Essentials of Ecology

CONCEPTS 3-4A AND 3-4B 63

Figure 3-14 Greatly simplified food web

in the Antarctic. Many more participants in

the web, including an array of decomposer

and detritus feeder organisms, are not

depicted here. Question: Can you imag-

ine a food web of which you are a part?

Try drawing a simple diagram of it.

Squid

Fish

Krill Herbivorous

zooplankton

Phytoplankton

CarnivorousCarnivorous

planktonplankton

Carnivorous

plankton

́

Humans

Blue whale

Killer

whale

Elephant

seal

Crabeater

seal

Leopard

seal

Emperor

penguin

Adelie

penguin

Petrel

Sperm whale

Heat

Heat Heat

Heat

Heat

Decomposers

Tertiary
consumers
(human)

Primary
consumers
(zooplankton)

Producers
(phytoplankton)

10

100

Secondary
consumers
(perch)

Usable energy available

at each trophic level

(in kilocalories)

10,000

1,000

Figure 3-15 Generalized pyramid of energy flow

showing the decrease in usable chemical energy

available at each succeeding trophic level in a

food chain or web. In nature, ecological efficiency

varies from 2% to 40%, with 10% efficiency

being common. This model assumes a 10%

ecological efficiency (90% loss of usable energy

to the environment, in the form of low-quality

heat) with each transfer from one trophic level

to another. Question: Why is a vegetarian diet

more energy efficient than a meat-based diet?

Energy flow pyramids explain why the earth can
support more people if they eat at lower trophic lev-

els by consuming grains, vegetables, and fruits directly,

rather than passing such crops through another trophic

level and eating grain eaters or herbivores such as cattle.

About two-thirds of the world’s people survive primar-

ily by eating wheat, rice, and corn at the first trophic

level, mostly because they cannot afford meat.