible and
marketable fish back into
the sea
Sharply reduce or eliminate
fishing subsidies
Charge fees for harvesting fish
and shellfish from publicly
owned offshore waters
Aquaculture
Certify sustainable fisheries
Control pollution more
strictly
Protect Areas
Restrict coastal locations
for fish farms
Establish no-fishing areas
Depend more on
herbivorous fish species
Establish more marine
protected areas
Nonnative Invasions
Rely more on integrated
coastal management
Kill organisms in ship
ballast water
Consumer Information
Label sustainably harvested
fish
Filter organisms from ship
ballast water
Publicize overfished and
threatened species
Dump ballast water far at
sea and replace with
deep-sea water
Fig. 9-24, p. 202
Three Big Ideas from This
Chapter - #1
The economic values of the important
ecological services provided by the
world’s ecosystems need to be
included in the prices of goods and
services.
Three Big Ideas from This
Chapter - #2
We can sustain terrestrial biodiversity
by protecting severely threatened
areas, restoring damaged
ecosystems, and sharing with other
species much of the land we
dominate.
Three Big Ideas from This
Chapter - #3
We can sustain aquatic biodiversity by
establishing protected sanctuaries,
managing coastal development,
reducing water pollution, and
preventing overfishing.