Energy Flow Through Ecosystems

Ecosystems and Energy

Ecosystem: the sum of all the organisms living in a given area and the abiotic factors they interact with
- Biotic factors: living, or once living, components of an environment
- Abiotic factors: nonliving (physical and chemical properties of the environment)
1st law of thermodynamics: energy can neither be created nor destroyed, only transferred
- Law of conservation of mass: chemical elements are continually recycled in the environment
2nd law of thermodynamics: exchanges of energy increase the entropy of the universe
A net gain in energy results in energy storage or growth of an organism
A net loss of energy results in loss of mass and eventual death of an organism
Organisms use different strategies to regulate body temperature
- Endotherms: use thermal energy from metabolism to maintain body temperatures
- Ectotherms: use external sources (ie sun/shade or other organisms) to regulate their body temperature

Metabolic Rate

Metabolic rate: the total amount of energy an animal uses in a unit of time
- Can be measured in calories, heat loss, or by the amount of oxygen consumed (or CO2 produced)
  - Oxygen is used in cellular respiration and CO2 is produced as a by-product
- An animal’s metabolic rate is related to its body mass
  - Smaller organisms = higher metabolic rate
  - Larger organisms = lower metabolic rate

Semelparity vs Iteroparity

Semelparity
- Big-bang reproduction
- Many offspring produced at once
- Individual often dies afterwards
- Less stable environments
Iteroparity
- Repeated reproduction
- Few, but large offspring
- More stable environments

Trophic Levels

Species can be grouped into trophic levels based upon their mains source of nutrition and energy
Unlike mass, energy CANNOT be recycled
- The sun constantly supplies energy to ecosystems
Primary producers (autotrophs): use light energy to synthesize organic compounds
- Plants, algae, photosynthetic plankton
  - Some organisms are chemosynthetic (vs photosynthetic) meaning they produce food using the energy created by chemical reactions
    - Ie some bacteria and archaea organisms
Heterotrophs: rely on autotrophs because they cannot make their own food
- Primary consumers: herbivores
- Secondary consumers: carnivores that eat herbivores
- Tertiary consumers: carnivores that eat other carnivores
- Decomposers: get energy from detritus (nonliving organic material; leaves, wood, dead organisms)
  - Include fungi and many prokaryotes
  - Important for recycling chemical elements
The trophic structures of a community are determined by the feeding relationships between organisms
- Food chain: the transfer of food energy up the trophic levels
  - Food webs: linked food chains
Any changes to the availability of energy can disrupt ecosystems
- For example:
  - If energy resources change, so can the number and size of trophic levels (Increase energy, increase trophic levels/size; decrease energy, decrease trophic levels/size)
  - A change at the producer level can affect the number and size of the remaining trophic levels

Primary Production

Primary production: the amount of light energy that is converted to chemical energy
- Primary producers set a “spending limit” for the entire ecosystems energy budget
- Gross primary production (GPP): total primary production in an ecosystem
- Net primary production (NPP): the GPP minus the energy used by the primary producers for respiration (Ra)
Satellite images show that different ecosystems have varying NPP

Secondary Production

Secondary production: the amount of chemical energy in a consumer’s food that is converted to new biomass
- The transfer of energy between trophic levels is at around 10% efficiency

Pyramid of Biomass

Biomass: the total weight of dry matter (dry weight) present in the ecosystem at any one time; the total mass of organisms at a trophic level.
With less energy at higher trophic levels, there are usually fewer organisms as well.
Organisms tend to be larger in size at higher trophic levels, but their smaller numbers result in less biomass.

Matter Cycling

Unlike energy, matter cycles through ecosystems
- Matter is found in limited amounts, unlike solar energy
- Biogeochemical cycles: nutrient cycles that contain both biotic and abiotic factors
  - Water, carbon, nitrogen, and phosphorus cycle

Water Cycle

Biological importance of the water cycle: water is essential for all life and influences the rate of ecosystem processes

Carbon Cycle

Biological importance of the carbon cycle: carbon is essential for life and required in the formation of organic compounds

Nitrogen Cycle

Biological importance of the nitrogen cycle: nitrogen is important for the formation of amino acids, proteins, and nucleic acids

Phosphorous Cycle

Biological importance of the phosphorous cycle: phosphorus is important for the formation of nucleic acids, phospholipids, and ATP (energy)

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Energy Flow Through Ecosystems

Ecosystems and Energy

Ecosystem: the sum of all the organisms living in a given area and the abiotic factors they interact with
- Biotic factors: living, or once living, components of an environment
- Abiotic factors: nonliving (physical and chemical properties of the environment)
1st law of thermodynamics: energy can neither be created nor destroyed, only transferred
- Law of conservation of mass: chemical elements are continually recycled in the environment
2nd law of thermodynamics: exchanges of energy increase the entropy of the universe
A net gain in energy results in energy storage or growth of an organism
A net loss of energy results in loss of mass and eventual death of an organism
Organisms use different strategies to regulate body temperature
- Endotherms: use thermal energy from metabolism to maintain body temperatures
- Ectotherms: use external sources (ie sun/shade or other organisms) to regulate their body temperature

Metabolic Rate

Metabolic rate: the total amount of energy an animal uses in a unit of time
- Can be measured in calories, heat loss, or by the amount of oxygen consumed (or CO2 produced)
  - Oxygen is used in cellular respiration and CO2 is produced as a by-product
- An animal’s metabolic rate is related to its body mass
  - Smaller organisms = higher metabolic rate
  - Larger organisms = lower metabolic rate

Semelparity vs Iteroparity

Semelparity
- Big-bang reproduction
- Many offspring produced at once
- Individual often dies afterwards
- Less stable environments
Iteroparity
- Repeated reproduction
- Few, but large offspring
- More stable environments

Trophic Levels

Species can be grouped into trophic levels based upon their mains source of nutrition and energy
Unlike mass, energy CANNOT be recycled
- The sun constantly supplies energy to ecosystems
Primary producers (autotrophs): use light energy to synthesize organic compounds
- Plants, algae, photosynthetic plankton
  - Some organisms are chemosynthetic (vs photosynthetic) meaning they produce food using the energy created by chemical reactions
    - Ie some bacteria and archaea organisms
Heterotrophs: rely on autotrophs because they cannot make their own food
- Primary consumers: herbivores
- Secondary consumers: carnivores that eat herbivores
- Tertiary consumers: carnivores that eat other carnivores
- Decomposers: get energy from detritus (nonliving organic material; leaves, wood, dead organisms)
  - Include fungi and many prokaryotes
  - Important for recycling chemical elements
The trophic structures of a community are determined by the feeding relationships between organisms
- Food chain: the transfer of food energy up the trophic levels
  - Food webs: linked food chains
Any changes to the availability of energy can disrupt ecosystems
- For example:
  - If energy resources change, so can the number and size of trophic levels (Increase energy, increase trophic levels/size; decrease energy, decrease trophic levels/size)
  - A change at the producer level can affect the number and size of the remaining trophic levels

Primary Production

Primary production: the amount of light energy that is converted to chemical energy
- Primary producers set a “spending limit” for the entire ecosystems energy budget
- Gross primary production (GPP): total primary production in an ecosystem
- Net primary production (NPP): the GPP minus the energy used by the primary producers for respiration (Ra)
Satellite images show that different ecosystems have varying NPP

Secondary Production

Secondary production: the amount of chemical energy in a consumer’s food that is converted to new biomass
- The transfer of energy between trophic levels is at around 10% efficiency

Pyramid of Biomass

Biomass: the total weight of dry matter (dry weight) present in the ecosystem at any one time; the total mass of organisms at a trophic level.
With less energy at higher trophic levels, there are usually fewer organisms as well.
Organisms tend to be larger in size at higher trophic levels, but their smaller numbers result in less biomass.

Matter Cycling

Unlike energy, matter cycles through ecosystems
- Matter is found in limited amounts, unlike solar energy
- Biogeochemical cycles: nutrient cycles that contain both biotic and abiotic factors
  - Water, carbon, nitrogen, and phosphorus cycle

Water Cycle

Biological importance of the water cycle: water is essential for all life and influences the rate of ecosystem processes

Carbon Cycle

Biological importance of the carbon cycle: carbon is essential for life and required in the formation of organic compounds

Nitrogen Cycle

Biological importance of the nitrogen cycle: nitrogen is important for the formation of amino acids, proteins, and nucleic acids

Phosphorous Cycle

Biological importance of the phosphorous cycle: phosphorus is important for the formation of nucleic acids, phospholipids, and ATP (energy)