1. The Nutrient Cycles and Human Impact

2. The Cycling of Chemical Elements in Ecosystems  Biogeochemical Cycles KEY PLAYERS  Decomposers – complete cycle Types of Biogeochemical Cycles: Global – atmosphere and ocean Regional – stuff found in the soil NUTRIENT RESEVOIRS: PAGE 1195

3. Organic
materials
available
as nutrients
Living
organisms,
detritus
unavailable
Coal, oil,
peat
Inorganic
Atmosphere,
soil, water
Minerals
in rocks
Formation of
sedimentary rock
Weathering,
erosion
Respiration,
decomposition,
excretion
Burning
of fossil fuels
Fossilization
Reservoir a
Reservoir b
Reservoir c
Reservoir d
Assimilation, photosynthesis

4. The water cycle
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
Evapotranspiration, Condensation, Precipitation

5. The carbon cycle - base of biological molecules
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, consumers and decomposers.
Volcanoes and the burning of fossil fuels add CO2 to the atmosphere.

6. THE WATER CYCLE THE CARBON CYCLE
Figure 54.17
Transport
over land
Solar energy
Net movement of
water vapor by wind
Precipitation
over ocean
Evaporation
from ocean
Evapotranspiration
from land
Percolation
through
soil
Runoff and
groundwater
CO2 in atmosphere
Photosynthesis
Cellular
respiration
Burning of
fossil fuels
and wood
Higher-level
consumers
Primary
Detritus
Carbon compounds
in water
Decomposition
THE WATER CYCLE
THE CARBON CYCLE

7. The nitrogen cycle
Nitrogen is a component of amino acids, proteins, and nucleic acids.
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 (amino acids)

8. Reservoirs
The major reservoir of nitrogen is the atmosphere, which is % nitrogen gas (N2).
Soils and the sediments of lakes, rivers, and oceans.
Dissolved in surface water and groundwater.
Nitrogen is stored in living biomass.

9. Key processes
Nitrogen enters ecosystems primarily through bacterial nitrogen fixation.
Some nitrogen is fixed by lightning and industrial fertilizer production (Haber process)
Ammonification by bacteria forms NH4+
In nitrification, bacteria convert NH4+ to NO3−.
In denitrification, bacteria use NO3− for metabolism instead of O2, releasing N2.
- important symbiosis: Legumes and Nitrifying bacteria

10. THE NITROGEN CYCLE THE PHOSPHORUS CYCLE
Figure 54.17
N2 in atmosphere
Denitrifying
bacteria
Nitrifying
Nitrification
Nitrogen-fixing
soil bacteria
bacteria in root
nodules of legumes
Decomposers
Ammonification
Assimilation
NH3
NH4+
NO3
NO2 
Rain
Plants
Consumption
Decomposition
Geologic
uplift
Weathering
of rocks
Runoff
Sedimentation
Plant uptake
of PO43
Soil
Leaching
THE NITROGEN CYCLE
THE PHOSPHORUS CYCLE

11. Phosphorus Cycle
Part of nucleic acids, phospholipids, and ATP
Bones and teeth.
Biologically available forms
Phosphate (PO43−), plants absorb and use to synthesize organic compounds.
Reservoirs
Sedimentary rocks of marine origin.
Soils, dissolved in the oceans, and in organisms.
Key processes
Weathering of rocks gradually adds phosphate to soil.
Absorbed by producers and incorporated into organic material.
It is returned to soil or water through decomposition of biomass or excretion by consumers.

12. THE NITROGEN CYCLE THE PHOSPHORUS CYCLE
Figure 54.17
N2 in atmosphere
Denitrifying
bacteria
Nitrifying
Nitrification
Nitrogen-fixing
soil bacteria
bacteria in root
nodules of legumes
Decomposers
Ammonification
Assimilation
NH3
NH4+
NO3
NO2 
Rain
Plants
Consumption
Decomposition
Geologic
uplift
Weathering
of rocks
Runoff
Sedimentation
Plant uptake
of PO43
Soil
Leaching
THE NITROGEN CYCLE
THE PHOSPHORUS CYCLE

13. 3. Decomposition rates largely determine the rates of nutrient cycling.
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.
The rate of decomposition increases with actual evapotranspiration – wet and warm

14. Figure 54.18 Consumers Producers Decomposers Nutrients available
to producers
Abiotic
reservoir
Geologic
processes
Decomposers

15. Human Impact on Ecosystems and the Biosphere The human population moves nutrients from one part of the biosphere to another. Human activity intrudes in nutrient cycles. 1) Remove nutrients in the form of biomass: crops, lumber - can exhaust the nutrients of a system 2) Introduce excess nutrients: fertilizers and sewage - excess Nitrates in air  atmospheric problems (ozone depeletion, global warming, acid deposition) - excess Nitrates in water  eutrophication of water ways, fish kills , tainted ground water, methemoglobinemia 3) Excess consumers: livestock – depletes standing biocrops 4) Increase CO2 , Nitrate and Sulfur output – fossil fuels

16. 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 and return as 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.
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
– affects species directly

17. Field pH
5.3
5.2–5.3
5.1–5.2
5.0–5.1
4.9–5.0
4.8–4.9
4.7–4.8
4.6–4.7
4.5–4.6
4.4–4.5
4.3–4.4
4.3

18. Climate Change: Enhanced Global Warming
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.
Increased productivity by vegetation is one consequence of increasing CO2 levels.
Rising atmospheric CO2 levels may have an impact on Earth’s heat budget.

19. 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.
This phenomenon is called the greenhouse effect.
If it were not for this effect, the average air temperature on Earth would be −18°C.

20. 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.

21. 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.

22. 1 2 3
Chlorine from CFCs interacts with ozone (O3), forming chlorine monoxide (ClO) and
oxygen (O2).
Two ClO molecules react, forming chlorine peroxide (Cl2O2).
Sunlight causes Cl2O2 to break down into O2 and free chlorine atoms. The chlorine atoms can begin the cycle again.
Sunlight
Chlorine O3 O2
ClO
Cl2O2
Chlorine atoms

23. Results:
Increased levels of UV radiation
Increases in skin cancer and cataracts
Damage to plants
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.

24. 5) Add toxins and toxicants to environment
- Toxins can become concentrated in successive trophic levels of food webs.
BIOLOGICAL ACCUMULATION AND MAGNIFICATION
- Toxicants ingested and metabolized by organisms can accumulate in the fatty tissues or muscles of animals and become more concentrated in successive trophic levels of a food web
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.

25. - 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.
Ex: 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.

26. Concentration of PCBs
Herring
gull eggs
124 ppm
Zooplankton
0.123 ppm
Phytoplankton
0.025 ppm
Lake trout ppm
Smelt
1.04 ppm