6th Grade Common Assessment Cycle 2 Study Guide Reading

Ecosystems - Trophic Levels

The organization of communities is based on the use of energy from the Sun within a

given ecosystem. Organisms within a community are dependent on the survival of the other

organisms because energy is passed from one organism to another.The Sun's energy cycles

through ecosystems from producers through consumers and back into the nutrient pool through

decomposers.

A trophic level describes the feeding level that an organism belongs to.Producer, decomposer,

primary consumer, secondary consumer, and tertiary consumer are all trophic levels that can

be used to describe an organism's place in an ecosystem.

Producer

Producers, such as green plants, use photosynthesis to make their own food using energy from

the Sun. Other producers include algae and some kinds of bacteria and protists.

Green plants, such as sunflowers, are producers that use energy from the Sun to make

food. All of the other organisms in an ecosystem depend on producers for energy.

Consumer

Consumers are organisms that gain energy by eating producers and/or other

consumers. Primary consumers are organisms that feed off of producers.Herbivores are

primary consumers. For example, a deer that eats grass is a primary consumer. Secondary

consumers are organisms that eat primary consumers. Carnivores are secondary

consumers. A wolf that kills and eats a deer is a secondary consumer. Next come tertiary

consumers, then quaternary consumers, and so forth until the top carnivore is reached.

Consumers eat other organisms. Deer are primary consumers because they eat grass, which is

a producer. Wolves are secondary consumers because they eat primary consumers like deer.

Decomposer

Decomposers are organisms that consume dead organisms and release nutrients from dead

plants and animals into the soil, water, and atmosphere.The role that decomposers play in an

ecosystem is crucial. Decomposers are important for the water, carbon, nitrogen, and oxygen

cycles. The nutrients that decomposers release into the soil are also used by producers to make

food.Fungi, such as mushrooms, are examples of decomposers. Some kinds of bacteria are

also decomposers.

Decomposers, such as mushrooms, are vital to ecosystems because they decompose dead

organisms and recycle nutrients back into ecosystems.

Matter & Energy in Ecosystems

Food chains, food webs, and energy pyramids are models that can show the flow of energy and

matter through ecosystems.Matter and energy are conserved as they are transferred and

transformed.

Food Chains

A food chain describes the feeding relationships and energy flow between species within an

ecosystem.

Producers receive energy from the Sun and make food. Producers are the beginning of a food

chain because all of the other organisms in the food chain depend on the food energy that is

made by producers. The next organisms in the food chain are primary consumers, which eat

producers. Next comesecondary consumers, then tertiary consumers, and so forth until the

top consumer is reached. All organisms in the food chain are decomposed bydecomposers.

This food chain shows the flow of energy from a producer, algae, to the consumers in the

ecosystem. Minnows are primary consumers, salmon are secondary consumers, and bears are

tertiary consumers.

The arrows in a food chain represent the direction of energy flow. An arrow points from the

organism that is being consumed to the organism that is receiving energy. For example, in the

food chain above, an arrow points from the algae to the minnow. This means that the minnow

is consuming the algae and receiving energy.

Food Webs

A food web is a group of interconnected food chains. Food webs are commonly used to show

the flow of energy through an ecosystem. However, they are also useful tools for following the

flow of matter. As in food chains, the arrows in a food web indicate the direction the energy

and organic matter flow within an ecosystem.

Organisms within a food web can belong to more than one trophic level, or feeding level. For

example, in the food web below, krill are primary, secondary, and tertiary consumers. Krill are

primary consumers because they eat phytoplankton, which are producers. Krill are also

secondary consumers because they eat herbivorous zooplankton, which are primary

consumers. Krill are tertiary consumers because they eat carnivorous zooplankton, which are

secondary consumers.

An Antarctic food web is shown in the picture above. Organisms in food webs can belong to

more than one feeding level.

Another food web is shown below.

In one of the feeding relationships shown in this food web, organic matter from the grass—in

the form of the sugars, proteins, and water that make up the grass's leaves—becomes

incorporated into the grasshopper. The organic material in the grasshopper is transferred to the

frog when the frog eats the grasshopper and then to the copperhead when the copperhead eats

the frog.When the copperhead dies, its matter will be broken down by decomposers into

smaller molecules which can be released into the atmosphere or become part of the

soil. Ultimately, the atoms in the released molecules will be used by other organisms to build

body structures.

Energy Pyramid

An energy pyramid is a diagram that shows the relative amounts of energy located within

each trophic level. The trophic levels are stacked one on top of another, with the producers on

the bottom. Each level in an energy pyramid has less energy available to it than the level

below.

Most of the stored energy in an ecosystem is in plants and other producers.This is because

most of the energy in an energy pyramid is used or lost as heat energy as it moves up the

pyramid. In fact, only about 10% of the energy produced at each level is available to the one

above it. This is the reason that consumers in an ecosystem cannot outnumber producers, and

predators cannot outnumber prey.

The size of each level of the energy pyramid is determined by the amount of energy stored in

the organisms at that trophic level.

An average of only 10% of the energy from the previous level moves to the next level. The

rest is used up or lost as heat energy.

Conservation of Matter and Energy in Ecosystems

Ecosystems are generally not considered closed systems in terms of matter.Organisms in an

ecosystem give off gases, water, and other wastes that may find their way into the atmosphere

or other ecosystems. Likewise, when producers take in carbon dioxide and produce sugars

with them, they are bringing new matter into the ecosystem from the surroundings.

However, matter is conserved as it moves from one step in a food chain or web to another. For

example, if a bird swallows a grasshopper, all of the matter that made up the grasshopper's

body is inside the bird's body. Some of the matter will be used to make new building and

energy-producing materials for the bird's body. The rest of the matter will be converted into

waste materials that are eliminated from the bird's body and deposited back into the

environment as urine, feces, and waste gases.

Decomposers break down animal wastes and the remains of dead plants and animals. Through

this process, matter is converted back to water and nutrients, which are then returned to the

soil and the atmosphere. This allows the cycle to continue.

Matter and energy are transferred from one organism to another in ecosystems.

Energy is also transformed as it flows through an ecosystem. The total amount of energy in the

universe remains constant, but, unlike matter, energy is able to move freely into and out of the

Earth system. Almost all of the energy entering ecosystems comes from the Sun. Producers are

able to capture some of the Sun's energy during photosynthesis and convert it to chemical

energy.

When consumers feed on producers, some of the producer's energy is transferred to the

consumer. Energy is transferred in a similar fashion each time any consumer or decomposer

feeds on any other organism.

Organisms also use energy to perform life functions. For example, animals use energy to

contract muscles during movement. This process transforms some energy into heat, which is

transferred to the environment. Therefore, when that animal is later consumed, only some of

its energy is transferred to the organism consuming it.

All of the energy that is captured by producers is eventually released and returned to the

environment as heat.

Basic Needs & Organism Growth

All living organisms have basic needs. Organisms must be able to acquire the things that they

need from their habitats in order to grow and survive.

Basic Needs of Animals

The basic needs of animals include shelter, food, water, air, space, waste removal, and a

particular range of temperatures.

Shelter—Animals need shelter because shelter provides protection from the elements and from predators. A bird's nest is an example of shelter.

Food—Animals need food because it provides the energy and nutrients necessary to perform life functions. Some animals eat plants. Some animals eat other animals. Some animals eat both plants and other animals.

Water—Animals need water because it transports nutrients and wastes in the animals' bodies, and it helps keep body temperatures constant.

Air—Animals need air because oxygen is needed for the chemical process that releases energy from food.

Space—Animals need space because overcrowded areas can lead to starvation and disease.

Waste removal—Animals need to be able to remove wastes because waste is produced as animals use food, water, and air for life processes. Animals must be able to get rid of this waste to survive.

Temperature range—Animals are best suited to survive in certain temperature ranges.

Animals meet their needs in the habitat, or environment, in which they live.The environment

is everything that surrounds and affects an animal. This includes the plants and other animals

in the area, rocks, soil, air, and water.Both living and non-living things are part of an

environment.

Basic Needs of Plants

The basic needs of plants include sunlight, water, air, soil, and space.

Sunlight—Plants get energy from the Sun. Chlorophyll found in plant leaves uses sunlight to change water, minerals, and carbon dioxide into food. This process is called photosynthesis.

Water—Plants must have water because it helps carry nutrients from the soil to the plant's roots. Water is part of plant cells and is necessary for photosynthesis.

Minerals & Nutrients From Soil—Plants need soil because they use it to get water, nutrients, and minerals.

Air—Plants also get nutrients from the air. During photosynthesis, plants take in carbon dioxide from the air and release oxygen.

Space—Plants need space to grow. If there are too many plants for the amount of sunlight, soil, minerals, or space, some of the plants will not survive.

Basic Needs & Organism Growth

While the growth of an organism is partially controlled by the organism's genetic code,

availability of resources also plays a role. Organisms need access to enough resources to meet

their basic needs. For example, if a plant receives very little water for an extended period of

time, the plant might grow much slower than normal. If it is deprived of water for long

enough, the plant may never reach the size that it would have if it had received enough water

during its growth. Likewise, if a plant does not receive enough sunlight or if its environment is

too hot or too cold, then the plant may not grow as large as its potential, and it may eventually

die.

Animal growth is also impacted by the availability of resources to meet the animal's basic

needs. For example, the growth of a koi fish is dependent on the space available to it in its

environment. A koi fish will grow much larger in a large environment than it will in a small

environment. This is due to differences in food availability, as well as water quality.

A koi fish that grows up in a small pond like this one may never get as large as if it had grown

up in a larger pond.

If an animal does not receive enough food or nutrients when it is young, it may grow up to be

smaller than it would have otherwise.

Biotic & Abiotic Factors in Ecosystems

Ecosystems can be characterized by their biotic and abiotic factors. The biotic factors in an

ecosystem are things that are alive. The abiotic factors are things that are not alive.

Biotic Factors

The biotic factors in an environment are the living parts. These include plants, animals, and

other organisms that live there. For example, deer, maple trees, and mushrooms are some of

the living things that might be found in a forest.

Some ecosystems are characterized mainly by the types of plants living in them. An example

is a hardwood forest, which is characterized by the hardwood trees that grow there.

Plants and fungi are both examples of the living parts of an ecosystem.

Abiotic Factors

The abiotic factors in an environment are not alive. These include rainfall, temperature,

sunlight, water, soil, rocks, and air. For example, very low temperatures and very little

precipitation are some of the nonliving factors that are found in the tundra.

Sunlight is a nonliving part of an ecosystem.

Rainfall and temperature are important because they define many ecosystems.For example, a

tropical rainforest is defined by its high rainfall and high temperature throughout the year. A

desert is defined by its low annual rainfall of less than 25 cm.

The abiotic parts of an ecosystem can include many other factors. For example, the abiotic

parts a river ecosystem might include speed of flow, depth of the water, and the amount of

minerals in the water. The abiotic parts of a grassland area might include the nutrients in the

soil, wind, and weather patterns such as dew forming in the morning.

The nonliving parts of this savannah ecosystem determine what kinds of plants and animals

can live there.

Link Between Biotic & Abiotic Factors

Biotic and abiotic factors exist together in an ecosystem and impact each other.

Abiotic factors often determine what living things can survive in the ecosystem.For example,

animals that can survive in the Arctic have to be adapted to cold climates, while animals that

can survive in deserts need to be adapted to dry climates. Little or no plant life can survive in

the Arctic, while a wide range of plants live in rainforests.

The abiotic factors in an ecosystem also provide the things plants and animals need to

survive. These include sunlight, water, and soil for plants. For animals, suitable temperature

ranges, water, and oxygen in the air are critical for life.

Biotic factors can also impact the abiotic parts of an ecosystem. For example, plants add

oxygen to the atmosphere, worms living in the ground aerate the soil, and algae growing in

lakes can reduce the sunlight reaching the bottom of the lake.

Resource Availability & Populations

The growth of a population in an ecosystem is limited by the resources available. Populations

can only grow to a certain point before they begin to run out of resources that the organisms

need in order to survive.

Population Growth

Populations of organisms do not grow linearly. That is, graphs of their populations do not

form a straight line. Instead, populations grow exponentiallybecause the more organisms there

are, the faster the population grows.

For example, if two dogs produce six puppies, and later, those six puppies each produce six

puppies of their own, within two generations, 36 puppies will have been produced from the

original two dogs!

This model, however, shows a very small growth ratio. In reality, it is more likely that the

original two dogs had a set of six puppies every year for several years. Their puppies also

probably produced multiple sets of puppies. This means that the dog population would be

much greater than 36.

Carrying Capacity

As a growing population reaches the limits of the available resources in an environment, its

size levels off to "match" the amount of resources available. In doing so, the population has

reached its carrying capacity. When populations fall below the carrying capacity, the birth

rate tends to go up because there are more resources available. When

populations overshoot the carrying capacity, on the other hand, they generally experience a

substantial decline, or crash, before stabilizing again.

The carrying capacity of a population can be determined by analyzing graphs that track

population size over long periods of time. For example, the carrying capacity of a population

is represented by the red line in the graph below. This is the equilibrium point between small

increases and decreases in the population size.

This pattern continues with only slight changes during periods in which the environment stays

roughly the same. In cases of drastic change, the carrying capacity could change. For example,

if the major food source of a population dies out, the carrying capacity for that population will

drop. Conversely, an increase in available food can cause the carrying capacity for an

organism to increase. For instance, the Agricultural Revolution was responsible for raising the

carrying capacity for humans by increasing the resources available to support the human

population.

Limiting Factors

Limiting factors limit a population's growth. These factors can be resources that organisms

need in order to live and that are present in limited quantities.Limiting factors can be biotic or

abiotic. They include food, water, space, and shelter.

For a plant population, a limiting factor might be how much light there is, or it might be the

availability of good soil. For a hyena population, a limiting factor might be competition for

food with other predators. The number of plants or hyenas in a specific ecosystem will be

limited by the resource that runs out first. This will be the limiting factor. Different

ecosystems can have different limiting factors, even for similar populations.

The limiting factor for a population of hyenas could be many different things, including

competition with other predators.

Limiting factors are sometimes created by humans. If there is a chemical spill that kills plant

and animal life in an area, this could limit how successful the surviving populations can

be. Humans also destroy large amounts of plant and animal habitats. So space is often a

limiting factor for many wild plant and animal populations. All stable populations are subject

to at least one limiting factor.

Patterns of Population Growth

The pattern of growth for a population can change as environmental conditions cause resource

availability to change. These changes could include:

a change in the food supply

a change in the water supply

a change in temperature

crowding and competition

Competition

Since there are limited amounts of resources in an ecosystem, if one organism gets a particular

resource, another does not. This leads to competition as two organisms try to use the same

resources. Food, water, sunlight, and space are examples of resources that organisms compete

for.

Plants and animals of the same species may compete for resources such as food, water, shelter,

and space. Populations of different species will also compete with one other if their needs are

the same and they share an ecosystem.

For example, trees in a forest compete for sunlight. As one tree grows taller, the shorter trees

are shaded by it, and they receive less sunlight. The shorter trees may die as a result.

The tall tree and the shorter trees in this picture are competing for sunlight.

Population Dynamics

Populations in an ecosystem affect one another. A change in the number of one type of

organism will cause a change in the number of other types of organisms. These changes can be

studied by looking at the population dynamics of an ecosystem.

The food web above represents four populations within a savanna ecosystem.Antelopes

depend on leaves from trees as their major food source. African wild dogs and lions compete

with each other for antelopes as a food source.

The number of organisms within these populations will always be changing as some

organisms are born and other organisms die. The population size of one species will also

change if the population size of another species changes.

For example, if a drought in the ecosystem caused many of the trees to die, there would not be

enough food for all of the antelope to survive. The antelope population would decrease. If the

antelope population decreased, the number of African wild dogs and lions would also likely

decrease because they would be losing a major food source.

Another example would be if humans hunted and killed many of the African wild dogs and

lions. This would cause an increase in the antelope population because they would not have as

many predators. More antelope means they would eat more leaves from trees. This would

decrease the amount of leaves, which is a resource.

All populations within an ecosystem are related in some way. This means that a change in

even one population in an ecosystem can have drastic effects on the ecosystem as a whole.

Organism Interactions

Organisms interact with others within the same population and with organisms from

populations of different species. These interactions can improve or reduce the chance of survival

for some organisms.

Competition

Resources in any environment are limited. There is only so much access to sunlight, food,

water, shelter, and space. Therefore, plants and animals may have to compete, or struggle, to

get resources for themselves. Many animals mark their territories with scents (smells) to try to

keep other animals away.This helps make sure that the food, water, shelter, and possible mates

in the animal's territory do not get taken by another animal. If one animal trespasses on the

territory of another, a fight may start.

Animals compete for food, territory, and mates.

Trees in a forest compete for sunlight. As one tree grows taller, the shorter trees are shaded by

it, and they receive less sunlight. The shorter trees may die as a result.

Cooperation

Cooperation is a type of interaction in which organisms of the same species work

together. Many species show cooperative behavior, including horses, dolphins, lions, and

ants. Animals that exhibit cooperative behavior often live, travel, and/or hunt in herds or

groups. Living in these groups can provide protection for the animals and a higher success rate

during hunts.

Groups of organisms that live together cooperatively are usually part of ahierarchy of

leadership. Some members of the group have a higher status than other members of the

group. Dominant members determine what the group will do and subordinate members follow

their lead. This helps to eliminate aggression between group members and allows the group to

work together for the benefit of all.

Dominant females lead elephant herds.

Fish travel in schools for protection.

An example of an animal that lives in a cooperative group is the wolf. Wolves live in packs

that usually include six or seven members. There are two leaders within the group, the alpha

male and the alpha female, and these two pack members determine when the pack hunts,

moves location, or stays in an area.The leaders of the pack are usually the pack members with

the most experience in hunting and defending territory. The other pack members have roles

within this pack to help the pack work effectively.

Mutualism

Mutualism is a kind of organism interaction that is mutually beneficial to both organisms

involved. Unlike cooperation, mutualism specifically occurs between members of different

species.

Flowers and their pollinators are one of the most common examples of mutualism because

many kinds of plants depend on insects, such as moths, bees, wasps, and beetles, to perform

pollination in order to reproduce. Plants that rely on pollinators attract the pollinator by the

shape, color, or smell of their flowers. As the pollinator feeds on the nectar or pollen from the

flower, some of the pollen sticks to its legs and body. When the pollinator visits a second plant

of the same species, the pollen from the first plant is transferred to the reproductive organs of

the second plant, and pollination occurs. Both organisms receive a benefit from this

interaction. The pollinator receives access to a food source and the plant is able to reproduce

because of their relationship.

Bees are pollinators that receive nectar or pollen from flowering plants. They also aid in the

pollination of the plant, which makes the relationship mutualistic.

Predation

Predation takes place when an organism captures and consumes another organism as a food

source. The organism that hunts is called the predator and the organism that is consumed is

called the prey.

An example of predation is a bird catching, killing, and eating a frog.

In this example, the bird is the predator and the frog is the prey.

Populations of predators and prey are closely linked. There are always more prey than there

are predators in a stable ecosystem. As the population of one changes, the population of the

other will also change. For example, if a prey population decreases, predators will have less

food available, and the predator population will also decrease.

Predators are very important for ecosystem stability because they keep the population of prey

species from getting too large. Without predators, prey species would overpopulate areas and

use up all of the resources, causing the food supply of the prey to decrease.