Chapter 54 Ecosystems
Lecture Outline
Overview: Ecosystems,
Energy, and Matter
·
An
ecosystem consists of all the
organisms living in a community as well as all the abiotic factors with which
they interact.
·
The
dynamics of an ecosystem involve two processes that cannot be fully described
by population or community processes and phenomena: energy flow and chemical
cycling.
·
Energy
enters most ecosystems in the form of sunlight.
°
It
is converted to chemical energy by autotrophs, passed to heterotrophs in the organic
compounds of food, and dissipated as heat.
·
Chemical
elements are cycled among abiotic and biotic components of the ecosystem.
·
Energy,
unlike matter, cannot be recycled.
°
An
ecosystem must be powered by a continuous influx of energy from an external source,
usually the sun.
·
Energy
flows through ecosystems, while matter cycles within them.
Concept 54.1 Ecosystem ecology emphasizes energy flow and chemical
cycling
·
Ecosystem
ecologists view ecosystems as transformers of energy and processors of matter.
·
We
can follow the transformation of energy by grouping the species in a community
into trophic levels of feeding
relationships.
Ecosystems obey physical laws.
·
The
law of conservation of energy states that energy cannot be created or destroyed
but only transformed.
°
Plants
and other photosynthetic organisms convert solar energy to chemical energy, but
the total amount of energy does not change.
°
The
total amount of energy stored in organic molecules plus the amounts reflected
and dissipated as heat must equal the total solar energy intercepted by the
plant.
·
The
second law of thermodynamics states that some energy is lost as heat in any
conversion process.
°
We
can measure the efficiency of ecological energy conversions.
·
Chemical
elements are continually recycled.
°
A
carbon or nitrogen atom moves from one trophic level to another and eventually
to the decomposers and back again.
Trophic relationships determine the routes of
energy flow and chemical cycling in ecosystems.
·
Autotrophs,
the primary producers of the ecosystem,
ultimately support all other organisms.
°
Most
autotrophs are photosynthetic plants, algae or bacteria that use light energy
to synthesize sugars and other organic compounds.
°
Chemosynthetic
prokaryotes are the primary producers in deep-sea hydrothermal vents.
·
Heterotrophs
are at trophic levels above the primary producers and depend on their
photosynthetic output.
°
Herbivores
that eat primary producers are called primary
consumers.
°
Carnivores
that eat herbivores are called secondary
consumers.
°
Carnivores
that eat secondary producers are called tertiary
consumers.
·
Another
important group of heterotrophs is the detritivores,
or decomposers.
°
They
get energy from detritus, nonliving
organic material such as the remains of dead organisms, feces, fallen leaves,
and wood.
°
Detritivores
play an important role in material cycling.
Decomposition connects all trophic levels.
·
The
organisms that feed as detritivores form a major link between the primary
producers and the consumers in an ecosystem.
·
Detritivores
play an important role in making chemical elements available to producers.
°
Detritivores
decompose organic material and transfer chemical elements in inorganic forms to
abiotic reservoirs such as soil, water, and air.
·
Producers
then recycle these elements into organic compounds.
·
An
ecosystem’s main decomposers are fungi and prokaryotes.
Concept 54.2 Physical and chemical factors limit primary production
in ecosystems
·
The
amount of light energy converted to chemical energy by an ecosystem’s
autotrophs in a given time period is an ecosystem’s primary production.
An ecosystem’s energy budget depends on
primary production.
·
Most
primary producers use light energy to synthesize organic molecules, which can
be broken down to produce ATP.
·
The
amount of photosynthetic production sets the spending limit of the entire
ecosystem.
·
A
global energy budget can be analyzed.
°
Every
day, Earth is bombarded by approximately 1023 joules of solar
radiation.
§
The
intensity of solar energy striking Earth varies with latitude, with the tropics
receiving the greatest input.
§
Most
of this radiation is scattered, absorbed, or reflected by the atmosphere.
§
Much
of the solar radiation that reaches Earth’s surface lands on bare ground or
bodies of water that either absorb or reflect the energy.
§
Only
a small fraction actually strikes algae, photosynthetic prokaryotes, or plants,
and only some of this is of wavelengths suitable for photosynthesis.
§
Of
the visible light that reaches photosynthetic organisms, only about 1% is
converted to chemical energy.
°
Although
this is a small amount, primary producers produce about 170 billion tons of
organic material per year.
·
Total
primary production in an ecosystem is known as gross primary production (GPP).
°
This
is the amount of light energy that is converted into chemical energy per unit
time.
·
Plants
use some of these molecules as fuel in their own cellular respiration.
·
Net primary production
(NPP) is
equal to gross primary production minus the energy used by the primary
producers for respiration (R):
NPP
= GPP − R
·
To
ecologists, net primary production is the key measurement, because it
represents the storage of chemical energy that is available to consumers in the
ecosystem.
·
Primary
production can be expressed as energy per unit area per unit time, or as
biomass of vegetation added to the ecosystem per unit area per unit time.
°
This
should not be confused with the total
biomass of photosynthetic autotrophs present in a given time, which is called
the standing crop.
°
Primary
production is the amount of new
biomass added in a given period of time.
°
Although
a forest has a large standing cross biomass, its primary production may
actually be less than that of some grasslands, which do not accumulate
vegetation because animals consume the plants rapidly.
·
Different
ecosystems differ greatly in their production as well as in their contribution
to the total production of the Earth.
°
Tropical
rain forests are among the most productive terrestrial ecosystems.
°
Estuaries
and coral reefs also are very productive, but they cover only a small area
compared to that covered by tropical rain forests.
°
The
open ocean has a relatively low production per unit area but contributes more
net primary production than any other single ecosystem because of its very
large size.
·
Overall,
terrestrial ecosystems contribute two-thirds of global net primary production,
and marine ecosystems contribute approximately one-third.
In aquatic ecosystems, light and nutrients
limit primary production.
·
Light
is a key variable controlling primary production in oceans, since solar
radiation can only penetrate to a certain depth known as the photic zone.
°
The
first meter of water absorbs more than half of the solar radiation.
·
If
light were the main variable limiting primary production in the ocean, we would
expect production to increase along a gradient from the poles toward the
equator, which receives the greatest intensity of light.
°
There
is no such gradient.
°
There
are parts of the ocean in the tropics and subtropics that exhibit low primary
production, while some high-latitude ocean regions are relatively productive.
·
More
than light, nutrients limit primary production in aquatic ecosystems.
·
A
limiting nutrient is an element that
must be added for production to increase in a particular area.
·
The
nutrient most often limiting marine production is either nitrogen or
phosphorus.
°
In
the open ocean, nitrogen and phosphorous levels are very low in the photic zone
but are higher in deeper water where light does not penetrate.
·
Nitrogen
is the nutrient that limits phytoplankton growth in many parts of the ocean.
°
This
knowledge can be used to prevent algal blooms by limiting pollution that
fertilizes phytoplankton.
·
Some
areas of the ocean have low phytoplankton density despite their relatively high
nitrogen concentrations.
°
For
example, the
°
Nutrient-enrichment
experiments showed that iron availability limits primary production in this
area.
·
Marine
ecologists carried out large-scale field experiments in the
°
A
massive phytoplankton bloom occurred, with a 27-fold increase in chlorophyll
concentration in water samples from test sites.
·
Why
are iron concentrations naturally low in certain oceanic areas?
°
Windblown
dust from the land delivers iron to the ocean, and relatively little dust
reaches the central Pacific and
·
The
iron factor in marine ecosystems is related to the nitrogen factor.
·
When
iron is limiting, adding iron stimulates the growth of cyanobacteria that fix
nitrogen.
·
Phytoplankton
proliferate, once released from nitrogen limitation.
°
Iron
à
cyanobacteria à nitrogen fixationà phytoplankton production
·
In
areas of upwelling, nutrient-rich deep waters circulate to the ocean surface.
°
These
areas have exceptionally high primary production, supporting the hypothesis
that nutrient availability determines marine primary production.
°
Areas
of upwelling are prime fishing locations.
·
Nutrient
limitation is also common in freshwater lakes.
·
Sewage
and fertilizer pollution can add nutrients to lakes.
·
Additional
nutrients shifted many lakes from phytoplankton communities dominated by
diatoms and green algae to communities dominated by cyanobacteria.
°
This
process is called eutrophication and
has a wide range of ecological impacts, including the loss of most fish
species.
·
David
Schindler of the
°
His
research led to the use of phosphate-free detergents and other water quality
reforms.
In terrestrial ecosystems, temperature and
moisture are the key factors limiting primary production.
·
Tropical
rain forests, with their warm, wet conditions, are the most productive of all
terrestrial ecosystems.
·
By
contrast, low-productivity ecosystems are generally dry (deserts) or dry and
cold (arctic tundra).
·
Between
these extremes lie temperate forest and grassland ecosystems with moderate
climates and intermediate productivity.
·
These
contrasts in climate can be represented by a measure called actual evapotranspiration, which is the
amount of water annually transpired by plants and evaporated from a landscape.
°
Actual
evapotranspiration increases with precipitation and with the amount of solar
energy available to drive evaporation and transpiration.
·
On
a more local scale, mineral nutrients in the soil can play a key role in
limiting primary production in terrestrial ecosystems.
·
Primary
production removes soil nutrients.
·
A
single nutrient deficiency may cause plant growth to slow and cease.
·
Nitrogen
and phosphorus are the soil nutrients that most commonly limit terrestrial
production.
·
Scientific
studies relating nutrients to terrestrial primary production have practical applications
in agriculture.
°
Farmers
can maximize crop yields with the right balance of nutrients for the local soil
and type of crop.
Concept 54.3 Energy transfer between trophic levels is usually less
than 20% efficient
·
The
amount of chemical energy in consumers’ food that is converted to their own new
biomass during a given time period is called the secondary production of an ecosystem.
·
We
can measure the efficiency of animals as energy transformers using the
following equation:
°
production
efficiency = net secondary production / assimilation of primary production
·
Net
secondary production is the energy stored in biomass represented by growth and
reproduction.
·
Assimilation
consists of the total energy taken in and used for growth, reproduction, and
respiration.
·
Production efficiency is thus the fraction of
food energy that is not used for
respiration.
°
This
differs among organisms.
§
Birds
and mammals generally have low production efficiencies of between 1% and 3%
because they use so much energy to maintain a constant body temperature.
§
Fishes
have production efficiencies of around 10%.
§
Insects
are even more efficient, with production efficiencies averaging 40%.
·
Trophic efficiency is the percentage of
production transferred from one trophic level to the next.
°
Trophic
efficiencies must always be less than production efficiencies because they take
into account not only the energy lost through respiration and contained in
feces, but also the energy in organic material at lower trophic levels that is
not consumed.
°
Trophic
efficiencies usually range from 5% to 20%.
°
In
other words, 80–95% of the energy available at one trophic level is not
transferred to the next.
·
This
loss is multiplied over the length of a food chain.
°
If
10% of energy is transferred from primary producers to primary consumers, and
10% of that energy is transferred to secondary consumers, then only 1% of net
primary production is available to secondary consumers.
·
Pyramids of net production represent the
multiplicative loss of energy in a food chain.
°
The
size of each block in the pyramid is proportional to the new production of each
trophic level, expressed in energy units.
·
Biomass pyramids represent the ecological
consequences of low trophic efficiencies.
°
Most
biomass pyramids narrow sharply from primary producers to top-level carnivores
because energy transfers are so inefficient.
°
In
some aquatic ecosystems, the pyramid is inverted and primary consumers outweigh
producers.
°
Such
inverted biomass pyramids occur because the producers—phytoplankton—grow, reproduce,
and are consumed by zooplankton so rapidly that they never develop a large
standing crop.
°
They
have a short turnover time, which means they have a small
standing crop biomass compared to their production.
§
turnover
time = standing crop biomass (mg/m2) / production (mg/m2/day)
°
Because
the phytoplankton replace their biomass at such a rapid rate, they can support
a biomass of zooplankton much greater than their own biomass.
·
Because
of the progressive loss of energy along a food chain, any ecosystem cannot
support a large biomass of top-level carnivores.
°
With
some exceptions, predators are usually larger than the prey they eat.
°
Top-level
predators tend to be fairly large animals.
°
As
a result, the limited biomass at the top of an ecological pyramid is concentrated
in a small number of large individuals.
·
In
a pyramid of numbers, the size of
each block is proportional to the number of individuals present in each trophic
level.
·
The
dynamics of energy through ecosystems have important implications for the human
population.
°
Eating
meat is an inefficient way of tapping photosynthetic production.
°
Worldwide
agriculture could feed many more people if humans all fed as primary consumers,
eating only plant material.
Herbivores consume a small percentage of
vegetation: the green world hypothesis.
·
According
to the green world hypothesis,
herbivores consume relatively little plant biomass because they are held in
check by a variety of factors, including predators, parasites, and disease.
·
How
green is our world?
°
83
× 1010 metric tons of carbon are stored in the plant biomass of
terrestrial ecosystems.
°
Herbivores
annually consume less than 17% of the total net primary production.
·
The
green world hypothesis proposes several factors that keep herbivores in check:
°
Plants
have defenses against herbivores.
°
Nutrients,
not energy supply, usually limit herbivores.
§
Animals
need certain nutrients that plants tend to supply in relatively small amounts.
§
The
growth and reproduction of many herbivores are limited by availability of
essential nutrients.
°
Abiotic
factors limit herbivores.
§
Temperature
and moisture may restrict carrying capacities for herbivores below the level
that would strip vegetation.
°
Intraspecific
competition can limit herbivore numbers.
§
Territorial
behavior and competitive behaviors may reduce herbivore population density.
°
Interspecific
interactions check herbivore densities.
§
Parasites,
predators, and disease limit the growth of herbivore populations.
§
This
applies the top-down model of community structure.
Concept 54.4 Biological and geochemical processes move nutrients
between organic and inorganic parts of the ecosystem
·
Chemical
elements are available to ecosystems only in limited amounts.
°
Life
on Earth depends on the recycling of essential chemical elements.
·
Nutrient
circuits involve both biotic and abiotic components of ecosystems and are
called biogeochemical cycles.
·
There
are two general categories of biogeochemical cycles: global and regional.
°
Gaseous
forms of carbon, oxygen, sulfur, and nitrogen occur in the atmosphere, and
cycles of these elements are global.
°
Elements
that are less mobile in the environment, such as phosphorus, potassium,
calcium, and trace elements generally cycle on a more localized scale in the
short term.
§
Soil
is the main abiotic reservoir for these elements.
·
We
will consider a general model of chemical cycling that includes the main
reservoirs of elements and the processes that transfer elements between
reservoirs.
°
Each
reservoir is defined by two characteristics: whether it contains organic or inorganic
materials and whether or not the materials are directly available for use by
organisms.
·
Reservoir a. The nutrients in living organisms and in
detritus are available to other organisms when consumers feed and when
detritivores consume nonliving organic material.
·
Reservoir b. Some materials move to the fossilized organic
reservoir as dead organisms and are buried by sedimentation over millions of
years. Nutrients in fossilized deposits cannot be assimilated directly.
·
Reservoir c. Inorganic elements and compounds that are
dissolved in water or present in soil or air are available for use by
organisms.
·
Reservoir d. Inorganic elements present in rocks are not
directly available for use by organisms. These nutrients may gradually become
available through erosion and weathering.
·
Describing
biogeochemical cycles in general terms is much simpler than trying to trace
elements through these cycles.
°
Ecologists
study chemical cycling by adding tiny amounts of radioactive isotopes to the
elements they are tracing.
There are a number of important biogeochemical
cycles.
·
We
will consider the cycling of water, carbon, nitrogen, and phosphorus.
The water cycle
·
Biological importance
°
Water
is essential to all organisms and its availability influences rates of ecosystem
processes.
·
Biologically available
forms
°
Liquid
water is the primary form in which water is used.
·
Reservoirs
°
The
oceans contain 97% of the water in the biosphere.
°
2%
is bound as ice, and 1% is in lakes, rivers, and groundwater.
°
A
negligible amount is in the atmosphere.
·
Key processes
°
The
main processes driving the water cycle are evaporation of liquid water by solar
energy, condensation of water vapor into clouds, and precipitation.
°
Transpiration
by terrestrial plants moves significant amounts of water.
°
Surface
and groundwater flow returns water to the oceans.
The carbon cycle
·
Biological importance
°
Organic
molecules have a carbon framework.
·
Biologically available
forms
°
Autotrophs
convert carbon dioxide to organic molecules that are used by heterotrophs.
·
Reservoirs
°
The
major reservoirs of carbon include fossil fuels, soils, aquatic sediments, the
oceans, plant and animal biomass, and the atmosphere (CO2).
·
Key processes
°
Photosynthesis
by plants and phytoplankton fixes atmospheric CO2.
°
CO2
is added to the atmosphere by cellular respiration of producers and consumers.
°
Volcanoes
and the burning of fossil fuels add CO2 to the atmosphere.
The nitrogen cycle
·
Biological importance
°
Nitrogen
is a component of amino acids, proteins, and nucleic acids.
°
It
may be a limiting plant nutrient.
·
Biologically available
forms
°
Plants
and algae can use ammonium (NH4+) or nitrate (NO3−).
°
Various
bacteria can also use NH4+, NO3−,
or NO2.
°
Animals
can use only organic forms of nitrogen.
·
Reservoirs
°
The
major reservoir of nitrogen is the atmosphere, which is 80% nitrogen gas (N2).
°
Nitrogen
is also bound in soils and the sediments of lakes, rivers, and oceans.
°
Some
nitrogen is dissolved in surface water and groundwater.
°
Nitrogen
is stored in living biomass.
·
Key processes
°
Nitrogen
enters ecosystems primarily through bacterial nitrogen fixation.
§
Some
nitrogen is fixed by lightning and industrial fertilizer production.
°
Ammonification by bacteria decomposes
organic nitrogen.
°
In
nitrification, bacteria convert NH4+ to
NO3−.
°
In
denitrification, bacteria use NO3−
for metabolism instead of O2, releasing N2.
The phosphorus cycle
·
Biological importance
°
Phosphorus
is a component of nucleic acids, phospholipids, and ATP and other
energy-storing molecules.
°
It
is a mineral constituent of bones and teeth.
·
Biologically available
forms
°
The
only biologically important inorganic form of phosphorus is phosphate (PO43−),
which plants absorb and use to synthesize organic compounds.
·
Reservoirs
°
The
major reservoir of phosphorus is sedimentary rocks of marine origin.
°
There
are also large quantities of phosphorus in soils, dissolved in the oceans, and
in organisms.
·
Key processes
°
Weathering
of rocks gradually adds phosphate to soil.
°
Some
phosphate leaches into groundwater and surface water and moves to the sea.
°
Phosphate
may be taken up by producers and incorporated into organic material.
°
It
is returned to soil or water through decomposition of biomass or excretion by
consumers.
Decomposition rates largely determine the
rates of nutrient cycling.
·
The
rates at which nutrients cycle in different ecosystems are extremely variable
as a result of variable rates of decomposition.
°
Decomposition
takes an average of four to six years in temperate forests, while in a tropical
rain forest, most organic material decomposes in a few months to a few years.
°
The
difference is largely the result of warmer temperatures and more abundant
precipitation in tropical rain forests.
·
Like
net primary production, the rate of decomposition increases with actual
evapotranspiration.
·
In
tropical rain forests, relatively little organic material accumulates as leaf
litter on the forest floor.
°
75%
of the nutrients in the ecosystem are present in the woody trunks of trees.
°
10%
of the nutrients are concentrated in the soil.
·
In
temperate forests, where decomposition is slower, the soil may contain 50% of
the organic material.
·
In
aquatic ecosystems, decomposition in anaerobic mud of bottom sediments can take
50 years or more.
°
However,
algae and aquatic plants usually assimilate nutrients directly from the water.
°
Aquatic
sediments may constitute a nutrient sink.
Nutrient cycling is strongly regulated by
vegetation.
·
Long-term
ecological research (LTER) monitors the dynamics of ecosystems over long
periods of time.
°
The
°
The
study site is a deciduous forest with several valleys, each drained by a small
creek that is a tributary of Hubbard Brook.
·
Preliminary
studies confirmed that internal cycling within a terrestrial ecosystem conserves
most of the mineral nutrients.
·
Some
areas were completely logged and then sprayed with herbicides for three years
to prevent regrowth of plants.
°
All
the original plant material was left in place to decompose.
·
Water
runoff from the altered watershed increased by 30–40%, apparently because there
were no plants to absorb and transpire water from the soil.
°
The
concentration of Ca2+ in the creek increased four-fold, while
concentration of K+ increased by a factor of 15.
°
Nitrate
loss was increased by a factor of 60.
·
This
study demonstrates that the amount of nutrients leaving an intact forest
ecosystem is controlled by the plants.
·
Results
of the Hubbard Brook studies assess natural ecosystem dynamics and provide
insight into the mechanisms by which human activities affect ecosystem
processes.
Concept 54.5 The human population is disrupting chemical cycles
throughout the biosphere
·
Human
activities and technologies have disrupted the trophic structure, energy flow,
and chemical cycling of ecosystems worldwide.
The human population moves nutrients from one
part of the biosphere to another.
·
Human
activity intrudes in nutrient cycles.
°
Nutrients
from farm soil may run off into streams and lakes, depleting nutrients in one
area, causing excesses in another, and disrupting chemical cycles in both
places.
°
Humans
also add entirely new materials—many toxic—to ecosystems.
·
In
agricultural ecosystems, a large amount of nutrients are removed from the area
as crop biomass.
°
After
a while, the natural store of nutrients can become exhausted.
°
The
soil cannot be used to grow crops without nutrient supplementation.
·
Nitrogen
is the main nutrient lost through agriculture.
°
Plowing
and mixing the soil increase the decomposition rate of organic matter,
releasing usable nitrogen that is then removed from the ecosystem when crops
are harvested.
·
Recent
studies indicate that human activities have approximately doubled the worldwide
supply of fixed nitrogen, due to the use of fertilizers, cultivation of
legumes, and burning.
°
This
may increase the amount of nitrogen oxides in the atmosphere and contribute to
atmospheric warming, depletion of ozone, and possibly acid precipitation.
·
The
key problem with excess nitrogen seems to be critical load, the amount of added nitrogen that can be absorbed by
plants without damaging the ecosystem.
°
Nitrogenous
minerals in the soil that exceed the critical load eventually leach into
groundwater or run off into freshwater and marine ecosystems, contaminating
water supplies, choking waterways, and killing fish.
·
Lakes
are classified by nutrient availability as oligotrophic or eutrophic.
°
In
an oligotrophic lake, primary productivity is relatively low because the
mineral nutrients required by phytoplankton are scarce.
°
Overall
productivity is higher in eutrophic lakes.
·
Human
intrusion has disrupted freshwater ecosystems by cultural eutrophication.
°
Sewage
and factory wastes and runoff of animal wastes from pastures and stockyards
have overloaded many freshwater streams and lakes with nitrogen.
°
This
results in an explosive increase in the density of photosynthetic organisms,
released from nutrient limitation.
°
Shallow
areas become choked with weeds and algae.
°
As
photosynthetic organisms die and organic materials accumulate at the lake
bottom, detritivores use all the available oxygen in the deeper waters.
°
This
can eliminate fish species.
Combustion of fossil fuels is the main cause
of acid precipitation.
·
The
burning of fossil fuels releases oxides of sulfur and nitrogen that react with
water in the atmosphere to produce sulfuric and nitric acids.
·
These
acids fall back to earth as acid precipitation—rain, snow, sleet or fog with a
pH less than 5.6.
·
Acid
precipitation is a regional or global problem, rather than a local one.
°
The
tall exhaust stacks built for smelters and generating plans export the problem
far downwind.
·
Acid
precipitation lowers the pH of soil and water and affects the soil chemistry of
terrestrial ecosystems.
°
With
decreased pH, calcium and other nutrients leach from the soil.
°
The
resulting nutrient deficiencies affect the health of plants and limit their
growth.
·
Freshwater
ecosystems are very sensitive to acid precipitation.
°
Lakes
underlain by granite bedrock have poor buffering capacity because of low
bicarbonate levels.
°
Fish
populations have declined in many lakes in
§
Lake
trout are keystone predators in many Canadian lakes.
§
When
they are replaced by acid-tolerant species, the dynamics of food webs in the
lakes change dramatically.
·
Environmental
regulations and new industrial technologies have led to reduced sulfur dioxide
emissions in many developed countries.
°
The
water chemistry of many streams and freshwater lakes is slowly improving as a
result.
°
Ecologists
estimate that it will take another 10 to 20 years for these ecosystems to
recover, even if emissions continue to decline.
·
Massive
emissions of sulfur dioxide and acid precipitation continue in parts of central
and eastern Europe.
Toxins can become concentrated in successive
trophic levels of food webs.
·
Humans
introduce many toxic chemicals into ecosystems.
°
These
substances are ingested and metabolized by organisms and can accumulate in the
fatty tissues of animals.
°
These
toxins become more concentrated in successive trophic levels of a food web, a
process called biological magnification.
§
Magnification
occurs because the biomass at any given trophic level is produced from a much
larger biomass ingested from the level below.
§
Thus,
top-level carnivores tend to be the organisms most severely affected by toxic
compounds in the environment.
°
Many
toxins cannot be degraded by microbes and persist in the environment for years
or decades.
°
Other
chemicals may be converted to more toxic products by reaction with other
substances or by the metabolism of microbes.
§
For
example, mercury was routinely expelled into rivers and oceans in an insoluble
form.
§
Bacteria
in the bottom mud converted it to methyl mercury, an extremely toxic soluble
compound that accumulated in the tissues of organisms, including humans who
fished in contaminated waters.
Human activities may be causing climate change
by increasing atmospheric carbon dioxide.
·
Since
the Industrial Revolution, the concentration of CO2 in the
atmosphere has increased greatly as a result of burning fossil fuels and wood
removed by deforestation.
°
The
average CO2 concentration in the environment was 274 ppm before
1850.
°
Measurements
in 1958 read 316 ppm and have increased to 370 ppm today.
·
If
CO2 emissions continue to increase at the present rate, the
atmospheric concentration of this gas will be double what it was at the start
of the Industrial Revolution by the year 2075.
·
Increased
productivity by vegetation is one consequence of increasing CO2
levels.
·
Because
C3 plants are more limited than C4 plants by CO2
availability, one effect of increasing CO2 levels may be the spread
of C3 species into terrestrial habitats previously favoring C4
plants.
°
For
example, corn may be replaced on farms by wheat and soybeans.
·
To
assess the effect of rising levels of atmospheric CO2 on temperate
forests, scientists at
°
The
FACTS-1 study is testing how elevated CO2 influences tree growth,
carbon concentration in soils, insect populations, soil moisture, understory
plant growth, and other factors over a ten-year period.
·
Rising
atmospheric CO2 levels may have an impact on Earth’s heat budget.
°
When
light energy hits the Earth, much of it is reflected off the surface.
§
CO2
causes the Earth to retain some of the energy that would ordinarily escape the
atmosphere.
à
This
phenomenon is called the greenhouse
effect.
à
If
it were not for this effect, the average air temperature on Earth would be
−18°C.
à
A
number of studies predict that by the end of the 21st century, atmospheric CO2
concentration will have doubled and average global temperature will rise by
2°C.
·
An
increase of only 1.3°C would make the world warmer than at any time in the past
100,000 years.
°
If
increased temperatures caused the polar ice caps to melt, sea levels would rise
by an estimated 100 m, flooding coastal areas 150 km inland from current
coastlines.
°
A
warming trend would also alter geographic distribution of precipitation, making
major
·
Scientists
continue to construct models to predict how increasing levels of CO2
in the atmosphere will affect Earth.
·
Global
warming is a problem of uncertain consequences and no certain solutions.
·
Stabilizing
CO2 emissions will require concerted international effort and the
acceptance of dramatic changes in personal lifestyles and industrial processes.
·
Many
ecologists think that this effort suffered a major setback in 2001, when the
United States pulled out of the Kyoto Protocol, a 1997 pledge by industrialized
nations to reduce their CO2 output by 5% over a ten-year period.
Human activities are depleting atmospheric
ozone.
·
Life
on earth is protected from the damaging affects of ultraviolet radiation (UV)
by a layer of O3, or ozone, that is present in the lower
stratosphere.
·
Studies
suggest that the ozone layer has been gradually “thinning” since 1975.
·
The
destruction of ozone probably results from the accumulation of CFCs, or
chlorofluorocarbons—chemicals used in refrigeration, as propellant in aerosol
cans, and for certain manufacturing processes.
°
The
breakdown products from these chemicals rise to the stratosphere, where the
chlorine they contain reacts with ozone to reduce it to O2.
§
Subsequent
reactions liberate the chlorine, allowing it to react with other ozone
molecules in a catalytic chain reaction.
§
At
middle latitudes, ozone levels have decreased by 2–10% during the past 20
years.
°
The
result of a reduction in the ozone layer may be increased levels of UV
radiation that reach the surface of the Earth.
§
Some
scientists expect increases in skin cancer and cataracts, as well as
unpredictable effects on crops and natural communities.
§
Even
if all chlorofluorocarbons were banned globally today, chlorine molecules
already present in the atmosphere will continue to reduce ozone levels for at
least a century.
·
The
impact of human activity on the ozone layer is one more example of how much we
are able to disrupt ecosystems and the entire biosphere.