Ecological Pyramids (DP IB Environmental Systems & Societies (ESS))
Revision Note
Ecological Pyramids
Ecological pyramids include:
Pyramids of numbers
Pyramids of biomass
Pyramids of energy (also known as pyramids of productivity)
They are quantitative models usually measured for a given time and area
Pyramids of numbers
Ecological pyramids include:
Pyramids of numbers
Pyramids of biomass
Pyramids of energy
They are quantitative models usually measured for a given time and given area
A pyramid of numbers shows how many organisms we are talking about at each level of a food chain
The width of the box indicates the number of organisms at that trophic level
For example, consider the following food chain:
grass → vole → owl
A pyramid of numbers for this food chain would look like the one shown below
Often, the number of organisms decreases along food chains, as there is a decrease in available energy since some energy is lost to the surrounding environment at each trophic level
Therefore pyramids of numbers usually become narrower towards the apex (the top)
Despite the name, a pyramid of numbers doesn’t always have to be pyramid-shaped
For example, consider the following food chain:
oak tree → insects → woodpecker
The pyramids of numbers for this food chain will display a different pattern to the first food chain
When individuals at lower trophic levels are relatively large, like the oak tree, the pyramid becomes inverted:
Only a single oak tree is needed to support large numbers of insects (which can then support large numbers of woodpeckers)
Pyramids of biomass
A pyramid of biomass shows how much mass the organisms at each trophic level would have without including all the water that is in the organisms:
This is known as their ‘dry mass’
As per the second law of thermodynamics, the quantities of biomass generally decrease along food chains, so the pyramids become narrower towards the top
If we take our first food chain as an example, it would be impossible to have 10kg of grass feeding 50kg of voles feeding 100kg of barn owls
Being able to construct accurate pyramids of biomass from appropriate data is an important skill
Worked Example
The table below shows:
A food chain with four trophic levels
The total mass of organisms at each trophic level
| Clover → | Snail → | Thrush → | Sparrowhawk |
---|---|---|---|---|
Biomass (kg) | 80 | 30 | 10 | 2 |
Draw a pyramid of biomass for the food chain in Table 1.
Pyramids of biomass are usually pyramid-shaped, regardless of what the pyramid of numbers for that food chain looks like
However, they can occasionally be inverted and show higher quantities at higher trophic levels
These inverted pyramids sometimes occur due to marked seasonal variations
For example, in some marine ecosystems, the standing crop of phytoplankton, the major producers, is lower than the mass of the primary consumers, such as zooplankton
This is because the phytoplankton reproduce very quickly and are constantly being consumed by the primary consumers, which leads to a lower standing crop but higher productivity
This can occur because phytoplankton can vary greatly in productivity (and therefore biomass) depending on sunlight intensity
Pyramids of energy
Pyramids of energy (also referred to as pyramids of productivity) show the flow of energy through trophic levels, indicating the rate at which that energy is being generated
Pyramids of productivity illustrate the amount of energy or biomass of organisms at each trophic level per unit area per unit time
Productivity is measured in units of flow
The units are mass or energy per metre squared per year (g/kg m-2 yr-1 or J/kJ m-2 yr-1)
The length of each box, or bar, represents the quantity of energy present
These pyramids are always widest at the base and decrease in size as they go up
This is because pyramids of productivity for entire ecosystems over a year always show a decrease along the food chain, following the second law of thermodynamics
The base is wide due to the large amount of energy contained within the biomass of producers
As you move up the pyramid to higher trophic levels, the quantity of energy decreases as not all energy is transferred to the biomass of the next trophic level (roughly 10 % of the energy is passed on)
Energy is lost at each trophic level due to:
Incomplete consumption
Incomplete digestion
Loss of heat energy to the environment during respiration
Excretion of the waste products of metabolism e.g. carbon dioxide, water, and urea
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