1. Chapter 4: Ecosystems
The Living World Unit

2. Members of an Ecosystem
Eukaryotic cells (have nucleus)
Prokaryotic cells (no nucleus/bacteria)
Different Species
Within a specific range/distribution
Direct or indirect interactions among populations
ALL ecosystems make up Earth’s Biosphere

3. Biosphere 2 Project
3.15 acre structure built in the 1980’s in Arizona to see if a sealed, self-sustaining environment was possible. ($200 million; privately funded)
Unable to control temperature
Contained:
Over 3,500 plant and animal species
5 biomes: desert, grassland, marsh, ocean, rainforest
8 humans ( )
Outcome:
After 1 year, oxygen levels dropped too much and had to be pumped in
76% of vertebrate species went extinct
Ocean became too acidic
Air pollution
Is now owned by Columbia University

4. (crust, top of upper mantle)
Oceanic crust
Continental crust
Vegetation
and animals
Biosphere
Lithosphere
Upper mantle
Soil
Crust
Asthenosphere
Rock
Lower mantle
“Spheres”
Core
Mantle
Crust
(soil and rock)
Biosphere
(Living and dead
organisms)
Atmosphere
(air)
Lithosphere
(crust, top of upper mantle)
Hydrosphere
(water)

5. Biomes/Zones of Earth Terrestrial portions are called biomes
Forests (conifer, deciduous, rain forest)
Deserts
Grasslands
Aquatic Life Zones
Freshwater (lakes, ponds, rivers, streams, wetlands)
Marine (coral reefs, coastal regions, deep ocean)

6. It starts with the sun! 1 billionth of sun’s output reaches Earth
Solar
radiation
Energy in = Energy out
Reflected by
atmosphere (34%)
1 billionth of sun’s output reaches Earth
UV radiation
Radiated by
atmosphere
as heat (66%)
Lower stratosphere
(ozone layer)
Visible
light
Greenhouse
effect
Carbon dioxide, methane, NOx, H2O, O3: natural sources
Absorbed
by ozone
Troposphere
Heat
Absorbed
by the earth
Heat radiated
by the earth
Earth

7. Photosynthesis Formula:
Carbon dioxide + water + sunlight  glucose + oxygen
CO2 + H2O + solar Energy  C6H12O6 + O2
Producers or autotrophs are capable of photosynthesis
Chemosynthesis: photosynthesis without sunlight (specialized bacteria can do this)
Autotrophs/producers are typically found at the bottom of the “food chain”

8. Who are you calling a Heterotroph?
Scavengers
Nutrients from dead and decaying animal/meat
Omnivores
Nutrients from both plant and animal matter
Carnivores
Nutrients from animals/meat
Herbivore
Nutrients from plant material
Detritivore
Nutrients from dead organic matter (plant or animal)
Decomposers put nutrients back into ground

9. Powder broken down by decomposers into plant nutrients in soil
Detritus feeders
Decomposers
Bark beetle
engraving
Carpenter
ant
galleries
Termite and
carpenter
ant
work
Long-horned
beetle holes
Dry rot fungus
Wood
reduced
to powder
Mushroom
Powder broken down by decomposers
into plant nutrients in soil
Time progression
Detritivores

10. Respiration is more than breathing?
Aerobic respiration: making energy in the presence of oxygen
Glucose + oxygen  carbon dioxide + water + energy
C6H12O6 + 6O2  6CO2 + H2O + energy
Anaerobic respiration: energy gained in absence of oxygen. By products include methane gas, acetic acid
This process was taking place in waste water treatment plant!

11. Variety is the Spice of Life
Genetic diversity: variety of genetic material/traits within a population.
Species diversity: the number of species present in an area.
Ecological diversity: variety of ecosystems found in an area or on the Earth
Functional diversity: Biological and chemical processes needed for survival

12. (decomposers and detritus feeders)
First Trophic
Level
Second Trophic
Level
Third Trophic
Level
Fourth Trophic
Level
Producers
(plants)
Primary
consumers
(herbivores)
Secondary
consumers
(carnivores)
Tertiary
consumers
(top carnivores)
Heat
Heat
Heat
Heat
Solar
energy
Heat
Heat
Heat
Heat
Heat
Detritivores
(decomposers and detritus feeders)
Types of Consumers

13. Ecological Efficiency
Ecological efficiency: useable energy that is passed along from one trophic level to the next. Typical is 10% efficient (90% of energy is lost)
Top carnivores
Carnivores
Herbivores
Producers
5,060
Decomposers/detritivores
20,810
3,368
383 21

14. (decomposers and detritus feeders)
First Trophic
Level
Second Trophic
Level
Third Trophic
Level
Fourth Trophic
Level
Producers
(plants)
Primary
consumers
(herbivores)
Secondary
consumers
(carnivores)
Tertiary
consumers
(top carnivores)
Heat
Heat
Heat
Heat
Solar
energy
Heat
Heat
Heat
Heat
Heat
Detritivores
(decomposers and detritus feeders)
Food Chains

15. Food Webs Humans Blue whale Sperm whale Killer whale Elephant seal
Crabeater seal
Leopard
seal
Emperor
penguin
Adélie
penguins
Petrel
Squid
Fish
Carnivorous plankton
Herbivorous
zooplankton
Krill
Phytoplankton

16. The dirt on dirt
Soil horizon: a horizontal layer with a distinct texture and composition. (soil triangle)
Soil profile: cross section of horizons. Can use a sampling tube to see profile. Mature, undisturbed soils have at least 3 of the 4 horizons.

17. Soil Profiles
We will complete soil profile pictures by using text. Feel free to view these slides from the website at a later time to understand each of the horizons that make up the various profiles.
Viewing them in lecture would be quite boring.

18. O horizon Location: very top of ground to a few inches down
Composition: undecomposed leaves, partially decomposed leaves, twigs, grasses, crop waste, animal waste, fungi
Color: brown or black
Additional information: not very deep; some biomes have very little O horizon (desert)

19. A Horizon Location: Just underneath O Horizon
Composition: has partially decomposed organic matter (humus), inorganic nutrients. Also known as topsoil.
Color: brown or dark brown (fertile), gray, yellow, reddish (not as fertile)
Additional information: Depth will varying by biome/region. Lots of life (bugs, worms, bacteria, fungi)
Bottom of A Horizon is the zone of Eluviation (or E horizon). Loss of minerals and nutrients here – were pushed downward.

20. E Horizon
Location: Underneath A horizon (sometimes is included as just a part of the A horizon)
Composition: Lacking in nutrients, leaching of nutrients into B horizon occurs here
Color: lighter shade of the A horizon
Additional information: E horizon may be included as a part of the A horizon and not listed. Mostly found in forested area soils.

21. B Horizon Location: Underneath E or A horizon
Composition: More dense because of fine particles from upper zones leaching down. Also called subsoil
Color: yellowish to brown
Additional information: Typically a dense layer with more clay content. Depth of B horizon may vary by biome/region
Cool animation of leaching.

22. C Horizon Location: Fairly deep – 3+ feet down
Composition: Chunks of rock and parent material of the upper layer soil. Mostly inorganic
Color: lighter – rock.
Additional information: C horizon is also referred to as the Parent material and contains clay, sand, gravel.

23. R Horizon Location: Under the C horizon Composition: solid bedrock
Color: lighter – rock.
Additional information: R horizon is not considered soil. It is solid bedrock. May not be shown on all graphics/profiles.

24. Profiles
O Horizon
A Horizon
E Horizon
B Horizon
C Horizon

25. Soil Profiles - Biomes O A A E B B C C R Mosaic of closely packed
pebbles,
boulders O A A
Alkaline,
dark, and rich
in humus
Weak humus-
mineral mixture E B
Dry, brown to
reddish-brown, with
variable accumulations
of clay, calcium
carbonate, and
soluble salts B
Clay, calcium
compounds C C R
Desert Soil
(hot, dry climate)
Grassland Soil
(semiarid climate)

26. Soil Profiles - Biomes O O O A A A/E E E B B B C C C R R R
Tropical Rain Forest Soil
(humid, tropical climate)
Deciduous Forest Soil
(humid, mild climate)
Coniferous Forest Soil
(humid, cold climate)

27. Soil Texture Pyramid
Find:
50% clay
15% sand
35% silt

28. Soil Texture Pyramid 2
Find:
30% clay
35% sand
35% silt

29. Figure 4-28 Page 76 Water Cycle Condensation Precipitation
Transpiration
from plants
Evaporation
from land
Evaporation
from ocean
Runoff
Surface runoff
Precipitation
Infiltration and
Percolation
Surface
runoff
Groundwater movement
Ocean
Water Cycle

30. Carbon Cycle Diffusion Combustion of fossil fuels Carbon dioxide
dissolved in
ocean water
photosynthesis
aerobic respiration
Marine food webs
sediments
death, sedimentation
uplifting over geologic time
sedimentation
Marine sediments, including
formations with fossil fuels

31. Carbon Cycle Atmosphere Combustion of fossil fuels volcanic action
combustion of wood
photosynthesis
aerobic respiration
Terrestrial
rocks
Land food webs
sedimentation
weathering
Soil water
(dissolved carbon)
Peat,
fossil fuels
death, burial, compaction over geologic time
leaching runoff
Carbon Cycle

32. Nitrogen Cycle Gaseous Nitrogen (N2) in Atmosphere Nitrogen Fixation
© 2004 Brooks/Cole – Thomson Learning
Gaseous Nitrogen (N2)
in Atmosphere
Nitrogen Fixation
(Legumes)
Food Webs On Land
uptake by autotrophs
excretion, death, decomposition
uptake by autotrophs
Fertilizers
Nitrogen Fixation
bacteria convert N2 to ammonia (NH3) ; this dissolves to form ammonium (NH4+)
Nitrogenous Wastes, Remains In Soil
NO3 –
in soil
Denitrification
by bacteria
Ammonification
bacteria, fungi convert the residues to NH3 , this dissolves to form NH4+
2. Nitrification
bacteria convert NO2- to nitrate (NO3-)
NH3, NH4+
in soil
1. Nitrification
bacteria convert NH4+ to nitrate (NO2–)
loss by leaching
NO2 –
in soil
loss by leaching
Nitrogen Cycle

33. Nitrogen Ways nitrogen gets INTO ground Ways nitrogen leaves ground:
Lightening
Decomposition
Nitrification (legumes)
Fertilizer
Leaching
Denitrification
Use by autotrophs
Harvesting/removal of crops

34. Phosphorous Cycle mining FERTILIZER excretion GUANO agriculture
weathering
uptake by autotrophs
uptake by autotrophs
MARINE FOOD WEBS
DISSOLVED IN OCEAN WATER
leaching, runoff
DISSOLVED IN SOIL WATER, LAKES, RIVERS
LAND FOOD WEBS
death, decomposition
death, decomposition
sedimentation
settling out
weathering
uplifting over geologic time
ROCKS
MARINE SEDIMENTS
Phosphorous Cycle

35. Phosphorous Ways phosphorous gets INTO ground
Ways phosphorous leaves ground:
Guano
Phosphate salts
Fertilizer
Decompositions
weathering
Uptake by autotrophs
Use in food chains and webs
Sedimentation/rock cycle

36. Acidic fog and precipitation
Water
Acidic fog and precipitation
Sulfur trioxide
Sulfuric acid
Ammonia
Ammonium sulfate
Oxygen
Sulfur dioxide
Hydrogen sulfide
Plants
Volcano
Dimethyl sulfide
Industries
Animals
Ocean
Sulfate salts
Death, decay
Metallic
sulfide deposits
Sulfur
Hydrogen sulfide
Sulfur Cycle

37. Sulfur Ways sulfur gets INTO ground/atmosphere
Ways phosphorous leaves ground:
Fertilizer
Volcanoes
Hot springs
Factory emissions
Uptake by autotrophs
Use in food chains and webs
Sedimentation/rock cycle