CH. 8 - AC Reynolds High

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Transcript CH. 8 - AC Reynolds High

MILLER/SPOOLMAN
LIVING IN THE ENVIRONMENT
Chapter 8
Aquatic Biodiversity
17TH
Core Case Study: Why Should We Care
about Coral Reefs? (1)
• Biodiversity
• Formation
• Tiny animals (polyps) and algae have mutualistic
relationship
• Polyps secret calcium carbonate shells, which become
coral reefs
Core Case Study: Why Should We Care
about Coral Reefs? (2)
• Important ecological and economic services
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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
Core Case Study: Why Should We Care
about Coral Reefs? (3)
• Degradation and decline
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Coastal development
Pollution
Overfishing
Warmer ocean temperatures leading to coral
bleaching: kill algae and thus the polyps
• Increasing ocean acidity
A Healthy Coral Reef in the Red Sea
Fig. 8-1, p. 168
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.
Most of the Earth Is Covered with
Water (1)
• Saltwater: global ocean divided into 4 areas
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Atlantic
Pacific
Arctic
Indian
• Freshwater
Most of the Earth Is Covered with
Water (2)
• Aquatic life zones
• Saltwater life zones (marine life zones)
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Oceans and estuaries
Coastlands and shorelines
Coral reefs
Mangrove forests
• Freshwater life zones
• Lakes
• Rivers and streams
• Inland wetlands
The Ocean Planet
Fig. 8-2, p. 169
Ocean hemisphere
Land–ocean hemisphere
Fig. 8-2, p. 169
Aquatic Systems
Fig. 8-3, p. 170
Most Aquatic Species Live in Top, Middle,
or Bottom Layers of Water (1)
• Plankton: free floating
• Phytoplankton
• Primary producers for most aquatic food webs
• Zooplankton
• Primary and secondary consumers
• Single-celled to large invertebrates like jellyfish
• Ultraplankton
• Tiny photosynthetic bacteria
Most Aquatic Species Live in Top, Middle,
or Bottom Layers of Water (2)
• Nekton
• Strong swimmers: fish, turtles, whales
• Benthos
• Bottom dwellers: oysters, sea stars, clams, lobsters,
crabs
• Decomposers
• Mostly bacteria
Most Aquatic Species Live in Top, Middle,
or Bottom Layers of Water (3)
• Key factors in the distribution of organisms
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Temperature
Dissolved oxygen content
Availability of food
Availability of light and nutrients needed for
photosynthesis in the euphotic (photic) zone
• Turbidity: degree of cloudiness in water
• Inhibits photosynthesis
Four Types of Aquatic Life Forms
Fig. 8-4, p. 171
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.
Oceans Provide Vital Ecological
and Economic Resources
• Estimated $12 trillion per year in goods and services
• Reservoirs of diversity in three major life zones
1. Coastal zone
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Warm, nutrient rich, shallow
Shore to edge of continental shelf
Usually high NPP from ample sunlight and nutrients
2. Open sea
3. Ocean bottom
Major Ecological and Economic Services Provided by
Marine Systems
Fig. 8-5, p. 172
Natural Capital
Marine Ecosystems
Ecological Services
Economic Services
Climate moderation
Food
CO 2 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
Habitats and nursery
areas
Employment
Recreation
Oil and natural gas
Genetic resources
and biodiversity
Minerals
Scientific information
Building materials
Fig. 8-5, p. 172
Major Life Zones and Vertical Zones in an Ocean
Fig. 8-6, p. 173
Coastal Zone Open Sea
Depth in
meters
0
Sea level
50
Euphotic Zone
Estuarine
Zone
Photosynthesis
Low tide
100
Continental shelf
200
500
Bathyal Zone
1,000
Twilight
High tide
1,500
2,000
Abyssal Zone
3,000
4,000
Darkness
Water temperature drops
rapidly between the euphotic
zone and the abyssal zone in an
area called the thermocline .
5,000
10,000
0
5
10
15
Water temperature (°C)
20
25
30
Fig. 8-6, p. 173
Estuaries and Coastal Wetlands Are
Highly Productive (1)
• Estuaries and coastal wetlands
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Where rivers meet the sea
Seawater mixes with freshwater
Very productive ecosystems: high nutrient levels
River mouths
Inlets
Bays
Sounds
Salt marshes
Mangrove forests
View of an Estuary from Space
Fig. 8-7, p. 173
Coastal Marsh Ecosystem
Fig. 8-8, p. 174
Peregrine falcon
Herring
gulls
Cordgrass
Snowy
egret
Short-billed
dowitcher
Marsh
periwinkle
Phytoplankton
Smelt
Zooplankton and small
crustaceans
Soft-shelled
clam
Producer
to primary
consumer
Bacteria
Primary to
Secondary to
secondary consumerhigher-level
consumer
Clamworm
All consumers and
producers
to decomposers
Fig. 8-8a, p. 174
Estuaries and Coastal Wetlands Are
Highly Productive (2)
• Seagrass Beds
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Grow underwater in shallow areas
Support a variety of marine species
Stabilize shorelines
Reduce wave impact
• Mangrove forests
• Along tropical and subtropical coastlines
• 69 different tree species that grow in saltwater
See Grass Bed Organisms
Fig. 8-9, p. 174
Mangrove Forest in Australia
Fig. 8-10, p. 175
Estuaries and Coastal Wetlands Are
Highly Productive (3)
• 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
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
Living between the Tides
Fig. 8-11, p. 176
Rocky Shore Beach
Sea star
Hermit crab
Shore crab
High tide
Periwinkle
Sea urchin
Anemone
Mussel
Low tide
Sculpin
Kelp
Monterey flatworm
Barnacles
Sea lettuce
Nudibranch
Fig. 8-11a, p. 176
Beach flea
Barrier Beach
Peanut worm
Blue crab
Tiger
beetle
Clam
Dwarf
olive
High tide
Sandpiper
Silversides
Low tide
White sand
macoma
Sand
dollar
Ghost shrimp
Mole
shrimp
Moon
snail
Fig. 8-11b, p. 176
Hermit
crab
Sea star
Rocky Shore Beach
Shore crab
High tide
Periwinkle
Sea urchin
Anemone
Mussel
Low tide
Sculpin
Barnacles
Sea lettuce
Kelp
Beach flea
Monterey flatworm
Barrier Beach
Tiger
beetle
Peanut worm
Nudibranch
Blue crab
Silversides
Low tide
White sand
macoma
Clam
High tide
Dwarf
olive
Sand
dollar
Sandpiper
Mole
shrimp
Moon
snail
Ghost
shrimp
Stepped Art
Fig. 8-11, p. 176
Coral Reefs Are Amazing Centers
of Biodiversity
• Marine equivalent of tropical rain forests
• Habitats for one-fourth of all marine species
Natural Capital: Some Components and Interactions in a
Coral Reef Ecosystem
Fig. 8-12, p. 177
Gray reef shark
Sea nettle
Green sea
turtle
Blue tang
Fairy basslet
Parrot fish
Brittle star
Algae
Hard corals
Sergeant
major
Banded coral
shrimp
Phytoplankton
Coney
Symbiotic
algae
Zooplankton
Blackcap basslet
Sponges
Moray eel
Bacteria
Producer
to primary
consumer
Primary to secondary
Secondary to
consumer
higher-level
consumer
All producers
and consumers
to decomposers
Fig. 8-12, p. 177
The Open Sea and Ocean Floor Host a
Variety of Species (1)
• Three vertical zones of the open sea
1. Euphotic zone
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Phytoplankton
Nutrient levels low
Dissolved oxygen levels high
2. Bathyal zone
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Dimly lit
Zooplankton and smaller fishes
The Open Sea and Ocean Floor Host a
Variety of Species (2)
3. Abyssal zone
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Dark and cold
High levels of nutrients
Little dissolved oxygen
Deposit feeders
Filter feeders
• Upwelling brings nutrients to euphotic zone
• Primary productivity and NPP
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.
Human Activities Are Disrupting and
Degrading Marine Systems
• Major threats to marine systems
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Coastal development
Overfishing
Use of fishing trawlers
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
Major Human Impacts on Marine Ecosystems and Coral
Reefs
Fig. 8-13, p. 179
Natural Capital Degradation
Major Human Impacts on Marine Ecosystems
and Coral Reefs
Marine Ecosystems
Coral Reefs
Ocean warming
Rising ocean acidity
Over one-fifth of mangrove forests lost to
Soil erosion
agriculture, development, and shrimp
Algae growth from fertilizer runoff
farms since 1980
Bleaching
Beaches eroding because of coastal
Rising sea levels
development and rising sea levels
Increased UV exposure
Ocean bottom habitats degraded by
dredging and trawler fishing
Damage from anchors
Damage from fishing and diving
At least 20% of coral reefs severely damaged and
25–33% more threatened
Fig. 8-13, p. 179
Half of coastal wetlands lost to
agriculture and urban development
Case Study: The Chesapeake Bay—an
Estuary in Trouble (1)
• Largest estuary in the US; polluted since 1960
• Human population increased
• Point and nonpoint sources raised pollution
• Phosphate and nitrate levels too high
• Excess sediments from runoff and decreased
vegetation
Case Study: The Chesapeake Bay—an
Estuary in Trouble (2)
• Oysters, a keystone species, greatly reduced
• 1983: Chesapeake Bay Program
• Integrated coastal management with local, state,
federal governments and citizens’ groups
• 2008 update:
• 25 years and $6 billion
• Program met only 21% of goals
• Water quality “very poor”
Chesapeake Bay
Fig. 8-14, p. 180
Drainage basin
No oxygen
Low concentrations of
oxygen
Fig. 8-14, p. 180
8-4 Why Are Freshwater Ecosystems
Important?
• Concept 8-4 Freshwater ecosystems provide major
ecological and economic services, and are
irreplaceable reservoirs of biodiversity.
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
Water Stands in Some Freshwater
Systems and Flows in Others (2)
• Four zones based on depth and distance from shore
1. Littoral zone
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Near shore where rooted plants grow
High biodiversity
Turtles, frogs, crayfish, some fish
2. Limnetic zone
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Open, sunlight area away from shore
Main photosynthetic zone
Some larger fish
Water Stands in Some Freshwater
Systems and Flows in Others (3)
3. Profundal zone
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Deep water too dark for photosynthesis
Low oxygen levels
Some fish
4. Benthic zone
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Decomposers
Detritus feeders
Some fish
Nourished primarily by dead matter
Major Ecological and Economic Services Provided by
Freshwater Systems
Fig. 8-15, p. 181
Natural Capital
Freshwater Systems
Ecological Services
Economic Services
Climate moderation
Food
Nutrient cycling
Drinking water
Waste treatment
Flood control
Irrigation water
Groundwater
recharge
Hydroelectricity
Habitats for many
species
Transportation
corridors
Genetic resources
and biodiversity
Recreation
Scientific information
Employment
Fig. 8-15, p. 181
Distinct Zones of Life in a Fairly Deep Temperate Zone
Lake
Fig. 8-16, p. 182
Painted turtle
Blue-winged
teal
Green frog
Muskrat
Pond snail
Littoral zone
Plankton
Diving beetle
Northern pike
Yellow perch
Bloodworms
Fig. 8-16, p. 182
Some Lakes Have More Nutrients
Than Others
• Oligotrophic lakes
• Low levels of nutrients and low NPP
• Very clear water
• Eutrophic lakes
• High levels of nutrients and high NPP
• Murky water with high turbidity
• Mesotrophic lakes
• Cultural eutrophication of lakes from human input
of nutrients
The Effect of Nutrient Enrichment
on a Lake
Fig. 8-17, p. 182
Stepped Art
Fig. 8-17, p. 182
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
Three Zones in the Downhill Flow of Water
Fig. 8-18, p. 183
Lake
Rain and snow
Glacier
Headwaters
Rapids
Waterfall
Tributary
Flood plain
Oxbow lake
Salt marsh
Delta
Deposited
sediment
Ocean
Source Zone
Transition Zone
Water
Floodplain Zone
Sediment
Fig. 8-18, p. 183
Rain and
snow
Lake
Glacier
Rapids
Waterfall
Tributary
Flood plain
Oxbow lake
Salt marsh
Delta Deposited
sediment
Ocean
Source Zone
Transition Zone
Floodplain Zone
Water
Sediment
Stepped Art
Fig. 8-18, p. 183
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
New Orleans, Louisiana Flooded by Hurricane Katrina
Fig. 8-19, p. 185
Projection of New Orleans if the Sea Level Rises 0.9 Meter
Fig. 8-20, p. 185
Freshwater Inland Wetlands Are
Vital Sponges (1)
• Marshes
• Swamps
• Prairie potholes
• Floodplains
• Arctic tundra in summer
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
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.
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
streams, rivers, and lakes
• Impact of drained wetlands
Three Big Ideas
1. Saltwater and freshwater aquatic life zones cover
almost three-fourths of the earth’s surface, and
oceans dominate the planet.
2. The earth’s aquatic systems provide important
ecological and economic services.
3. Human activities threaten biodiversity and disrupt
ecological and economic services provided by
aquatic systems.