1. Energy Flow Through Ecosystems
An Introduction to Energy and Laws of Thermodynamics

2. Ecosystem Ecology Levels of Organization Biosphere Biome Ecosystem
Examines interactions between the living and non-living world
Ecosystem- the sum of all the organisms living within its boundaries (biotic community) and all the abiotic factors with which they interact
Levels of Organization
Biosphere
Biome
Ecosystem
Community
Population
Organism

3. Thermodynamics Physical Laws that govern energy relationships
Involves Two Processes:
Energy Flow
– Energy cannot be recycled therefore there must be a constant supply
Chemical Recycling – Matter can be recycled and Nature does it with perfection.

4. First Law of Thermodynamics Conservation of Energy
First law of thermodynamics: Energy can be transferred or transformed but
Neither created nor destroyed. For
example, the chemical (potential) energy
in food will be converted to the kinetic
energy of the cheetah’s movement in (b).
(a)
Chemical
energy
The study of energy transformation
In short, the law of conservation of energy states that energy can not be created or destroyed, it can only be changed from one form to another or transferred from one body to another, but the total amount of energy remains constant (the same).

5. Second Law of Thermodynamics Law of Entropy
In any energy transformation, some energy is lost as unusable energy in the sense that work cannot be performed. This is usually in the form of heat.
Second law of thermodynamics: Every energy transfer or transformation increases
the disorder (entropy) of the universe. For example, disorder is added to the cheetah’s
surroundings in the form of heat and the small molecules that are the by-products
of metabolism.
(b)
Heat
co2
H2O +

6. Two Important Questions
Where does the energy needed for living organisms originate?
How is energy used by these organisms?

7. Flow of energy through life = Metabolism
The totality of an organism’s chemical reactions
driving life processes by transforming energy from one form to another
organic molecules  ATP & organic molecules
sun
organic molecules  ATP & organic molecules
solar energy  ATP & organic molecules

8. Metabolism Chemical reactions of life Oxidation – Reduction
Anabolic reactions
Catabolic reactions
Forming bonds between molecules
Consume energy
Breaking bonds between molecules
Release energy

9. Living Organisms
Temporary storage units for useful energy, whereby one organism can be used by another as a source of energy.

10. The Source of High Quality Energy
Solar
radiation
Energy in = Energy out
Reflected by
atmosphere (34%)
UV radiation
Absorbed
by ozone
by the earth
Visible
light
Lower Stratosphere
(ozone layer)
Troposphere
Heat
Greenhouse
effect
Radiated by
atmosphere
as heat (66%)
Earth
Heat radiated
Most of the Energy arrives as electromagnetic radiation from the sun
Supports photosynthesis (less than 2%)
Powers the cycling of matter
Drives climate and weather that distribute heat and H2O

11. Autotrophs are producers
They capture energy and synthesize their own organic nutrients.
They can do this by photosynthesis or chemosynthesis.
Chemosynthetic bacteria get energy and raw materials from vents called "smokers" on the ocean floor.
Tube worms rely upon the bacteria that coexist with them to make food at the bottom of the ocean.

12. Photoautotrophs
Autotrophs (=self-nourishing) are called primary producers.
Photoautotrophs fix energy from the sun and store it in complex organic compounds
green plants
algae
some bacteria
some protists
light
simple
inorganic
compounds
complex
organic
compounds
photoautotrophs

13. Chemoautotrophs chemoautotrophs Chemosynthesis.
Chemosynthetic bacteria get energy and raw materials from inorganic sources
Oxidize reduced inorganic substances (typically sulfur and ammonia compounds) and produce complex organic compounds.
Nitrifing bacteria
Halophiles (found in highly concentrated salt lakes)
Thermophiles (found in hot springs and geysers)
oxygen
complex
organic
compounds
reduced
inorganic
compounds
chemoautotrophs

14. Heterotrophs are Consumers
Heterotrophs are consumers, they must consume preformed organic nutrients synthesized by other organisms.

15. Heterotrophs heterotrophs
Heterotrophs (=other-nourishing) cannot produce their own food directly from sunlight+ inorganic compounds. They require energy previously stored in complex molecules.
Examples of heterotrophs
Herbivores – eat plants
Carnivores – eat meat
Omnivores – eat both plants and meat
Scavengers – eat carrion
Saprophytes – eat dead or decaying material
heat
complex
organic
compounds
simple
inorganic
compounds
heterotrophs
this may include several steps, with several different types of organisms

16. Components of Ecosystems
Abiotic cycles
Producers (autotrophs)
Source of all food
Photosynthesis
Chemosynthesis
Consumers (heterotrophs)
Aerobic respiration
Oxygen
Anaerobic respiration
Methane, H2S
Decomposers
Matter recyclers…
Release organic compounds into soil and water where they can be used by producers
Heat
Abiotic chemicals
(carbon dioxide,
oxygen, nitrogen,
minerals)
Producers
(plants)
Decomposers
(bacteria, fungus)
Consumers
(herbivores,
carnivores)
Solar
energy

18. PHOTOSYNTHESIS CELLULAR RESPIRATION 6CO2 + 6H2O + LIGHT C6H12O6 + 6O2
Carbon Dioxide Water
Glucose Oxygen
CELLULAR RESPIRATION
C6H12O O2
6CO H2O ENERGY
Glucose Oxygen
Carbon Dioxide Water ATP

19. Primary Productivity
Primary productivity determines the amount of energy available in an ecosystem
Primary productivity is affected mostly by light in aquatic ecosystems
Limiting nutrient is phosphorus or nitrogen
Temperature and moisture are key control factors in terrestrial ecosystems
Evapotranspitation
Water transpiration

20. Primary Productivity Gross Primary production
Total primary production in an ecosystem
Not the amount of energy available to consumers!
NPP=GPP-R
R= energy used for respiration
Energy expended: Plants use the energy captured in photosynthesis for maintenance and growth.

21. Trophic Levels – Energy Pyramids
An energy pyramid provides a means of describing the feeding and energy relationships within a food chain or web.  
Each organism in an ecosystem is assigned to a feeding (Trophic) level based on source of energy
The greatest amount of energy is found at the base of the pyramid.
The least amount of energy is found at top of the pyramid
Tertiary consumers
Secondary consumers
Primary consumers
Producers

22. Energy Flow Detritvores Heat First Trophic Level Second Trophic
Third Trophic
Fourth Trophic
Solar
energy
Producers
(plants)
Primary
consumers
(herbivores)
Tertiary
(top carnivores)
Secondary
(carnivores)
Detritvores

23. Energy Pyramid
Each step shows that some energy is stored or utilized in the organism which eats the preceding one.  
Shows that much of the energy is lost when one organism in a food chain eats another.   Most of this energy which is lost goes into the environment as heat energy.
It is estimated that only 10% of the energy at each trophic level is available to organisms at the next higher level.

24. Biomass
Energy is sometimes considered in terms of biomass = the dry weight of tissue of all the organisms and organic material in an area.
Producer organisms represent the greatest amount of living tissue or biomass at the bottom of the pyramid.  
There are more plants on Earth than there are animals.
Bio=life Mass=weight
Bio + Mass = Weight of living things within an ecosystem.

25. Why we transform each species into biomass instead of absolute numbers

26. Numbers Pyramid

27. Biomass Pyramid

28. Implications of Pyramids….
Why could the earth support more people if the eat at lower trophic levels?
Why are food chains and webs rarely more than four or five trophic levels?
Why are there so few top level carnivores?
Why are these species usually the first to suffer when the the ecosystems that support them are disrupted?

29. Number of observations10 8 6 4 2
Average number
of links = 3.5
Streams
Lakes
Terrestrial
Number of observations 1 2 3 4 5 6
Number of links in food chain

30. Food Webs
A food web is a series of interrelated food chains which provides a more accurate picture of the feeding relationships in an ecosystem
More than one thing will usually eat a particular species.
A species will many times feed at multiple levels on the trophic pyramid   

31. Generalized Food Web of the Antarctic
Humans
Blue whale
Sperm whale
Crabeater seal
Killer
whale
Elephant
seal
Leopard
Adélie
penguins
Petrel
Fish
Squid
Carnivorous plankton
Krill
Phytoplankton
Herbivorous
zooplankton
Emperor
penguin
Note: Arrows
Go in direction
Of energy flow…