Ch 6 - Aquatic Biodiversity
Download
Report
Transcript Ch 6 - Aquatic Biodiversity
Chapter 6
Aquatic Biodiversity
Chapter Overview Questions
What
are the basic types of aquatic life zones
and what factors influence the kinds of life
they contain?
What are the major types of saltwater life
zones, and how do human activities affect
them?
What are the major types of freshwater life
zones, and how do human activities affect
them?
Why Should We Care About Coral
Reefs?
Coral
reefs form in
clear, warm coastal
waters of the tropics
and subtropics.
Formed by massive
colonies of polyps.
Figure 6-1
Fig. 6-1a, p. 126
Why Should We Care About Coral
Reefs?
Help
moderate atmospheric temperature by
removing CO2 from the atmosphere.
Act as natural barriers that help protect 14%
of the world’s coastlines from erosion by
battering waves and storms.
Provide habitats for a variety of marine
organisms.
AQUATIC ENVIRONMENTS
Saltwater and freshwater aquatic life zones cover
almost three-fourths of the earth’s surface
Major types of organisms found in aquatic
environments depends on salinity
Salinity: amount of various salts dissolved in a given
volume of water
Two main types of aquatic life zones:
Marine (saltwater): estuaries, coastlines, coral
reefs, costal marshes, mangrove swamps, and
oceans
Freshwater: lakes, ponds, streams, rivers, and
inland wetlands
Figure 6-2
Ocean hemisphere
Land–ocean hemisphere
Fig. 6-2, p. 127
AQUATIC ENVIRONMENTS
Figure 6-3
What Kinds of Organisms Live in
Aquatic Life Zones?
Aquatic
systems contain floating, drifting,
swimming, bottom-dwelling, and decomposer
organisms.
Plankton: important group of weakly swimming,
free-floating biota.
• Phytoplankton (plant), Zooplankton (animal),
Ultraplankton (photosynthetic bacteria)
Nekton: fish, turtles, whales.
Benthos: bottom dwellers (barnacles, oysters).
Decomposers: breakdown organic compounds
(mostly bacteria).
Life in Layers
Life
in most aquatic systems is found in
surface, middle, and bottom layers.
Temperature, access to sunlight for
photosynthesis, dissolved oxygen content,
nutrient availability changes with depth.
Euphotic zone (upper layer in deep water
habitats): sunlight can penetrate.
Marine Ecosystems
Scientists
estimate
that marine systems
provide $21 trillion in
goods and services
per year – 70% more
than terrestrial
ecosystems.
Figure 6-4
The Coastal Zone:
Where Most of the Action Is
The
coastal zone: the warm, nutrient-rich,
shallow water that extends from the high-tide
mark on land to the gently sloping, shallow
edge of the continental shelf.
The coastal zone makes up less than 10% of
the world’s ocean area but contains 90% of
all marine species.
Provides numerous ecological and economic
services.
Subject to human disturbance.
Sun
Euphotic Zone
Photosynthesis
Estuarine
Zone
Continental
shelf
Open
Sea
Sea level
Bathyal Zone
Abyssal
Zone
Darkness
High tide Coastal
Zone
Low tide
Fig. 6-5, p. 130
Estuaries and Coastal Wetlands
Estuaries
include river mouths, inlets, bays,
sounds, salt marshes in temperate zones and
mangrove forests in tropical zones
Highly productive ecosystems
Costal wetlands: land areas covered with water
all or part of the year
River mouths, inlets, bays, sounds, salt marshes in
temperate zones, and mangrove forests in tropical
zones
Fig. 6-6, p. 130
Herring gulls
Peregrine falcon
Snowy
Egret
Cordgrass
Short-billed
Dowitcher
Marsh
Periwinkle
Phytoplankton
Smelt
Soft-shelled
clam
Zooplankton and
small crustaceans
Clamworm
Bacteria
Producer to
primary
consumer
Primary to
secondary
consumer
Secondary to
higher-level
consumer
All consumers
and producers
to decomposers
Fig. 6-7a, p. 131
Fig. 6-7b, p. 131
Mangrove Forests
Are found along about
70% of gently sloping
sandy and silty
coastlines in tropical
and subtropical
regions
Tropical equivalent of
salt marshes
Worth $200K - $900K
per square K, but
cleared for aquaculture
for about $20K
Figure 6-8
Estuaries and Coastal Wetlands:
Centers of Productivity
Estuaries
and coastal marshes provide
ecological and economic services.
Filter toxic pollutants, excess plant nutrients,
sediments, and other pollutants.
Reduce storm damage by absorbing waves
and storing excess water produced by storms
and tsunamis.
Provide food, habitats and nursery sites for
many aquatic species.
Rocky and Sandy Shores:
Living with the Tides
Organisms
experiencing daily low and high
tides have evolved a number of ways to
survive under harsh and changing conditions.
Gravitational pull by moon and sun causes tides.
Intertidal Zone: area of shoreline between low
and high tides.
Rocky and Sandy Shores:
Living with the Tides
Organisms
in
intertidal zone
develop specialized
niches to deal with
daily changes in:
Temperature
Salinity
Wave action
Figure 6-9
Rocky Shore Beach
Hermit crab
Sea star
Shore crab
High tide
Periwinkle
Sea urchin
Anemone
Mussel
Low tide
Sculpin
Barnacles
Kelp
Sea lettuce
Monterey flatworm
Nudibranch
Fig. 6-9, p. 132
Barrier Beach
Beach flea
Peanut worm
Blue crab
Tiger
Beetle
Clam
Dwarf
Olive
High tide
Sandpiper
Low tide
Silversides
Mole
Shrimp
White sand
macoma
Sand dollar
Ghost
Shrimp
Moon
snail
Fig. 6-9, p. 132
Barrier Islands
Low,
narrow, sandy islands that form offshore
from a coastline.
Primary and secondary dunes on gently
sloping sandy barrier beaches protect land
from erosion by the sea.
Figure 6-10
Threats to Coral
Reefs
Biologically
diverse
and productive coral
reefs are being
stressed by human
activities.
Coral reefs can only
live between 18-30
oC – a change in
one degree could
cause bleaching
Figure 6-11
Natural Capital Degradation
Coral Reefs
Ocean warming
Soil erosion
Algae growth from fertilizer runoff
Mangrove destruction
Bleaching
Rising sea levels
Increased UV exposure
Damage from anchors
Damage from fishing and diving
Fig. 6-12, p. 135
Biological Zones in the Open Sea:
Light Rules
Euphotic
Nutrient levels low, dissolved O2 high,
photosynthetic activity.
Bathyal
zone: dimly lit middle layer.
No photosynthetic activity, zooplankton and fish
live there and migrate to euphotic zone to feed at
night.
Abyssal
zone: brightly lit surface layer.
zone: dark bottom layer.
Very cold, little dissolved O2.
Effects of Human Activities on Marine
Systems: Red Alert
Human
activities
are destroying or
degrading many
ecological and
economic services
provided by the
world’s coastal
areas.
Figure 6-13
FRESHWATER LIFE ZONES
Freshwater
life zones
include:
Standing (lentic)
water such as lakes,
ponds, and inland
wetlands.
Flowing (lotic)
systems such as
streams and rivers.
Figure 6-14
Lakes: Water-Filled Depressions
Lakes
are large natural bodies of standing
freshwater formed from precipitation, runoff,
and groundwater seepage consisting of:
Littoral zone (near shore, shallow, with rooted
plants).
Limnetic zone (open, offshore area, sunlit).
Profundal zone (deep, open water, too dark for
photosynthesis).
Benthic zone (bottom of lake, nourished by dead
matter).
Lakes: Water-Filled Depressions
During
summer and winter in deep temperate
zone lakes become stratified into temperature
layers and will overturn.
This equalizes the temperature at all depths.
Oxygen is brought from the surface to the lake
bottom and nutrients from the bottom are brought
to the top.
What
causes this overturning?
Sunlight
Green
frog
Painted
turtle
Blue-winged
teal
Muskrat
Pond
snail
Littoral zone
Limnetic zone
Diving
beetle
Plankton
Profundal zone
Benthic zone
Yellow
perch
Bloodworms
Northern
pike
Fig. 6-15, p. 137
Effects of Plant Nutrients on Lakes:
Too Much of a Good Thing
Plant
nutrients from a lake’s environment
affect the types and numbers of organisms it
can support.
Figure 6-16
Effects of Plant Nutrients on Lakes:
Too Much of a Good Thing
Plant
nutrients from a lake’s environment
affect the types and numbers of organisms it
can support.
Oligotrophic (poorly nourished) lake: Usually
newly formed lake with small supply of plant
nutrient input.
Eutrophic (well nourished) lake: Over time,
sediment, organic material, and inorganic
nutrients wash into lakes causing excessive plant
growth.
Mesotrophic in-between.
Effects of Plant Nutrients on Lakes:
Too Much of a Good Thing
Cultural
eutrophication:
Human inputs of nutrients from the atmosphere
and urban and agricultural areas can accelerate
the eutrophication process.
Freshwater Streams and Rivers:
From the Mountains to the Oceans
Water
flowing from mountains to the sea
creates different aquatic conditions and
habitats.
Figure 6-17
Case Study:
Dams, Wetlands, Hurricanes,
and New Orleans
Dams
and levees have been built to control
water flows in New Orleans.
Reduction in natural flow has destroyed
natural wetlands.
Causes city to lie below sea-level (up to 3
meters).
Global sea levels have risen almost 0.3 meters
since 1900.
Freshwater Inland Wetlands:
Vital Sponges
Inland
wetlands
act like natural
sponges that
absorb and store
excess water
from storms and
provide a variety
of wildlife
habitats.
Figure 6-18
Freshwater Inland Wetlands:
Vital Sponges
Filter
and degrade pollutants.
Reduce flooding and erosion by absorbing
slowly releasing overflows.
Help replenish stream flows during dry
periods.
Help recharge ground aquifers.
Provide economic resources and recreation.
Impacts of Human Activities on
Freshwater Systems
Dams, cities, farmlands, and filled-in wetlands alter
and degrade freshwater habitats.
Dams, diversions and canals have fragmented about 40%
of the world’s 237 large rivers.
Flood control levees and dikes alter and destroy aquatic
habitats.
Cities and farmlands add pollutants and excess plant
nutrients to streams and rivers.
Many inland wetlands have been drained or filled for
agriculture or (sub)urban development.
Impacts of Human Activities on
Freshwater Systems
These
wetlands
have been ditched
and drained for
cropland
conversion.
Figure 6-19