Chapter 52 Population
Ecology
Lecture Outline
Overview: Earth’s
Fluctuating Populations
·
To
understand human population growth, we must consider the general principles of
population ecology.
·
Population ecology is the study of
populations in relation to the environment, including environmental influences
on population density and distribution, age structure, and population size.
Concept 52.1 Dynamic biological
processes influence population density, dispersion, and demography
·
A
population is a group of individuals
of a single species that live in the same general area.
·
Members
of a population rely on the same resources, are influenced by similar
environmental factors, and have a high likelihood of interacting with and
breeding with one another.
·
Populations
can evolve through natural selection acting on heritable variations among
individuals and changing the frequencies of various traits over time.
Two important characteristics of any
population are density and the spacing of individuals.
·
Every
population has a specific size and specific geographical boundaries.
°
The
density of a population is measured
as the number of individuals per unit area or volume.
°
The
dispersion of a population is the
pattern of spacing among individuals within the geographic boundaries.
·
Measuring
density of populations is a difficult task.
°
We
can count individuals, but we usually estimate population numbers.
°
It
is almost always impractical to count all individuals in a population.
°
Instead,
ecologists use a variety of sampling techniques to estimate densities and total
population sizes.
§
For
example, they might count the number of individuals in a series of randomly
located plots, calculate the average density in the samples, and extrapolate to
estimate the population size in the entire area.
°
Such
estimates are accurate when there are many sample plots and a homogeneous
habitat.
°
A
sampling technique that researchers commonly use to estimate wildlife
populations is the mark-recapture
method.
§
Individuals
are trapped and captured, marked with a tag, recorded, and then released.
§
After
a period of time has elapsed, traps are set again, and individuals are captured
and identified.
§
The
second capture yields both marked and unmarked individuals.
§
From
these data, researchers estimate the total number of individuals in the
population.
§
The
mark-recapture method assumes that each marked individual has the same
probability of being trapped as each unmarked individual.
§
This
may not be a safe assumption, as trapped individuals may be more or less likely
to be trapped a second time.
·
Density
results from dynamic interplay between processes that add individuals to a
population and those that remove individuals from it.
°
Additions
to a population occur through birth (including all forms of reproduction) and immigration (the influx of new
individuals from other areas).
°
The
factors that remove individuals from a population are death (mortality) and emigration (the movement of individuals
out of a population).
°
Immigration
and emigration may represent biologically significant exchanges between
populations.
·
Within
a population’s geographic range, local densities may vary substantially.
°
Variations
in local density are important population characteristics, providing insight
into the environmental and social interactions of individuals within a
population.
§
Some
habitat patches are more suitable that others.
§
Social
interactions between members of a population may maintain patterns of spacing.
·
Dispersion
is clumped when individuals aggregate
in patches.
°
Plants
and fungi are often clumped where soil conditions favor germination and growth.
°
Animals
may clump in favorable microenvironments (such as isopods under a fallen log)
or to facilitate mating interactions.
°
Group
living may increase the effectiveness of certain predators, such as a wolf
pack.
·
Dispersion
is uniform when individuals are
evenly spaced.
°
For
example, some plants secrete chemicals that inhibit the germination and growth
of nearby competitors.
°
Animals
often exhibit uniform dispersion as a result of territoriality, the defense of a bounded space against encroachment
by others.
·
In
random dispersion, the position of
each individual is independent of the others, and spacing is unpredictable.
°
Random
dispersion occurs in the absence of strong attraction or repulsion among
individuals in a population, or when key physical or chemical factors are
relatively homogeneously distributed.
°
For
example, plants may grow where windblown seeds land.
°
Random
patterns are not common in nature.
Demography is the study of factors that affect
population density and dispersion patterns.
·
Demography is the study of the vital
statistics of populations and how they change over time.
·
Of
particular interest are birth rates and how they vary among individuals
(specifically females), and death rates.
·
A
life table is an age-specific
summary of the survival pattern of a population.
·
The
best way to construct a life table is to follow the fate of a cohort, a group of individuals of the
same age, from birth throughout their lifetimes until all are dead.
·
To
build a life table, we need to determine the number of individuals that die in
each age group and calculate the proportion of the cohort surviving from one
age to the next.
·
A
graphic way of representing the data in a life table is a survivorship curve.
°
This
is a plot of the numbers or proportion of individuals in a cohort of 1,000
individuals still alive at each age.
°
There
are several patterns of survivorship exhibited by natural populations.
°
A
Type I curve is relatively flat at the start, reflecting a low death rate in
early and middle life, and drops steeply as death rates increase among older
age groups.
§
Humans
and many other large mammals exhibit Type I survivorship curves.
°
The
Type II curve is intermediate, with constant mortality over an organism’s life
span.
§
Many
species of rodent, various invertebrates, and some annual plants show Type II
survivorship curves.
°
A
Type III curve drops slowly at the start, reflecting very high death rates
early in life, then flattens out as death rates decline for the few individuals
that survive to a critical age.
§
Type
III survivorship curves are associated with organisms that produce large
numbers of offspring but provide little or no parental care.
§
Examples
are many fishes, long-lived plants, and marine invertebrates.
·
Many
species fall somewhere between these basic types of survivorship curves or show
more complex curves.
°
Some
invertebrates, such as crabs, show a “stair-stepped” curve, with increased
mortality during molts.
·
Reproductive
rates are key to population size in populations without immigration or
emigration.
°
Demographers
who study sexually reproducing populations usually ignore males and focus on
females because only females give birth to offspring.
°
A
reproductive table is an
age-specific summary of the reproductive rates in a population.
§
The
best way to construct a reproductive table is to measure the reproductive
output of a cohort from birth until death.
§
For
sexual species, the table tallies the number of female offspring produced by
each age group.
§
Reproductive
output for sexual species is the product of the proportion of females of a
given age that are breeding and the number of female offspring of those
breeding females.
°
Reproductive
tables vary greatly from species to species.
§
Squirrels
have a litter of two to six young once a year for less than a decade, while
mussels may release hundreds of thousands of eggs in a spawning cycle.
Concept 52.2 Life history traits are products of natural selection
·
Natural
selection favors traits that improve an organism’s chances of survival and
reproductive success.
·
In
every species, there are trade-offs between survival and traits such as
frequency of reproduction, number of offspring produced, and investment in
parental care.
·
The
traits that affect an organism’s schedule of reproduction and survival make up
its life history.
Life histories are highly diverse, but they
exhibit patterns in their variability.
·
Life
histories entail three basic variables: when reproduction begins, how often the
organism reproduces, and how many offspring are produced during each
reproductive episode.
·
Life
history traits are evolutionary outcomes reflected in the development,
physiology, and behavior of an organism.
·
Some
organisms, such as the agave plant, exhibit what is known as big-bang reproduction, in which an
individual produces a large number of offspring and then dies.
°
This
is known as semelparity.
·
By
contrast, some organisms produce only a few offspring during repeated reproductive episodes.
°
This
is known as iteroparity.
·
What
factors contribute to the evolution of semelparity versus iteroparity?
·
In
other words, how much does an individual gain in reproductive success through
one pattern versus the other?
°
The
critical factor is survival rate of the offspring.
°
When
the survival of offspring is low, as in highly variable or unpredictable
environments, big-bang reproduction (semelparity) is favored.
°
Repeated
reproduction (iteroparity) is favored in dependable environments where
competition for resources is intense.
§
In
such environments, a few, well-provisioned offspring have a better chance of
surviving to reproductive age.
Limited resources mandate trade-offs
between investment in reproduction and survival.
·
Organisms
have finite resources, and limited resources mean trade-offs.
·
Life
histories represent an evolutionary resolution of several conflicting demands.
°
Sometimes
we see trade-offs between survival and reproduction when resources are limited.
°
For
example,
·
Selective
pressures also influence the trade-off between number and size of offspring.
°
Plants
and animals whose young are subject to high mortality rates often produce large
numbers of relatively small offspring.
§
Plants
that colonize disturbed environments usually produce many small seeds, only a
few of which reach suitable habitat.
§
Smaller
seed size may increase the chance of seedling establishment by enabling seeds
to be carried longer distances to a broader range of habitats.
°
In
other organisms, extra investment on the part of the parent greatly increases
the offspring’s chances of survival.
§
Oak,
walnut, and coconut trees all have large seeds with a large store of energy and
nutrients to help the seedlings become established.
°
In
animals, parental care does not always end after incubation or gestation.
°
Primates
provide an extended period of parental care.
Concept 52.3 The exponential model describes
population growth in an idealized, unlimited environment
·
All
populations have a tremendous capacity for growth.
·
However,
unlimited population increase does not occur indefinitely for any species,
either in the laboratory or in nature.
·
The
study of population growth in an idealized, unlimited environment reveals the
capacity of species for increase and the conditions in which that capacity may
be expressed.
·
Imagine
a hypothetical population living in an ideal, unlimited environment.
·
For
simplicity’s sake, we will ignore immigration and emigration and define a
change in population size during a fixed time interval based on the following
verbal equation.
Change
in population size =
Births during − Deaths during
during time interval time
interval time interval
·
Using
mathematical notation, we can express this relationship more concisely:
°
If
N represents population size, and t represents time, then DN
is the change is population size and Dt
is the time interval.
°
We
can rewrite the verbal equation as:
DN/Dt
= B − D where B is the number
of births and D is the number of
deaths.
·
We
can convert this simple model into one in which births and deaths are expressed
as the average number of births and deaths per individual during the specified
time period.
·
The
per capita birth rate is the number
of offspring produced per unit time by an average member of the population.
°
If
there are 34 births per year in a population of 1,000 individuals, the annual
per capita birth rate is 34/1000, or 0.034.
·
If
we know the annual per capita birth rate (expressed as b), we can use the formula B
= bN to calculate the expected number
of births per year in a population of any size.
·
Similarly,
the per capita death rate (symbolized
by m for mortality) allows us to
calculate the expected number of deaths per unit time for a population of any
size.
·
Now
we will revise the population growth equation, using per capita birth and death
rates:
DN/Dt
= bN − mN
·
Population
ecologists are most interested in the differences between the per capita birth
rate and the per capita death rate.
°
This
difference is the per capita rate of
increase or r, which equals b − m.
·
The
value of r indicates whether a
population is growing (r > 0) or
declining (r < 0).
·
If
r = 0, then there is zero population growth (ZPG).
°
Births
and deaths still occur, but they balance exactly.
·
Using
the per capita rate of increase, we rewrite the equation for change in
population size as:
DN/Dt
= rN
·
Ecologist
use differential calculus to express population growth as growth rate at a
particular instant in time:
dN/dt =
rN
·
Population
growth under ideal conditions is called exponential
population growth.
°
Under
these conditions, we may assume the maximum growth rate for the population (rmax), called the intrinsic rate of increase.
°
The
equation for exponential population growth is:
dN/dt = rmaxN
·
The
size of a population that is growing exponentially increases at a constant
rate, resulting in a J-shaped growth curve when the population size is plotted
over time.
°
Although
the intrinsic rate of increase is
constant, the population accumulates more new individuals per unit of time when
it is large.
°
As
a result, the curve gets steeper over time.
·
A
population with a high intrinsic rate of increase grows faster than one with a
lower rate of increase.
·
J-shaped
curves are characteristic of populations that are introduced into a new or
unfilled environment or whose numbers have been drastically reduced by a
catastrophic event and are rebounding.
Concept 52.4 The logistic growth model includes
the concept of carrying capacity
·
Typically,
resources are limited.
·
As
population density increases, each individual has access to an increasingly
smaller share of available resources.
·
Ultimately,
there is a limit to the number of individuals that can occupy a habitat.
°
Ecologists
define carrying capacity (K) as the maximum stable population size
that a particular environment can support.
°
Carrying
capacity is not fixed but varies over space and time with the abundance of
limiting resources.
·
Energy
limitation often determines carrying capacity, although other factors, such as
shelters, refuges from predators, soil nutrients, water, and suitable nesting
sites can be limiting.
·
If
individuals cannot obtain sufficient resources to reproduce, the per capita
birth rate b will decline.
·
If
they cannot find and consume enough energy to maintain themselves, the per
capita death rate m may increase.
°
A
decrease in b or an increase in m results in a lower per capita rate of
increase r.
·
We
can modify our mathematical model to incorporate changes in growth rate as the
population size nears the carrying capacity.
·
In
the logistic population growth
model, the per capita rate of increase declines as carrying capacity is
reached.
·
Mathematically,
we start with the equation for exponential growth, adding an expression that
reduces the rate of increase as N
increases.
·
If
the maximum sustainable population size (carrying capacity) is K, then K − N is the number of additional individuals the environment can
accommodate and (K − N)/K
is the fraction of K that is still
available for population growth.
·
By
multiplying the intrinsic rate of increase rmax
by (K − N)/K, we modify the
growth rate of the population as N
increases.
°
dN/dt
= rmaxN((K − N)/K)
°
When
N is small compared to K, the term (K − N)/K is large and the per capita
rate of increase is close to the intrinsic rate of increase.
°
When
N is large and approaches K, resources are limiting.
§
In
this case, the term (K − N)/K
is small and so is the rate of population growth.
·
Population
growth is greatest when the population is approximately half of the carrying
capacity.
°
At
this population size, there are many reproducing individuals, and the per
capita rate of increase remains relatively high.
·
The
logistic model of population growth produces a sigmoid (S-shaped) growth curve
when N is plotted over time.
°
New
individuals are added to the population most rapidly at intermediate population
sizes, when there is not only a breeding population of substantial size, but
also lots of available space and other resources in the population.
°
Population
growth rate slows dramatically as N
approaches K.
·
How
well does the logistic model fit the growth of real populations?
°
The
growth of laboratory populations of some organisms fits an S-shaped curve
fairly well.
°
These
populations are grown in a constant environment without predators or
competitors.
·
Some
of the assumptions built into the logistic model do not apply to all
populations.
·
The
logistic model assumes that populations adjust instantaneously and approach the
carrying capacity smoothly.
°
In
most natural populations, there is a lag time before the negative effects of
increasing population are realized.
°
Populations
may overshoot their carrying capacity before settling down to a relatively
stable density.
·
Some
populations fluctuate greatly, making it difficult to define the carrying
capacity.
·
The
logistic model assumes that regardless of population density, an individual
added to the population has the same negative effect on population growth rate.
°
Some
populations show an Allee effect, in
which individuals may have a more difficult time surviving or reproducing if
the population is too small.
°
Animals
may not be able to find mates in the breeding season at small population sizes.
°
A
plant may be protected in a clump of individuals but vulnerable to excessive
wind if it stands alone.
·
The
logistic population growth model provides a basis from which we can consider
how real populations grow and can construct more complex models.
°
The
model is useful in conservation biology for estimating how rapidly a particular
population might increase in numbers after it has been reduced to a small size,
or for estimating sustainable harvest rates for fish or wildlife populations.
·
The
logistic model predicts different per capita growth rates for populations of
low or high density relative to carrying capacity of the environment.
°
At
high densities, each individual has few resources available, and the population
grows slowly.
°
At
low densities, per capita resources are abundant, and the population can grow
rapidly.
·
Different
life history features are favored under each condition.
°
At
high population density, selection favors adaptations that enable organisms to survive
and reproduce with few resources.
§
Competitive
ability and efficient use of resources should be favored in populations that
are at or near their carrying capacity.
§
These
are traits associated with iteroparity.
°
At
low population density, adaptations that promote rapid reproduction, such as
the production of numerous, small offspring, should be favored.
§
These
are traits associated with semelparity.
°
Ecologists
have attempted to connect these differences in favored traits at different
population densities with the logistic model of population growth.
§
Selection
for life history traits that are sensitive to population density is known as K-selection,
or density-dependent selection.
à
K-selection tends to
maximize population size and operates in populations living at a density near K.
§
Selection
for life history traits that maximize reproductive success at low densities is
known as r-selection, or density-independent selection.
à
r-selection tends to
maximize r, the rate of increase, and
occurs in environments in which population densities fluctuate well below K, or when individuals face little
competition.
°
Laboratory
experiments suggest that different populations of the same species may show a
different balance of K-selected and r-selected traits, depending on conditions.
°
Many
ecologists claim that the concepts of r-
and K-selection oversimplify the
variation seen in natural populations.
Concept 52.5 Populations are regulated by a complex interaction of
biotic and abiotic influences
·
Why
do all populations eventually strop growing?
·
What
environmental factors stop a population from growing?
·
Why
do some populations show radical fluctuations in size over time, while others
remain relatively stable?
·
These
questions have practical applications at the core of management programs for
agricultural pests or endangered species.
·
The
first step to answering these questions is to examine the effects of increased
population density on rates of birth, death, immigration, and emigration.
·
Density-dependent factors have an increased
effect on a population as population density increases.
°
This
is a type of negative feedback.
·
Density-independent factors are unrelated to
population density.
Negative feedback prevents unlimited
population growth.
·
A
variety of factors can cause negative feedback on population growth.
·
Resource
limitation in crowded populations can reduce population growth by reducing
reproductive output.
°
Intraspecific
competition for food can lead to declining birth rates.
·
In
animal populations, territoriality may limit density.
°
In
this case, territory space becomes the resource for which individuals compete.
°
The
presence of nonbreeding individuals in a population is an indication that
territoriality is restricting population growth.
·
Population
density can also influence the health and thus the survival of organisms.
°
As
crowding increases, the transmission rate of a disease may increase.
°
Tuberculosis,
caused by bacteria that spread through the air when an infected person coughs
or sneezes, affects a higher percentage of people living in high-density cities
than in rural areas.
·
Predation
may be an important cause of density-dependent mortality for a prey species if
a predator encounters and captures more food as the population density of the
prey increases.
°
As
a prey population builds up, predators may feed preferentially on that species,
consuming a higher percentage of individuals.
·
The
accumulation of toxic wastes can contribute to density-dependent regulation of
population size.
°
In
wine, as yeast population increases, they accumulate alcohol during
fermentation.
°
However,
yeast can only withstand an alcohol percentage of approximately 13% before they
begin to die.
·
For
some animal species, intrinsic factors appear to regulate population size.
°
White-footed
mice individuals become more aggressive as population size increases, even when
food and shelter are provided in abundance.
°
Eventually
the population ceases to grow.
°
These
behavioral changes may be due to hormonal changes, which delay sexual
maturation and depress the immune system.
·
All
populations for which we have data show some fluctuation in numbers.
·
The
study of population dynamics focuses
on the complex interactions between biotic and abiotic factors that cause
variation in population size.
·
Populations
of large mammals, such as deer and moose, were once thought to remain
relatively stable over time.
°
A
long-term population study of a moose population on
°
The
population has had two major increases and collapses over the past 40 years.
·
Large
mammal populations do show much more stability than other populations.
°
Dungeness
crab populations fluctuated hugely over a 40-year period.
°
One
key factor causing these fluctuations is cannibalism.
§
Large
numbers of juveniles are eaten by older juveniles and older crabs.
°
In
addition, successful settlement of crabs is dependent on water temperatures and
ocean currents.
§
Small
changes in these variables cause large fluctuations in crab population numbers.
·
Immigration
and emigration can also influence populations.
°
This
is particularly true when a group of populations is linked together to form a metapopulation.
·
Some
populations undergo regular boom-and-bust cycles, fluctuating in density with
regularity.
°
For
example, voles and lemmings tend to have 3- to 4-year cycles.
°
Ruffled
grouse and ptarmigan have 9- to 11-year cycles.
·
A
striking example of population cycles is the 10-year cycles of lynx and
snowshoe hare in northern
·
Three
main hypotheses have been proposed to explain the lynx/hare cycles.
1. The cycles may be caused
by food shortage during winter.
2. The cycles may be due to
predator-prey interactions.
3. The cycles may be affected
by a combination of food resource limitation and excessive predation.
·
If
hare cycles are due to winter food shortage, they should stop if extra food is
added to a field population.
·
Researchers
conducted such an experiment over 20 years.
·
They
found that hare populations increased, but that populations of lynx and hares
continued to cycle.
·
The
first hypothesis can be discarded.
·
Field
ecologists have placed radio collars on hares, to find them as they die and
determine the cause of death.
·
90%
of dead hares were killed by predators; none appear to have died of starvation.
·
These
data support the second or third hypothesis.
·
Ecologists
tested these hypotheses by excluding predators from one area and by both
excluding predators and adding food to another area.
·
The
results support the hypothesis that the hare cycle is driven largely by
predation but that food availability also plays an important role, especially
in winter.
·
Perhaps
better-fed hares are more likely to escape from predators.
·
Many
different predators contribute to these cycles, not only lynx.
·
Long-term
experimental studies continue to be conducted to help unravel the complex
causes of these population cycles.
Concept 52.6 Human population growth has slowed after centuries of
exponential increase
·
The
concepts of population dynamics can be applied to the specific case of the
human population.
·
It
is unlikely that any other population of large animals has ever sustained so
much population growth for so long.
·
The
human population increased relatively slowly until about 1650 when
approximately 500 million people inhabited Earth.
·
The
Plague took a large number of lives.
·
Since
then, human population numbers have doubled three times.
·
The
global population now numbers more than 6 billion people, and is increasing by
about 73 million each year, or 201,000 people each day.
·
Population
ecologists predict a population of 7.3–8.4 billion people on Earth by the year
2025.
·
Although
the global population is still growing, the rate
of growth began to slow approximately 40 years ago.
°
The
rate of increase in the global population peaked at 2.19% in 1962.
°
By
2003, it had declined to 1.16%.
·
Current
models project a decline in overall growth rate to just over 0.4% by 2050.
·
Human
population growth has departed from true exponential growth, which assumes a
constant rate.
·
The
declines are the result of fundamental changes in population dynamics due to diseases
and voluntary population control.
·
To
maintain population stability, a regional human population can exist in one of
2 configurations:
Zero
population growth = High birth rates − High death
rates.
Zero
population growth = Low birth rates − Low death
rates.
·
The
movement from the first toward the second state is called the demographic transition.
·
After
1950, mortality rates declined rapidly in most developing countries.
°
Birth
rates have declined in a more variable manner.
·
In
the developed nations, populations are near equilibrium, with reproductive
rates near the replacement level.
·
In
many developed nations, the reproductive rates are in fact below replacement level.
·
These
populations will eventually decline if there is no immigration and no change in
birth rate.
·
Most
population growth is concentrated in developing countries, where 80% of the
world’s people live.
·
A
unique feature of human population growth is the ability to control it with
family planning and voluntary contraception.
°
Reduced
family size is the key to the demographic transition.
°
Delayed
marriage and reproduction help to decrease population growth rates and move a
society toward zero population growth.
·
However,
there is disagreement among world leaders as to how much support should be provided
for global family planning efforts.
·
One
important demographic variable is a country’s age structure.
·
Age
structure is shown as a pyramid showing the percentage of the population at
each age.
°
Age
structure differs greatly from nation to nation.
°
Age
structure diagrams can predict a population’s growth trends and can point to
future social conditions.
·
Infant mortality, the number of infant
deaths per 1,000 live births, and life
expectancy at birth, the predicted average length of life at birth, also
vary widely among different human populations.
°
These
differences reflect the quality of life faced by children at birth.
Estimating Earth’s carrying capacity for
humans is a complex problem.
·
Predictions
of future human population vary from 7.3 to 10.3 billion people by the year
2050.
°
Will
Earth be overpopulated by this time?
°
Is
it already overpopulated?
°
What
is the carrying capacity of Earth for humans?
§
This
question is difficult to answer.
§
Estimates
of the answer have ranged from less than 1 billion to more than 1 trillion.
°
Carrying
capacity is difficult to estimate, and scientists have used different methods
to obtain their answers.
§
Some
use curves like those produced by the logistic equation to predict the future
maximum human population size.
§
Others
generalize from existing “maximum” population density and multiply by the area
of habitable land.
§
Other
estimates are based on a single limiting factor, usually food.
·
Humans
have multiple constraints. We need food, water, fuel, building materials, and
other amenities.
·
The
concept of an ecological footprint
summarizes the aggregate land and water area appropriated by each nation to
produce all the resources it consumes and to absorb all the waste it generates.
·
Six
types of ecologically productive areas are distinguished in calculating the
ecological footprint:
1. Arable land (suitable for
crops)
2. Pasture
3.
4. Ocean
5. Built-up land
6. Fossil energy land (land
required for vegetation to absorb the carbon dioxide absorbed by burning fossil
fuels)
·
Countries
vary greatly in their individual footprint size and in their available ecological capacity (the actual
resource base of each country).
·
The
overall analysis of human impact via ecological footprints suggests that the
world is at or slightly above its carrying capacity.
·
We
can only speculate about Earth’s ultimate carrying capacity for humans, or
about the factors that will eventually limit our growth.
°
Perhaps
food will be the main factor.
°
Malnutrition
and famine result mainly from unequal distribution, rather than inadequate
production, of food.
°
So
far, technological improvements in agriculture have allowed food supplies to
keep up with global population growth.
§
Environments
can support a larger number of herbivores than carnivores.
°
Perhaps
we will eventually be limited by suitable space.
°
Humans
may run out of nonrenewable resources, such as certain metals or fossil fuels.
°
The
demands of many populations have already far exceeded the local and regional
supplies of water.
§
More
than one billion people lack access to sufficient water for basic sanitation.
°
It
is possible that the human population will eventually be limited by the
capacity of the environment to absorb its wastes.
·
Some
optimists suggest that there is no practical limit to human population growth,
due to our ability to develop technology.
·
Exactly
what the world’s carrying capacity is, and when and how we will approach it,
are topics of great concern and debate.
·
Unlike
other organisms, we can decide whether zero population growth will be attained
through social changes based on human choices or increased mortality due to
resource limitation, war, or environmental degradation.