1. BIOGEOCHEMICAL CYCLES
decomposers
bacteria and fungi
soil
minerals and humus
producers
green algae
water and salts
consumers
animals
decay
die
eaten
Matter within ecosystems is recycled.
BIOGEOCHEMICAL CYCLES
Matter within an ecosystem is recycled.
(diagram of consumer--->decomposer--->soil--->producer--->consumer)

2. All Cycles Are Related All cycles are related.
Carbon, Nitrogen, Sulfur, Phosphorusin Plants and Organisms N2
Fossil Fuel Combustion
H2O
CO2
SO2, NO2
Phyto- plankton
Zoo- plankton
Ocean Sediments
Nutrient Recycling
Nitrogen Fixing Bacteria
Nitrates, Sulfates, Phosphates
Phosphate
Nitrite, Dead Organic Mattrer & Decomposers
Urea
Runoff
Respiration Decomposition
Transpiration
All cycles are related.
Diagram showing interaction of water, carbon, nitrogen, sulfur, phosphorus cycles.
Just view that many things are being recycled.
(Do not teach the cycles from this slide at this time. Repeated at end of slide show for review.)

3. BIOGEOCHEMICAL CYCLES
Water, carbon, oxygen, and nitrogen are some of the elements that cycle between the abiotic (nonliving) and biotic (living) parts of the environment.
biotic
abiotic
BIOGEOCHEMICAL CYCLES
Water, carbon, oxygen, nitrogen & other elements cycle from the abiotic (“geo” nonliving environment) to biotic (“bio” living organisms) & then back to the environment.

4. BIOGEOCHEMICAL CYCLES
Water, carbon, oxygen, and nitrogen move through a regularly repeated sequence of events.
Define a cycle.
H2O C N O
BIOGEOCHEMICAL CYCLES
Water, carbon, oxygen, nitrogen & other elements move through a regularly repeated sequence of events.
Define a cycle.
A cycle is a repeated sequence of events.

5. BIOGEOCHEMICAL CYCLES
atmosphere
“bank”
Most element cycles have an atmospheric “bank” where the element is found in large amounts.
BIOGEOCHEMICAL CYCLES
(This slide series points out the repeated events in most cycles.)
Most element cycles have an atmospheric “bank” where the element is found in large amounts.
The soil and the ocean are additional major banks for some elements.

6. BIOGEOCHEMICAL CYCLES
atmosphere
“bank”
Elements move from the “bank” into organisms.
BIOGEOCHEMICAL CYCLES
Elements move from the “bank” into organisms.

7. BIOGEOCHEMICAL CYCLES
Organisms release elements in daily activities or after death.
Give an example of an activity that releases elements.
RIP
atmosphere
“bank”
BIOGEOCHEMICAL CYCLES
Organisms release elements in daily activities or after death.
Give an example of an activity that releases elements.
Examples vary - make sure respiration is one of them, others photosynthesis, transpiration, perspiring, excretion, digestion

8. BIOGEOCHEMICAL CYCLES
Three example of cycles:
Water
Carbon (carbon-oxygen)
Nitrogen
H2O C N O
BIOGEOCHEMICAL CYCLES
Three example cycles:
Water
Carbon (carbon-oxygen)
Nitrogen

9. WATER CYCLE Use the next diagram to help you define the following:
evaporation
condensation
precipitation
transpiration
runoff
accumulation
(Have the students make a heading for Water Cycle and copy the words with space for) definition.
WATER CYCLE
Use the next diagram to help you define the following:
evaporation
condensation
precipitation
transpiration
runoff
accumulation

10. water cycle diagram
Condendation
(clouds form)
Condensation
Transpiration
Precipitation
Evaporation
Accumulation
Run-off
PRECIPITATION - water vapor (gas) changing into a liquid or solid such as rain, hail, sleet or snow
CONDENSATION - water vapor (gas) changing to a tiny drops of water (liquid) that form clouds or rain
water cycle diagram #1
Discuss the events and have the students write a brief description.
RUN-OFF - water moving across the Earth’s surface (stream, river, gully)
TRANSPIRATION - water loss from plants when water vapor goes out through stomates (little openings) in leaves
ACCUMULATION - water gathering into an area (pond, lake, stream or ocean)
EVAPORATION - water changing from a liquid into a gas (water vapor)

11. WATER CYCLE Label your diagram of the water cycle. WATER CYCLE

12. biotic
abiotic
WATER CYCLE
Abiotic parts of the water cycle include condensation, evaporation & precipitation.
WATER CYCLE
Nonliving portions of the water cycle include condensation, evaporation & precipitation.

13. biotic
abiotic
WATER CYCLE
Living portions of the water cycle include plants performing transpiration and water intake by all organisms.
WATER CYCLE
Living portions of the water cycle include plants performing transpiration and water intake by all organisms.

14. WATER CYCLE
Water vapor exits plant leaves during transpiration through tiny openings called stomata.
WATER CYCLE
Water vapor exits plant leaves during transpiration through tiny openings called stomata.

15. water cycle diagram animated
Review the cycle, using questioning to engage the students.

16. CARBON CYCLE
Why is the Carbon Cycle often called the Carbon-Oxygen Cycle?
respiration
photosynthesis O2
CO2
CARBON CYCLE
Why is the Carbon Cycle often called the Carbon-Oxygen Cycle?
The carbon and oxygen are closely related in the formation of carbon dioxide which the way carbon is “banked” in the atmosphere. It is also sometimes called the carbon dioxide cycle.

17. CARBON CYCLE
Like other element cycles, the carbon cycle links abiotic & biotic parts of the environment.
biotic
abiotic
CARBON CYCLE
Like other element cycles, the carbon cycle links nonliving & living parts of the environment.

18. CARBON CYCLE
The exchange of gases during photosynthesis and respiration is a major example of the biotic (organisms) and abiotic (atmosphere) cycle of carbon-oxygen.
CARBON CYCLE
The exchange of gases during photosynthesis and respiration is a major example of the living-nonliving cycle of carbon-oxygen.
respiration
photosynthesis O2
CO2

19. 6CO2 + 6H2O + Energy ----> C6H12O6 + 6O2
CARBON CYCLE
How does carbon enter the living part of the cycle?
Using the process of PHOTOSYNTHESIS, plants use CO2 to make food
CO2
CO2
CO2
CO2
CO2
CARBON CYCLE
How does carbon enter the living part of the cycle?
CO2 + H2O ----> C6H12O6 + O2
Carbon enters living portion of the carbon cycle through photosynthesis.
CO2
CO2
CO2
6CO2 + 6H2O + Energy ----> C6H12O6 + 6O2

20. CARBON CYCLE Carbon is returned to the atmosphere cellular respiration
erosion
combustion
decomposition
CARBON CYCLE
Carbon returned to environment by:
cellular respiration
erosion
combustion
decomposition

21. CARBON CYCLE
Use the next diagram to help you define the relationship of the following terms to the carbon cycle.
respiration
photosynthesis
decomposition
combustion
erosion
CARBON CYCLE
Use the next diagram to help you define relationship of the following terms to the carbon cycle.
respiration - CO2 is released back into the atmosphere when food (glucose) is broken down during respiration
photosynthesis - CO2 is taken from the air and trapped into food (glucose) during photosynthesis
decomposition - CO2 is released back into the atmosphere as organic matter is broken down during decomposition
combustion - CO2 is released back into the atmosphere when organic material is burned (undergoes oxidation, similar to respiration )
erosion – CO2 is released back into the atmosphere when erosion breaks down rock such as limestone containing CaCO3 (calcium carbonate)

22. CARBON CYCLE
CO2 in Atmosphere
assimilation
by plants
combustion
“BANKS” – CO2 in atmosphere and trapped underground in fossil fuels
animal respiration
decomposition
plant respiration
photosynthesis
by algae
soil erosion
RESPIRATION - CO2 is released back into the atmosphere when food (glucose) is broken down during respiration
PHOTOSYNTHESIS - Plants use carbon dioxide to make food
respiration
by algae
and aquatic
animals
CARBON CYCLE
Discuss terms and what is happening at each directional arrow. (Have students note which arrow captures and which arrow releases carbon.)
litter
EROSION - CO2 is released back into the atmosphere when erosion breaks down certain rock
COMBUSTION - CO2 is released back into the atmosphere when organic material is burned
fossil fuels
coal, gas, petroleum
oceans, lakes
limestone
decomposition
DECOMPOSITION - CO2 is released back into the atmosphere as organic matter is broken down

23. N2 free nitrogen NITROGEN CYCLE
79% of the atmosphere is nitrogen gas but it is in a form most living things cannot use. N2
free
nitrogen
NITROGEN CYCLE
79% of the atmosphere is nitrogen gas but it is in a form most living things cannot use.

24. NITROGEN CYCLE
If we can’t take in free nitrogen, how do organisms acquire it so it can be used?
Why do living things need nitrogen?
NITROGEN CYCLE
If we can’t take in free nitrogen, how do we acquire it so we can use it in our bodies?
Why do we need nitrogen in our bodies?
(Don’t answer these now – they lead to next item.)

25. NITROGEN CYCLE
How does Nitrogen move from the abiotic part (atmosphere) into the biotic part (organisms) of the environment?
Step #1-Nitrogen-fixing bacteria convert nitrogen into nitrates.
Step #2-Plants absorb nitrates.
Step #3-Animals eat plants.
NITROGEN CYCLE
How do we acquire usable nitrogen?
Nitrogen-fixing bacteria convert nitrogen into nitrates.
Plants absorb nitrates.
Animals eat plants. N2
in air
nitrogen-fixing
bacteria
NITRATES
Step # Step # Step #3

26. NITROGEN CYCLE
How does the nitrogen return to the abiotic (atmosphere) part of the environment?
Step #4-Denitrifying bacteria convert the nitrates back into nitrogen.
denitrifying
bacteria
Step #4
NITROGEN CYCLE
How does the nitrogen return to the atmosphere?
Denitrifying bacteria convert the nitrates back into nitrogen. N2
in air
nitrogen-fixing
bacteria
NITRATES

27. ? NITROGEN CYCLE Why do we need nitrogen? protein DNA Nitrogen
Nitrogen is an essential element for all proteins (amino acids) and nucleic acids.
DNA ?
Nitrogen

28. NITROGEN CYCLE Can plants & animals use free nitrogen (N2)?
In what form must N2 be to be used by plants?
What organisms can turn the N2 into a usable form?
nitrates
NITROGEN CYCLE
Can plants & animals use free nitrogen? plants & animals cannot use free nitrogen in the atmosphere
In what form must N2 be to be used by plants? nitrates
What organisms can fix the N2 into a usable form? nitrogen-fixing bacteria
nitrogen-fixing
bacteria

29. NITROGEN CYCLE Simplified
Use the next diagram to help you define the relationship of the following terms to the nitrogen cycle.
free N2 bank
nitrogen fixation
nitrates
organisms
organic material
denitrification
NITROGEN CYCLE Simplified
Use the next diagram to help you define relationship of the following terms to the nitrogen cycle
free N2 “bank”: Free means pure nitrogen not in any other compound. The “bank” is the atmosphere which is made up of 79% nitrogen.
nitrogen-fixation: nitrogen-fixing bacteria convert free nitrogen into nitrate compounds
nitrates: the form of nitrogen that can can be used by organisms
organisms: Plants take in nitrates and use them in their tissues; animals eat the plants and get the nitrates from their tissues
organic material: Dead organisms, animal waste and organic litter are decomposed by bacteria and other decomposers
denitrification: Denitrifying bacteria convert nitrates from decomposition back into free nitrogen.

30. NITROGEN CYCLE Simplified
DENITRIFICATION - Denitrifying bacteria convert nitrates from decomposition back into free nitrogen.
Free N2 in Atmosphere
FREE N2 “BANK” - Pure nitrogen “banked” in the atmosphere which is made up of 79% nitrogen.
ORGANIC MATERIAL - Dead organisms, animal waste and organic litter are decomposed by bacteria and other decomposers
denitrifying
bacteria
nitrogen-fixing
bacteria
NITROGEN FIXING BACTERIA - nitrogen-fixing bacteria convert free nitrogen into nitrate compounds
ORGANISMS - Plants take in nitrates and use them in their tissues; animals eat the plants and get the nitrates from plant tissues
NITROGEN CYCLE SIMPLIFIED
diagram of nitrogen cycle
Discuss the diagram and have student label the diagram on their handout.
RIP
Organic
material
organisms
NITRATES
NITRATES - the form of nitrogen that can be used by organisms

31. NITROGEN CYCLE gaseous losses (N2, NOx) lightning fixes N2 into
nitrogen-fixing
bacteria
nitrates
organic
matter
denitrifying
gaseous losses (N2, NOx)
lightning
fixes N2 into
NITROGEN CYCLE
diagram of nitrogen cycle
Review the events in the nitrogen cycle.

32. Reviewing the Cycles WATER CYCLE evaporation condensation
precipitation
transpiration
Reviewing the Cycles
WATER CYCLE
evaporation
condensation
precipitation
transpiration

33. Reviewing the Cycles CARBON CYCLE photosynthesis-respiration
combustion
erosion
decomposition
RIP
atmosphere
“bank”
Reviewing the Cycles
CARBON CYCLE
photosynthesis-respiration
combustion
erosion
decomposition

34. Reviewing the Cycles NITROGEN CYCLE nitrogen-fixing bacteria nitrates
decomposition
denitrification
Free N2 in Atmosphere
nitrogen-fixing
bacteria
NITRATES
RIP
Organic
material
denitrifying
Reviewing the Cycles
NITROGEN CYCLE
nitrates
nitrogen-fixing bacteria
denitrification
decomposition

35. Cycle Interrelationships
Carbon, Nitrogen, Sulfur, Phosphorusin Plants and Organisms N2
Fossil Fuel Combustion
H2O
CO2
SO2, NO2
Phyto- plankton
Zoo- plankton
Ocean Sediments
Nutrient Recycling
Nitrogen Fixing Bacteria
Nitrates, Sulfates, Phosphates
Phosphate
Nitrite, Dead Organic Mattrer & Decomposers
Urea
Runoff
Respiration Decomposition
Transpiration
Cycle Interrelationships
Point put parts of each cycle and have students identify the event and cycle(s)