Ecosystems and the Biosphere PDF

Summary

This document is a chapter on ecosystems and the biosphere, describing the biotic and abiotic components and how they interact. It details energy flow and ecological concepts.

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CHAPTER 20
Ecosystems and the Biosphere

FIGURE 20.1 The (a) Karner blue butterfly and (b) wild lupine live in oak-pine barren habitats in North America. (credit
a: modification of work by John & Karen Hollingsworth, USFWS)

CHAPTER OUTLINE
20.1 Waterford's Energy Flow through Ecosystems
20.2 Biogeochemical Cycles
20.3 Terrestrial Biomes
20.4 Aquatic and Marine Biomes

INTRODUCTION Ecosystem ecology is an extension of organismal, population, and community
ecology. The ecosystem comprises all the biotic components (living things) and abiotic
components (non-living things) in a particular geographic area. Some of the abiotic components
include air, water, soil, and climate. Ecosystem biologists study how nutrients and energy are
stored and moved among organisms and the surrounding atmosphere, soil, and water.

Wild lupine and Karner blue butterflies live in an oak-pine barren habitat in portions of Indiana,
Michigan, Minnesota, Wisconsin, and New York (Figure 20.1). This habitat is characterized by
natural disturbance in the form of fire and nutrient-poor soils that are low in nitrogen—important
factors in the distribution of the plants that live in this habitat. Researchers interested in
ecosystem ecology study the importance of limited resources in this ecosystem and the
526 20 Ecosystems and the Biosphere

movement of resources (such as nutrients) through the biotic and abiotic portions of the
ecosystem. Researchers also examine how organisms have adapted to their ecosystem.

20.1 Waterford's Energy Flow through Ecosystems
LEARNING OBJECTIVES
By the end of this section, you will be able to:
Describe the basic types of ecosystems on Earth
Differentiate between food chains and food webs and recognize the importance of each
Describe how organisms acquire energy in a food web and in associated food chains
Explain how the efficiency of energy transfers between trophic levels affects ecosystems

An ecosystem is a community of living organisms and their abiotic (non-living) environment.
Ecosystems can be small, such as the tide pools found near the rocky shores of many oceans, or
large, such as those found in the tropical rainforest of the Amazon in Brazil (Figure 20.2).

FIGURE 20.2 A (a) tidal pool ecosystem in Matinicus Island, Maine, is a small ecosystem, while the (b) Amazon
rainforest in Brazil is a large ecosystem. (credit a: modification of work by Jim Kuhn; credit b: modification of work by
Ivan Mlinaric)

There are three broad categories of ecosystems based on their general environment: freshwater,
marine, and terrestrial. Within these three categories are individual ecosystem types based on the
environmental habitat and organisms present.

Ecology of Ecosystems
Life in an ecosystem often involves competition for limited resources, which occurs both within a
single species and between different species. Organisms compete for food, water, sunlight, space,
and mineral nutrients. These resources provide the energy for metabolic processes and the matter
to make up organisms’ physical structures. Other critical factors influencing community dynamics
are the components of its physical environment: a habitat’s climate (seasons, sunlight, and
rainfall), elevation, and geology. These can all be important environmental variables that
determine which organisms can exist within a particular area.

Freshwater ecosystems are the least common, occurring on only 1.8 percent of Earth's surface.
These systems comprise lakes, rivers, streams, and springs; they are quite diverse, and support a
variety of animals, plants, fungi, protists and prokaryotes.

Marine ecosystems are the most common, comprising 75 percent of Earth's surface and consisting
of three basic types: shallow ocean, deep ocean water, and deep ocean bottom. Shallow ocean
ecosystems include extremely biodiverse coral reef ecosystems, yet the deep ocean water is
known for large numbers of plankton and krill (small crustaceans) that support it. These two
environments are especially important to aerobic respirators worldwide, as the phytoplankton
perform 40 percent of all photosynthesis on Earth. Although not as diverse as the other two, deep

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 20.1 Waterford's Energy Flow through Ecosystems 527

ocean bottom ecosystems contain a wide variety of marine organisms. Such ecosystems exist even at depths where
light is unable to penetrate through the water.

Terrestrial ecosystems, also known for their diversity, are grouped into large categories called biomes. A biome is a
large-scale community of organisms, primarily defined on land by the dominant plant types that exist in geographic
regions of the planet with similar climatic conditions. Examples of biomes include tropical rainforests, savannas,
deserts, grasslands, temperate forests, and tundras. Grouping these ecosystems into just a few biome categories
obscures the great diversity of the individual ecosystems within them. For example, the saguaro cacti (Carnegiea
gigantean) and other plant life in the Sonoran Desert, in the United States, are relatively diverse compared with the
desolate rocky desert of Boa Vista, an island off the coast of Western Africa (Figure 20.3).

FIGURE 20.3 Desert ecosystems, like all ecosystems, can vary greatly. The desert in (a) Saguaro National Park, Arizona, has abundant plant
life, while the rocky desert of (b) Boa Vista island, Cape Verde, Africa, is devoid of plant life. (credit a: modification of work by Jay Galvin;
credit b: modification of work by Ingo Wölbern)

Ecosystems and Disturbance
Ecosystems are complex with many interacting parts. They are routinely exposed to various disturbances: changes
in the environment that affect their compositions, such as yearly variations in rainfall and temperature. Many
disturbances are a result of natural processes. For example, when lightning causes a forest fire and destroys part of
a forest ecosystem, the ground is eventually populated with grasses, followed by bushes and shrubs, and later
mature trees: thus, the forest is restored to its former state. This process is so universal that ecologists have given it
a name—succession. The impact of environmental disturbances caused by human activities is now as significant as
the changes wrought by natural processes. Human agricultural practices, air pollution, acid rain, global
deforestation, overfishing, oil spills, and illegal dumping on land and into the ocean all have impacts on ecosystems.

Equilibrium is a dynamic state of an ecosystem in which, despite changes in species numbers and occurrence,
biodiversity remains somewhat constant. In ecology, two parameters are used to measure changes in ecosystems:
resistance and resilience. The ability of an ecosystem to remain at equilibrium in spite of disturbances is called
resistance. The speed at which an ecosystem recovers equilibrium after being disturbed is called resilience.
Ecosystem resistance and resilience are especially important when considering human impact. The nature of an
ecosystem may change to such a degree that it can lose its resilience entirely. This process can lead to the complete
destruction or irreversible altering of the ecosystem.

Food Chains and Food Webs
A food chain is a linear sequence of organisms through which nutrients and energy pass as one organism eats
another; the levels in the food chain are producers, primary consumers, higher-level consumers, and finally
decomposers. These levels are used to describe ecosystem structure and dynamics. There is a single path through a
food chain. Each organism in a food chain occupies a specific trophic level (energy level), its position in the food
chain or food web.

In many ecosystems, the base, or foundation, of the food chain consists of photosynthetic organisms (plants or
phytoplankton), which are called producers. The organisms that consume the producers are herbivores: the
primary consumers. Secondary consumers are usually carnivores that eat the primary consumers. Tertiary
consumers are carnivores that eat other carnivores. Higher-level consumers feed on the next lower trophic levels,
528 20 Ecosystems and the Biosphere

and so on, up to the organisms at the top of the food chain: the apex consumers. In the Lake Ontario food chain,
shown in Figure 20.4, the Chinook salmon is the apex consumer at the top of this food chain.

FIGURE 20.4 These are the trophic levels of a food chain in Lake Ontario at the United States–Canada border. Energy and nutrients flow
from photosynthetic green algae at the base to the top of the food chain: the Chinook salmon. (credit: modification of work by National
Oceanic and Atmospheric Administration/NOAA)

One major factor that limits the number of steps in a food chain is energy. Energy is lost at each trophic level and
between trophic levels as heat and in the transfer to decomposers (Figure 20.5). Thus, after a limited number of
trophic energy transfers, the amount of energy remaining in the food chain may not be great enough to support
viable populations at yet a higher trophic level.

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 20.1 Waterford's Energy Flow through Ecosystems 529

FIGURE 20.5 The relative energy in trophic levels in a Silver Springs, Florida, ecosystem is shown. Each trophic level has less energy
available, and usually, but not always, supports a smaller mass of organisms at the next level.

There is a one problem when using food chains to describe most ecosystems. Even when all organisms are grouped
into appropriate trophic levels, some of these organisms can feed on more than one trophic level; likewise, some of
these organisms can also be fed on from multiple trophic levels. In addition, species feed on and are eaten by more
than one species. In other words, the linear model of ecosystems, the food chain, is a hypothetical, overly simplistic
representation of ecosystem structure. A holistic model—which includes all the interactions between different
species and their complex interconnected relationships with each other and with the environment—is a more
accurate and descriptive model for ecosystems. A food web is a concept that accounts for the multiple trophic
(feeding) interactions between each species and the many species it may feed on, or that feed on it. In a food web,
the several trophic connections between each species and the other species that interact with it may cross multiple
trophic levels. The matter and energy movements of virtually all ecosystems are more accurately described by food
webs (Figure 20.6).
530 20 Ecosystems and the Biosphere

FIGURE 20.6 This food web shows the interactions between organisms across trophic levels. Arrows point from an organism that is
consumed to the organism that consumes it. All the producers and consumers eventually become nourishment for the decomposers (fungi,
mold, earthworms, and bacteria in the soil). (credit "fox": modification of work by Kevin Bacher, NPS; credit "owl": modification of work by
John and Karen Hollingsworth, USFWS; credit "snake": modification of work by Steve Jurvetson; credit "robin": modification of work by Alan
Vernon; credit "frog": modification of work by Alessandro Catenazzi; credit "spider": modification of work by "Sanba38"/Wikimedia
Commons; credit "centipede": modification of work by “Bauerph”/Wikimedia Commons; credit "squirrel": modification of work by Dawn
Huczek; credit "mouse": modification of work by NIGMS, NIH; credit "sparrow": modification of work by David Friel; credit "beetle":
modification of work by Scott Bauer, USDA Agricultural Research Service; credit "mushrooms": modification of work by Chris Wee; credit
"mold": modification of work by Dr. Lucille Georg, CDC; credit "earthworm": modification of work by Rob Hille; credit "bacteria":
modification of work by Don Stalons, CDC)

LINK TO LEARNING
Head to this online interactive simulator (http://openstax.org/l/food_web) to investigate food web function. In the
Interactive Labs box, under underline
Food Web,end
click
underline
Step 1. Read the instructions first, and then click Step 2 for additional
instructions. When you are ready to create a simulation, in the upper-right corner of the Interactive Labs box, click
OPEN SIMULATOR.

Two general types of food webs are often shown interacting within a single ecosystem. A grazing food web has
plants or other photosynthetic organisms at its base, followed by herbivores and various carnivores. A detrital food
web consists of a base of organisms that feed on decaying organic matter (dead organisms), including decomposers
(which break down dead and decaying organisms) and detritivores (which consume organic detritus). These
organisms are usually bacteria, fungi, and invertebrate animals that recycle organic material back into the biotic part
of the ecosystem as they themselves are consumed by other organisms. As ecosystems require a method to recycle
material from dead organisms, grazing food webs have an associated detrital food web. For example, in a meadow
ecosystem, plants may support a grazing food web of different organisms, primary and other levels of consumers,
while at the same time supporting a detrital food web of bacteria and fungi feeding off dead plants and animals.
Simultaneously, a detrital food web can contribute energy to a grazing food web, as when a robin eats an earthworm.

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 20.1 Waterford's Energy Flow through Ecosystems 531

How Organisms Acquire Energy in a Food Web
All living things require energy in one form or another. Energy is used by most complex metabolic pathways (usually
in the form of ATP), especially those responsible for building large molecules from smaller compounds. Living
organisms would not be able to assemble macromolecules (proteins, lipids, nucleic acids, and complex
carbohydrates) from their monomers without a constant energy input.

Food-web diagrams illustrate how energy flows directionally through ecosystems. They can also indicate how
efficiently organisms acquire energy, use it, and how much remains for use by other organisms of the food web.
Energy is acquired by living things in two ways: autotrophs harness light or chemical energy and heterotrophs
acquire energy through the consumption and digestion of other living or previously living organisms.

Photosynthetic and chemosynthetic organisms are autotrophs, which are organisms capable of synthesizing their
own food (more specifically, capable of using inorganic carbon as a carbon source). Photosynthetic autotrophs
(photoautotrophs) use sunlight as an energy source, and chemosynthetic autotrophs (chemoautotrophs) use
inorganic molecules as an energy source. Autotrophs are critical for most ecosystems: they are the producer trophic
level. Without these organisms, energy would not be available to other living organisms, and life itself would not be
possible.

Photoautotrophs, such as plants, algae, and photosynthetic bacteria, are the energy source for a majority of the
world’s ecosystems. These ecosystems are often described by grazing and detrital food webs. Photoautotrophs
harness the Sun’s solar energy by converting it to chemical energy in the form of ATP (and NADP). The energy stored
in ATP is used to synthesize complex organic molecules, such as glucose. The rate at which photosynthetic
producers incorporate energy from the Sun is called gross primary productivity. However, not all of the energy
incorporated by producers is available to the other organisms in the food web because producers must also grow
and reproduce, which consumes energy. Net primary productivity is the energy that remains in the producers after
accounting for these organisms’ respiration and heat loss. The net productivity is then available to the primary
consumers at the next trophic level.

Chemoautotrophs are primarily bacteria and archaea that are found in rare ecosystems where sunlight is not
available, such as those associated with dark caves or hydrothermal vents at the bottom of the ocean (Figure 20.7).
Many chemoautotrophs in hydrothermal vents use hydrogen sulfide (H2S), which is released from the vents as a
source of chemical energy; this allows them to synthesize complex organic molecules, such as glucose, for their own
energy and, in turn, supplies energy to the rest of the ecosystem.

FIGURE 20.7 Swimming shrimp, a few squat lobsters, and hundreds of vent mussels are seen at a hydrothermal vent at the bottom of the
ocean. As no sunlight penetrates to this depth, the ecosystem is supported by chemoautotrophic bacteria and organic material that sinks
from the ocean’s surface. This picture was taken in 2006 at the submerged NW Eifuku volcano off the coast of Japan by the National
Oceanic and Atmospheric Administration (NOAA). The summit of this highly active volcano lies 1535 m below the surface.
532 20 Ecosystems and the Biosphere

Consequences of Food Webs: Biological Magnification
One of the most important consequences of ecosystem dynamics in terms of human impact is biomagnification.
Biomagnification is the increasing concentration of persistent, toxic substances in organisms at each successive
trophic level. These are substances that are fat soluble, not water soluble, and are stored in the fat reserves of each
organism. Many substances have been shown to biomagnify, including classical studies with the pesticide
dichlorodiphenyltrichloroethane (DDT), which were described in the 1960s bestseller, Silent Spring by Rachel
Carson. DDT was a commonly used pesticide before its dangers to apex consumers, such as the bald eagle, became
known. In aquatic ecosystems, organisms from each trophic level consumed many organisms in the lower level,
which caused DDT to increase in birds (apex consumers) that ate fish. Thus, the birds accumulated sufficient
amounts of DDT to cause fragility in their eggshells. This effect increased egg breakage during nesting and was
shown to have devastating effects on these bird populations. The use of DDT was banned in the United States in the
1970s.

Other substances that biomagnify are polychlorinated biphenyls (PCB), which were used as coolant liquids in the
United States until their use was banned in 1979, and heavy metals, such as mercury, lead, and cadmium. These
substances are best studied in aquatic ecosystems, where predatory fish species accumulate very high
concentrations of toxic substances that are at quite low concentrations in the environment and in producers. As
illustrated in a study performed by the NOAA in the Saginaw Bay of Lake Huron of the North American Great Lakes
(Figure 20.8), PCB concentrations increased from the producers of the ecosystem (phytoplankton) through the
different trophic levels of fish species. The apex consumer, the walleye, has more than four times the amount of
PCBs compared to phytoplankton. Also, based on results from other studies, birds that eat these fish may have PCB
levels at least one order of magnitude higher than those found in the lake fish.

FIGURE 20.8 This chart shows the PCB concentrations found at the various trophic levels in the Saginaw Bay ecosystem of Lake Huron.
Notice that the fish in the higher trophic levels accumulate more PCBs than those in lower trophic levels. (credit: Patricia Van Hoof, NOAA)

Other concerns have been raised by the biomagnification of heavy metals, such as mercury and cadmium, in certain
types of seafood. The United States Environmental Protection Agency recommends that pregnant people and young
children should not consume any swordfish, shark, king mackerel, or tilefish because of their high mercury content.
These individuals are advised to eat fish low in mercury: salmon, shrimp, pollock, and catfish. Biomagnification is a
good example of how ecosystem dynamics can affect our everyday lives, even influencing the food we eat.

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 20.2 Biogeochemical Cycles 533

20.2 Biogeochemical Cycles
LEARNING OBJECTIVES
By the end of this section, you will be able to:
Discuss the biogeochemical cycles of water, carbon, nitrogen, phosphorus, and sulfur
Explain how human activities have impacted these cycles and the resulting potential consequences for
Earth

Energy flows directionally through ecosystems, entering as sunlight (or inorganic molecules for chemoautotrophs)
and leaving as heat during the transfers between trophic levels. Rather than flowing through an ecosystem, the
matter that makes up living organisms is conserved and recycled. The six most common elements associated with
organic molecules—carbon, nitrogen, hydrogen, oxygen, phosphorus, and sulfur—take a variety of chemical forms
and may exist for long periods in the atmosphere, on land, in water, or beneath Earth’s surface. Geologic processes,
such as weathering, erosion, water drainage, and the subduction of the continental plates, all play a role in the
cycling of elements on Earth. Because geology and chemistry have major roles in the study of this process, the
recycling of inorganic matter between living organisms and their nonliving environment is called a biogeochemical
cycle.

Water, which contains hydrogen and oxygen, is essential to all living processes. The hydrosphere is the area of Earth
where water movement and storage occurs: as liquid water on the surface (rivers, lakes, oceans) and beneath the
surface (groundwater) or ice, (polar ice caps and glaciers), and as water vapor in the atmosphere. Carbon is found in
all organic macromolecules and is an important constituent of fossil fuels. Nitrogen is a major component of our
nucleic acids and proteins and is critical to human agriculture. Phosphorus, a major component of nucleic acids, is
one of the main ingredients (along with nitrogen) in artificial fertilizers used in agriculture, which has environmental
impacts on our surface water. Sulfur, critical to the three-dimensional folding of proteins (as in disulfide binding), is
released into the atmosphere by the burning of fossil fuels.

The cycling of these elements is interconnected. For example, the movement of water is critical for the leaching of
nitrogen and phosphate into rivers, lakes, and oceans. The ocean is also a major reservoir for carbon. Thus, mineral
nutrients are cycled, either rapidly or slowly, through the entire biosphere between the biotic and abiotic world and
from one living organism to another.

LINK TO LEARNING
Head to this website (http://openstax.org/l/biogeochemical) to learn more about biogeochemical cycles.

The Water Cycle
Water is essential for all living processes. The human body is more than one-half water and human cells are more
than 70 percent water. Thus, most land animals need a supply of fresh water to survive. Of the stores of water on
Earth, 97.5 percent is salt water (Figure 20.9). Of the remaining water, 99 percent is locked as underground water or
ice. Thus, less than one percent of fresh water is present in lakes and rivers. Many living things are dependent on
this small amount of surface fresh water supply, a lack of which can have important effects on ecosystem dynamics.
Humans, of course, have developed technologies to increase water availability, such as digging wells to harvest
groundwater, storing rainwater, and using desalination to obtain drinkable water from the ocean. Although this
pursuit of drinkable water has been ongoing throughout human history, the supply of fresh water continues to be a
major issue in modern times.
534 20 Ecosystems and the Biosphere

FIGURE 20.9 Only 2.5 percent of water on Earth is fresh water, and less than 1 percent of fresh water is easily accessible to living things.

The various processes that occur during the cycling of water are illustrated in Figure 20.10. The processes include
the following:

evaporation and sublimation
condensation and precipitation
subsurface water flow
surface runoff and snowmelt
streamflow

The water cycle is driven by the Sun’s energy as it warms the oceans and other surface waters. This leads to
evaporation (water to water vapor) of liquid surface water and sublimation (ice to water vapor) of frozen water, thus
moving large amounts of water into the atmosphere as water vapor. Over time, this water vapor condenses into
clouds as liquid or frozen droplets and eventually leads to precipitation (rain or snow), which returns water to Earth’s
surface. Rain reaching Earth’s surface may evaporate again, flow over the surface, or percolate into the ground. Most
easily observed is surface runoff: the flow of fresh water either from rain or melting ice. Runoff can make its way
through streams and lakes to the oceans or flow directly to the oceans themselves.

In most natural terrestrial environments rain encounters vegetation before it reaches the soil surface. A significant
percentage of water evaporates immediately from the surfaces of plants. What is left reaches the soil and begins to
move down. Surface runoff will occur only if the soil becomes saturated with water in a heavy rainfall. Most water in
the soil will be taken up by plant roots. The plant will use some of this water for its own metabolism, and some of
that will find its way into animals that eat the plants, but much of it will be lost back to the atmosphere through a
process known as evapotranspiration. Water enters the vascular system of the plant through the roots and
evaporates, or transpires, through the stomata of the leaves. Water in the soil that is not taken up by a plant and that
does not evaporate is able to percolate into the subsoil and bedrock. Here it forms groundwater.

Groundwater is a significant reservoir of fresh water. It exists in the pores between particles in sand and gravel, or in
the fissures in rocks. Shallow groundwater flows slowly through these pores and fissures and eventually finds its
way to a stream or lake where it becomes a part of the surface water again. Streams do not flow because they are
replenished from rainwater directly; they flow because there is a constant inflow from groundwater below. Some
groundwater is found very deep in the bedrock and can persist there for millennia. Most groundwater reservoirs, or
aquifers, are the source of drinking or irrigation water drawn up through wells. In many cases these aquifers are
being depleted faster than they are being replenished by water percolating down from above.

Rain and surface runoff are major ways in which minerals, including carbon, nitrogen, phosphorus, and sulfur, are
cycled from land to water. The environmental effects of runoff will be discussed later as these cycles are described.

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 20.2 Biogeochemical Cycles 535

FIGURE 20.10 Water from the land and oceans enters the atmosphere by evaporation or sublimation, where it condenses into clouds and
falls as rain or snow. Precipitated water may enter freshwater bodies or infiltrate the soil. The cycle is complete when surface or
groundwater reenters the ocean. (credit: modification of work by John M. Evans and Howard Perlman, USGS)

The Carbon Cycle
Carbon is the fourth most abundant element in living organisms. Carbon is present in all organic molecules, and its
role in the structure of macromolecules is of primary importance to living organisms. Carbon compounds contain
energy, and many of these compounds from plants and algae have remained stored as fossilized carbon, which
humans use as fuel. Since the 1800s, the use of fossil fuels has accelerated. As global demand for Earth’s limited
fossil fuel supplies has risen since the beginning of the Industrial Revolution, the amount of carbon dioxide in our
atmosphere has increased as the fuels are burned. This increase in carbon dioxide has been associated with climate
change and is a major environmental concern worldwide.

The carbon cycle is most easily studied as two interconnected subcycles: one dealing with rapid carbon exchange
among living organisms and the other dealing with the long-term cycling of carbon through geologic processes. The
entire carbon cycle is shown in Figure 20.11.
536 20 Ecosystems and the Biosphere

FIGURE 20.11 Carbon dioxide gas exists in the atmosphere and is dissolved in water. Photosynthesis converts carbon dioxide gas to
organic carbon, and respiration cycles the organic carbon back into carbon dioxide gas. Long-term storage of organic carbon occurs when
matter from living organisms is buried deep underground and becomes fossilized. Volcanic activity and, more recently, human emissions
bring this stored carbon back into the carbon cycle. (credit: modification of work by John M. Evans and Howard Perlman, USGS)

The Biological Carbon Cycle
Living organisms are connected in many ways, even between ecosystems. A good example of this connection is the
exchange of carbon between heterotrophs and autotrophs within and between ecosystems by way of atmospheric
carbon dioxide. Carbon dioxide is the basic building block that autotrophs use to build multi-carbon, high-energy
compounds, such as glucose. The energy harnessed from the Sun is used by these organisms to form the covalent
bonds that link carbon atoms together. These chemical bonds store this energy for later use in the process of
respiration. Most terrestrial autotrophs obtain their carbon dioxide directly from the atmosphere, while marine
autotrophs acquire it in the dissolved form (carbonic acid, HCO3–). However the carbon dioxide is acquired, a
byproduct of fixing carbon in organic compounds is oxygen. Photosynthetic organisms are responsible for
maintaining approximately 21 percent of the oxygen content of the atmosphere that we observe today.

The partners in biological carbon exchange are the heterotrophs (especially the primary consumers, largely
herbivores). Heterotrophs acquire the high-energy carbon compounds from the autotrophs by consuming them and
breaking them down by respiration to obtain cellular energy, such as ATP. The most efficient type of respiration,
aerobic respiration, requires oxygen obtained from the atmosphere or dissolved in water. Thus, there is a constant
exchange of oxygen and carbon dioxide between the autotrophs (which need the carbon) and the heterotrophs
(which need the oxygen). Autotrophs also respire and consume the organic molecules they form: using oxygen and
releasing carbon dioxide. They release more oxygen gas as a waste product of photosynthesis than they use for their
own respiration; therefore, there is excess available for the respiration of other aerobic organisms. Gas exchange
through the atmosphere and water is one way that the carbon cycle connects all living organisms on Earth.

The Biogeochemical Carbon Cycle
The movement of carbon through land, water, and air is complex, and, in many cases, it occurs much more slowly
geologically than the movement between living organisms. Carbon is stored for long periods in what are known as
carbon reservoirs, which include the atmosphere, bodies of liquid water (mostly oceans), ocean sediment, soil,
rocks (including fossil fuels), and Earth’s interior.

As stated, the atmosphere is a major reservoir of carbon in the form of carbon dioxide that is essential to the

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 20.2 Biogeochemical Cycles 537

process of photosynthesis. The level of carbon dioxide in the atmosphere is greatly influenced by the reservoir of
carbon in the oceans. The exchange of carbon between the atmosphere and water reservoirs influences how much
carbon is found in each, and each one affects the other reciprocally. Carbon dioxide (CO2) from the atmosphere
dissolves in water and, unlike oxygen and nitrogen gas, reacts with water molecules to form ionic compounds. Some
of these ions combine with calcium ions in the seawater to form calcium carbonate (CaCO3), a major component of
the shells of marine organisms. These organisms eventually form sediments on the ocean floor. Over geologic time,
the calcium carbonate forms limestone, which comprises the largest carbon reservoir on Earth.

On land, carbon is stored in soil as organic carbon as a result of the decomposition of living organisms or from
weathering of terrestrial rock and minerals. Deeper under the ground, at land and at sea, are fossil fuels, the
anaerobically decomposed remains of plants that take millions of years to form. Fossil fuels are considered a non-
renewable resource because their use far exceeds their rate of formation. A non-renewable resource is either
regenerated very slowly or not at all. Another way for carbon to enter the atmosphere is from land (including land
beneath the surface of the ocean) by the eruption of volcanoes and other geothermal systems. Carbon sediments
from the ocean floor are taken deep within Earth by the process of subduction: the movement of one tectonic plate
beneath another. Carbon is released as carbon dioxide when a volcano erupts or from volcanic hydrothermal vents.

Carbon dioxide is also added to the atmosphere by the animal husbandry practices of humans. The large number of
land animals raised to feed Earth’s growing human population results in increased carbon-dioxide levels in the
atmosphere caused by their respiration. This is another example of how human activity indirectly affects
biogeochemical cycles in a significant way. Although much of the debate about the future effects of increasing
atmospheric carbon on climate change focuses on fossils fuels, scientists take natural processes, such as
volcanoes, plant growth, soil carbon levels, and respiration, into account as they model and predict the future
impact of this increase.

The Nitrogen Cycle
Getting nitrogen into the living world is difficult. Plants and phytoplankton are not equipped to incorporate nitrogen
from the atmosphere (which exists as tightly bonded, triple covalent N2) even though this molecule comprises
approximately 78 percent of the atmosphere. Nitrogen enters the living world via free-living and symbiotic bacteria,
which incorporate nitrogen into their macromolecules through nitrogen fixation (conversion of N2). Cyanobacteria
live in most aquatic ecosystems where sunlight is present; they play a key role in nitrogen fixation. Cyanobacteria
are able to use inorganic sources of nitrogen to “fix” nitrogen. Rhizobium bacteria live symbiotically in the root
nodules of legumes (such as peas, beans, and peanuts) and provide them with the organic nitrogen they need. Free-
living bacteria, such as Azotobacter, are also important nitrogen fixers.

Organic nitrogen is especially important to the study of ecosystem dynamics since many ecosystem processes, such
as primary production and decomposition, are limited by the available supply of nitrogen. As shown in Figure 20.12,
the nitrogen that enters living systems by nitrogen fixation is eventually converted from organic nitrogen back into
nitrogen gas by bacteria. This process occurs in three steps in terrestrial systems: ammonification, nitrification, and
denitrification. First, the ammonification process converts nitrogenous waste from living animals or from the
remains of dead animals into ammonium (NH4+ ) by certain bacteria and fungi. Second, this ammonium is then
converted to nitrites (NO2−) by nitrifying bacteria, such as Nitrosomonas, through nitrification. Subsequently, nitrites
are converted to nitrates (NO3−) by similar organisms. Lastly, the process of denitrification occurs, whereby bacteria,
such as Pseudomonas and Clostridium, convert the nitrates into nitrogen gas, thus allowing it to re-enter the
atmosphere.
538 20 Ecosystems and the Biosphere

VISUAL CONNECTION

FIGURE 20.12 Nitrogen enters the living world from the atmosphere through nitrogen-fixing bacteria. This nitrogen and nitrogenous waste
from animals is then processed back into gaseous nitrogen by soil bacteria, which also supply terrestrial food webs with the organic
nitrogen they need. (credit: modification of work by John M. Evans and Howard Perlman, USGS)

Which of the following statements about the nitrogen cycle is false?

a. Ammonification converts organic nitrogenous matter from living organisms into ammonium (NH4+).
b. Denitrification by bacteria converts nitrates (NO3−)to nitrogen gas (N2).
c. Nitrification by bacteria converts nitrates (NO3−)to nitrites (NO2−)
d. Nitrogen fixing bacteria convert nitrogen gas (N2) into organic compounds.

Human activity can release nitrogen into the environment by two primary means: the combustion of fossil fuels,
which releases different nitrogen oxides, and by the use of artificial fertilizers (which contain nitrogen and
phosphorus compounds) in agriculture, which are then washed into lakes, streams, and rivers by surface runoff.
Atmospheric nitrogen (other than N2) is associated with several effects on Earth’s ecosystems including the
production of acid rain (as nitric acid, HNO3) and greenhouse gas effects (as nitrous oxide, N2O), potentially causing
climate change. A major effect from fertilizer runoff is saltwater and freshwater eutrophication, a process whereby
nutrient runoff causes the overgrowth of algae and a number of consequential problems.

A similar process occurs in the marine nitrogen cycle, where the ammonification, nitrification, and denitrification
processes are performed by marine bacteria and archaea. Some of this nitrogen falls to the ocean floor as sediment,
which can then be moved to land in geologic time by uplift of Earth’s surface, and thereby incorporated into
terrestrial rock. Although the movement of nitrogen from rock directly into living systems has been traditionally seen
as insignificant compared with nitrogen fixed from the atmosphere, a recent study showed that this process may
1
indeed be significant and should be included in any study of the global nitrogen cycle.

The Phosphorus Cycle
Phosphorus is an essential nutrient for living processes; it is a major component of nucleic acids and phospholipids,

1 Scott L. Morford, Benjamin Z. Houlton, and Randy A. Dahlgren, “Increased Forest Ecosystem Carbon and Nitrogen Storage from Nitrogen
Rich Bedrock,” Nature 477, no. 7362 (2011): 78–81.

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 20.2 Biogeochemical Cycles 539

and, as calcium phosphate, makes up the supportive components of our bones. Phosphorus is often the limiting
nutrient (necessary for growth) in aquatic, particularly freshwater, ecosystems.

Phosphorus occurs in nature as the phosphate ion (PO43-). In addition to phosphate runoff as a result of human
activity, natural surface runoff occurs when it is leached from phosphate-containing rock by weathering, thus
sending phosphates into rivers, lakes, and the ocean. This rock has its origins in the ocean. Phosphate-containing
ocean sediments form primarily from the bodies of ocean organisms and from their excretions. However, volcanic
ash, aerosols, and mineral dust may also be significant phosphate sources. This sediment then is moved to land
over geologic time by the uplifting of Earth’s surface. (Figure 20.13)

Phosphorus is also reciprocally exchanged between phosphate dissolved in the ocean and marine organisms. The
movement of phosphate from the ocean to the land and through the soil is extremely slow, with the average
phosphate ion having an oceanic residence time between 20,000 and 100,000 years.

FIGURE 20.13 In nature, phosphorus exists as the phosphate ion (PO43-). Weathering of rocks and volcanic activity releases phosphate
into the soil, water, and air, where it becomes available to terrestrial food webs. Phosphate enters the oceans in surface runoff,
groundwater flow, and river flow. Phosphate dissolved in ocean water cycles into marine food webs. Some phosphate from the marine food
webs falls to the ocean floor, where it forms sediment. (credit: modification of work by John M. Evans and Howard Perlman, USGS)

Excess phosphorus and nitrogen that enter these ecosystems from fertilizer runoff and from sewage cause
excessive growth of algae. The subsequent death and decay of these organisms depletes dissolved oxygen, which
leads to the death of aquatic organisms, such as shellfish and finfish. This process is responsible for dead zones in
lakes and at the mouths of many major rivers and for massive fish kills, which often occur during the summer
months (see Figure 20.14).
540 20 Ecosystems and the Biosphere

FIGURE 20.14 Dead zones occur when phosphorus and nitrogen from fertilizers cause excessive growth of microorganisms, which depletes
oxygen and kills fauna. Worldwide, large dead zones are found in areas of high population density. (credit: Robert Simmon, Jesse Allen,
NASA Earth Observatory)

A dead zone is an area in lakes and oceans near the mouths of rivers where large areas are periodically depleted of
their normal flora and fauna; these zones can be caused by eutrophication, oil spills, dumping toxic chemicals, and
other human activities. The number of dead zones has increased for several years, and more than 400 of these
zones were present as of 2008. One of the worst dead zones is off the coast of the United States in the Gulf of
Mexico: fertilizer runoff from the Mississippi River basin created a dead zone of over 8,463 square miles. Phosphate
and nitrate runoff from fertilizers also negatively affect several lake and bay ecosystems including the Chesapeake
Bay in the eastern United States.

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 20.2 Biogeochemical Cycles 541

CAREER CONNECTION

Chesapeake Bay

FIGURE 20.15 This (a) satellite image shows the Chesapeake Bay, an ecosystem affected by phosphate and nitrate runoff. A (b) member of
the Army Corps of Engineers holds a clump of oysters being used as a part of the oyster restoration effort in the bay. (credit a: modification
of work by NASA/MODIS; credit b: modification of work by U.S. Army)

The Chesapeake Bay (Figure 20.15a) is one of the most scenic areas on Earth; it is now in distress and is recognized
as a case study of a declining ecosystem. In the 1970s, the Chesapeake Bay was one of the first aquatic ecosystems
to have identified dead zones, which continue to kill many fish and bottom-dwelling species such as clams, oysters,
and worms. Several species have declined in the Chesapeake Bay because surface water runoff contains excess
nutrients from artificial fertilizer use on land. The source of the fertilizers (with high nitrogen and phosphate content)
is not limited to agricultural practices. There are many nearby urban areas and more than 150 rivers and streams
empty into the bay that are carrying fertilizer runoff from lawns and gardens. Thus, the decline of the Chesapeake
Bay is a complex issue and requires the cooperation of industry, agriculture, and individual homeowners.

Of particular interest to conservationists is the oyster population (Figure 20.15b); it is estimated that more than
200,000 acres of oyster reefs existed in the bay in the 1700s, but that number has now declined to only 36,000
acres. Oyster harvesting was once a major industry for Chesapeake Bay, but it declined 88 percent between 1982
and 2007. This decline was caused not only by fertilizer runoff and dead zones, but also because of overharvesting.
Oysters require a certain minimum population density because they must be in close proximity to reproduce.
Human activity has altered the oyster population and locations, thus greatly disrupting the ecosystem.

The restoration of the oyster population in the Chesapeake Bay has been ongoing for several years with mixed
success. Not only do many people find oysters good to eat, but the oysters also clean up the bay. They are filter
feeders, and as they eat, they clean the water around them. Filter feeders eat by pumping a continuous stream of
water over finely divided appendages (gills in the case of oysters) and capturing prokaryotes, plankton, and fine
organic particles in their mucus. In the 1700s, it was estimated that it took only a few days for the oyster population
to filter the entire volume of the bay. Today, with the changed water conditions, it is estimated that the present
population would take nearly a year to do the same job.

Restoration efforts have been ongoing for several years by non-profit organizations such as the Chesapeake Bay
Foundation. The restoration goal is to find a way to increase population density so the oysters can reproduce more
efficiently. Many disease-resistant varieties (developed at the Virginia Institute of Marine Science for the College of