Producers
Producers are able to produce carbohydrates from the energy of the sun
through photosynthesis or, in some instances, from inorganic molecules
through chemosynthesis. Because they can produce their own
food, producers are also called autotrophs. Producers form the
foundation of every food chain because only they can transform
inorganic energy into energy that all other organisms can use. On
land, plants and photosynthetic bacteria are the main producers. In
marine environments, green plants and algae are the main producers. In
deep water environments near geothermal vents, chemosynthetic
organisms are the main producers.
Video - Producers and Consumers
Consumers
ife; instead, consumers must ingest other organisms in order to get
these materials. Consumers are also called heterotrophs because
they must consume other organisms in order to get the energy necessary
for life. There are three types of consumers; the categories of
consumers are based on which organisms a particular consumer preys on.
Primary consumers, such as sheep, grasshoppers, and rabbits,
feed on producers. Since all producers are plants or plantlike, all
primary consumers are herbivores, which is the name for a plant-eating
animal. Secondary consumers eat primary consumers, making them
carnivores—animals that eat other animals. Foxes and insect-eating
birds are examples of secondary consumers. Tertiary consumers
eat secondary consumers and are therefore carnivores. Polar bears that
eat sea lions are tertiary consumers. Consumers that eat both
producers and other consumers are called omnivores.
Decomposers
Also called saprophytes, decomposers feed on waste or dead
material. Since they must ingest organic molecules in order to
survive, decomposers are heterotrophs. In the process of getting the
energy they need, decomposers break down complex organic molecules
into their inorganic parts—carbon dioxide, nitrogen, phosphorus, etc.
Food Chain, Food Web, Pyramids, and Biomagnification
Food Chains and Food Webs
All predatory interactions between producers and consumers in a community can be organized in food chains or more complex and realistic food webs. A food chain imagines a strictly linear interaction between the levels of producers and consumers we described above. An abstract food chain appears below on the left, with examples of animals that fit each category appearing on the right:
Each step in the food chain is referred to as a trophic level.
Food chains are simple and help us to understand the predation interactions between organisms, but because they are so simple, they aren’t really accurate. For instance, while sparrows do eat insects, they also eat grass. In addition, the food chain makes it seem as if there are only four populations in a community, when most communities contain far more. Most organisms in a community hunt more than one kind of prey and are hunted by more than one predator. These numerous predation interactions are best shown by a food web:
In fact, the more diverse and complicated the food relationships are in
a community, the more stable that community will be. Imagine a
community that was correctly described by the food chain grass
? insect ? sparrows?hawks.
If some blight struck the grass population, the insect population
would be decimated, which would destroy the sparrow population, and so
on, until the very top of the food chain. A more complex food web is
able to absorb and withstand such disasters. If something were to
happen to the grass in the food web, the primary consumers would all
have some other food source to tide them over until the grass
recovered.
The energy lost between each trophic level affects the number of
organisms that can occupy each trophic level. If the secondary
consumer trophic level contains 10
percent of the energy present in the primary consumer level, it
follows that there can only be about 10
percent as many secondary consumers as there are primary consumers.
The energy pyramid is therefore also a biomass pyramid that
shows the number of individuals in each trophic level.
Biological Magnification
Because biomass drops so dramatically from one trophic level to the next, any chemical present in a lower trophic level becomes heavily concentrated in higher trophic levels. Beginning in the 1940s, a pesticide called DDT was sprayed on crops to stop invading insects. The concentration of DDT in any local area was enough to kill insects, but not enough to hurt any of the larger organisms. But as each predator ate its prey, the DDT became concentrated in successive trophic levels. The small levels of DDT found in the insects became much more concentrated as it was swallowed and digested by predators. Eagles, sitting at the top of the food web, took in massive amounts of DDT in the course of eating their prey. The DDT caused the eagles to lay soft eggs that could not protect the developing embryos inside, which led to a severe population decline.
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