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Population Ecology

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Title: Population Ecology


1
Population Ecology
  • AP Chap 53

2
  • Population ecology is the study of populations in
    relation to environment, including environmental
    influences on density and distribution, age
    structure, and population size

3
Fig. 53-1
A population is a group of individuals of a
single species living in the same general area
4
Every population has geographic boundaries.
  • Density is the number of individuals per unit
    area or volume
  • Dispersion is the pattern of spacing among
    individuals within the boundaries of the
    population

5
Population density is often determined by
sampling techniques
  • Population size can be estimated by
  • Direct counting
  • Random sampling based on sample plots (quadrats)
  • Indexes such as tracks, nests, burrows, fecal
    droppings, etc.
  • Mark and recapture method

6
Quadrat sampling
7
Mark-recapture Method
8
Mark-Recapture Formula for estimating population
size
  • Estimate of Total Population   
  • (total number recaptured) x (number marked)
  • (total number recaptured with mark)

9
  • In a mark-recapture study, an ecologist traps,
    marks and releases 25 voles in a small wooded
    area. A week later she resets her traps and
    captures 30 voles, 10 of which are marked. What
    is her estimate of the vole population in that
    area?

10
How does population density change?
  • Addition birth, immigration
  • Removal death, emigration

11
Fig. 53-3
Births
Deaths
Births and immigration add individuals to a
population.
Deaths and emigration remove individuals from a
population.
Immigration
Emigration
12
Patterns of Dispersion
  • Environmental and social factors influence
    spacing of individuals in a population
  • In a clumped dispersion, individuals aggregate in
    patches
  • A clumped dispersion may be influenced by
    resource availability and behavior

13
Fig. 53-4a
(a) Clumped
14
UNIFORM
  • A uniform dispersion is one in which individuals
    are evenly distributed
  • It may be influenced by social interactions such
    as territoriality

15
Fig. 53-4b
(b) Uniform
16
RANDOM
  • In a random dispersion, the position of each
    individual is independent of other individuals
  • It occurs in the absence of strong attractions or
    repulsions

17
Fig. 53-4c
(c) Random
18
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19
Demographics
  • Demography is the study of the vital statistics
    (death and birth rates) of a population and how
    they change over time
  • Death rates and birth rates are of particular
    interest to demographers
  • A life table is an age-specific summary of the
    survival pattern of a population
  • It is best made by following the fate of a
    cohort, a group of individuals of the same age

20
Table 53-1
The life table of Beldings ground squirrels
reveals many things about this population
21
Survivorship Curves
  • A survivorship curve is a graphic way of
    representing the data in a life table
  • The survivorship curve for Beldings ground
    squirrels shows a relatively constant death rate

22
Fig. 53-5
1,000
100
Number of survivors (log scale)
Females
10
Males
1
2
0
4
8
6
10
Age (years)
23
  • Survivorship curves can be classified into three
    general types
  • Type I low death rates during early and middle
    life, then an increase among older age groups
  • Type II the death rate is constant over the
    organisms life span
  • Type III high death rates for the young, then a
    slower death rate for survivors

24
Fig. 53-6
More parental care, better health care
1,000
I
Predation, accidents, disease at all levels
100
II
Number of survivors (log scale)
10
High mortality of many offspring
III
1
0
50
100
Percentage of maximum life span
25
What type of survivorship curve?
Type 2
Type 3
Type 1
26
Reproductive tables focus on female
reproductivity.
Table 53-2
27
Life history traits are products of natural
selection
  • An organisms life history comprises the traits
    that affect its schedule of reproduction and
    survival
  • The age at which reproduction begins
  • How often the organism reproduces
  • How many offspring are produced during each
    reproductive cycle

28
  • Species that exhibit semelparity, or big-bang
    reproduction, reproduce once and die
  • Species that exhibit iteroparity, or repeated
    reproduction, produce offspring repeatedly
  • Highly variable or unpredictable environments
    likely favor big-bang reproduction, while
    dependable environments may favor repeated
    reproduction.

29
Trade-offs and Life Histories
  • Organisms have finite resources, which may lead
    to trade-offs between survival and reproduction
  • Examples
  • brood size vs parental life span
  • number of seeds and chance of gemination and
    growth

30
Fig. 53-8
RESULTS
100
Male
Female
80
60
Parents surviving the following winter ()
40
20
0
Reduced brood size
Normal brood size
Enlarged brood size
31
Fig. 53-9
Some plants produce a large number of small
seeds, ensuring that at least some of them will
grow and eventually reproduce
(a) Dandelion
Other types of plants produce a moderate number
of large seeds that provide a large store of
energy that will help seedlings become
established
(b) Coconut palm
32
In what way might high competition for limited
resources in a predictable environment influence
the evolution of life history traits? Semelparity
or iteroparity
  • Selection would most likely favor iteroparity,
    with fewer, larger, better-provisioned or
    cared-for offspring.

33
How do we model population growth?
  • By construction graphs and using mathematical
    formulas
  • If immigration and emigration are ignored, a
    populations growth rate (per capita increase)
    equals birth rate minus death rate
  • r b - d

34
  • Zero population growth occurs when the birth rate
    equals the death rate
  • Most ecologists use differential calculus to
    express population growth as growth rate at a
    particular instant in time

where N population size, t time, and r per
capita rate of increase
35
Exponential Growth
  • Exponential population growth is population
    increase under idealized. unlimited conditions
  • Under these conditions, the rate of reproduction
    is at its maximum, called the intrinsic rate of
    increase

36
  • Equation of exponential population growth

Exponential population growth results in a
J-shaped curve.
37
Fig. 53-10
2,000
dN
1.0N

dt
1,500
dN
0.5N

dt
Population size (N)
1,000
500
0
0
5
10
15
Number of generations
38
Fig. 53-11
The J-shaped curve of exponential growth
characterizes some rebounding populations.
8,000
6,000
Elephant population
4,000
Elephants in Kruger National Park in S. Africa
after they were protected from hunting.
2,000
0
1920
1940
1960
1980
1900
Year
39
But, is this the normal state of population
growth?
  • Exponential growth cannot be sustained for long
    in any population
  • A more realistic population model limits growth
    by incorporating carrying capacity
  • Carrying capacity (K) is the maximum population
    size the environment can support

40
The Logistic Growth Model
  • In the logistic population growth model, the per
    capita rate of increase declines as carrying
    capacity is reached
  • We construct the logistic model by starting with
    the exponential model and adding an expression
    that reduces per capita rate of increase as N
    approaches K.

41
Table 53-3
As N approaches K, rate nears 0.
42
  • The logistic model of population growth produces
    a sigmoid (S-shaped) curve

43
Fig. 53-12
Exponential growth
2,000
K
dN
1.0N

dt
1,500
K 1,500
Population size (N)
Logistic growth
1,000
1,500 N
dN
1.0N

1,500
dt
500
0
0
5
10
15
Number of generations
44
Fig. 53-13a
Some populations overshoot K before settling down
to a relatively stable density
1,000
800
These organisms are grown in a constant
environment lacking predators and competitors
Number of Paramecium/mL
600
400
200
0
0
5
10
15
Time (days)
(a) A Paramecium population in the lab
45
Fig. 53-13b
Some populations fluctuate greatly and make it
difficult to define K.
180
150
120
Number of Daphnia/50 mL
90
60
30
0
0
20
40
60
80
100
120
140
160
Time (days)
(b) A Daphnia population in the lab
46
  • Some populations show an Allee effect, in which
    individuals have a more difficult time surviving
    or reproducing if the population size is too
    small

47
The Logistic Model and Life Histories
  • Natural selection shapes the final life history
    of individual species.
  • Some members of populations are subject to
    r-selection and some to k-selection.
  • When population size is low relative to K,
  • r-selection favors r-strategies
  • high fecundity (ability to reproduce),
  • small body size,
  • early maturity onset,
  • short generation time, and
  • the ability to disperse offspring widely.

48
Characteristics of r - Selected Opportunists
  • Very high intrinsic rate of increase.
  • Opportunistic
  • Populations can expand rapidly to take advantage
    of temporarily favorable conditions
  • Ex Bacteria, some fungi, many insects, rodents,
    weeds, and annual plants.

49
  • In environments that are relatively stable and
    populations tend to be near K, with minimal
    fluctuations in population size, K-selection
    favors K strategies large body size, long life
    expectancy, and the production of fewer offspring
    that require extensive parental care until they
    mature.
  • These populations are strong competitors.
  • They are specialists rather than colonists and
    may become extinct if their normal way of life is
    destroyed.

50
Characteristics of K - Selected Species
  • Population responds slowly, usually with negative
    feedback control so that constancy is the rule.
  • Their numbers are controlled by the availability
    of resources. In other words, they are a density
    dependent species

Most birds
Most predators
Elephants
Whales
Oaks
Chestnuts
Apple
Coconut
51
r or k-selected?
  • Nature is more complex though and most
    populations lie somewhere in between these two
    extremes.
  • Ex- Gymnosperms and angiosperms are typically
    classified as K-strategists but they release many
    seeds.
  • Cod fish are large fish but
  • release large numbers of
  • gametes into the sea with
  • no parental investment.
  • So, cod are considered
  • r-strategists.

52
K or r-selected ?
  • When a farmer abandons a field, it is quickly
    colonized by fast-growing weeds. Are these
    species more likely to be K-selected or
    r-selected species?

r
53
What about the bluegill fish?
  • Bluegill exhibit one of the most social and
    complex mating systems in nature. Parental males
    delay maturation and compete to construct nests
    in colonies, court females, and provide sole
    parental care for the young within their nest.

54
Many factors that regulate population growth are
density dependent
  • There are two general questions about regulation
    of population growth
  • What environmental factors stop a population from
    growing indefinitely?
  • Why do some populations show radical fluctuations
    in size over time, while others remain stable?

55
Population Change and Population Density
  • In density-independent populations, birth rate
    and death rate do not change with population
    density
  • In density-dependent populations, birth rates
    fall and death rates rise with population density

56
Fig. 53-15
Density-dependent birth rate
Density-dependent birth rate
Density- independent death rate
Density- dependent death rate
Birth or death rate per capita
Equilibrium density
Equilibrium density
Population density
Population density
(a) Both birth rate and death rate vary.
(b) Birth rate varies death rate is constant.
Density-dependent death rate
Density- independent birth rate
Birth or death rate per capita
Equilibrium density
Population density
(c) Death rate varies birth rate is constant.
57
So, to determine if the environmental factor is
density dependent or independent.
  • Density-independent factors may affect all
    individuals in a population equally
  • rainfall, temperature, humidity, acidity,
    salinity, catastrophic events

58
  • Density-dependent factors have a greater affect
    when the population density is higher.

Food supply, disease, parasites, competition,
predation
59
Density-Dependent Population Regulation
  • Density-dependent birth and death rates are an
    example of negative feedback that regulates
    population growth
  • They are affected by many factors, such as
    competition for resources, territoriality,
    disease, predation, toxic wastes, and intrinsic
    factors

60
Fig. 53-17a
In many vertebrates and some invertebrates,
competition for territory may limit
density Cheetahs are highly territorial, using
chemical communication to warn other cheetahs of
their boundaries
(a) Cheetah marking its territory
61
Fig. 53-17b
  • Oceanic birds exhibit territoriality in nesting
    behavior

(b) Gannets
62
Disease
  • Population density can influence the health and
    survival of organisms
  • In dense populations, pathogens can spread more
    rapidly

63
Predation
  • As a prey population builds up, predators may
    feed preferentially on that species

64
Toxic Wastes
  • Accumulation of toxic wastes can contribute to
    density-dependent regulation of population size

65
Intrinsic Factors
  • For some populations, intrinsic (physiological)
    factors appear to regulate population size

66
Population Dynamics
  • The study of population dynamics focuses on the
    complex interactions between biotic and abiotic
    factors that cause variation in population size
  • Long-term population studies have challenged the
    hypothesis that populations of large mammals are
    relatively stable over time
  • Weather can affect population size over time

67
Fig. 53-18
2,100
1,900
1,700
1,500
1,300
Number of sheep
1,100
900
700
500
0
1955
1965
1975
1985
1995
2005
Year
68
Fig. 53-19
2,500
50
Wolves
Moose
2,000
40
1,500
30
Number of moose
Number of wolves
1,000
20
500
10
0
0
1955
1965
1975
1985
1995
2005
Year
Changes in predation pressure can drive
population fluctuations
69
Population Cycles Scientific Inquiry
  • Some populations undergo regular boom-and-bust
    cycles
  • Lynx populations follow the 10 year boom-and-bust
    cycle of hare populations
  • Three hypotheses have been proposed to explain
    the hares 10-year interval
  • - winter food supply
  • - predators
  • - sunspot activity (quality of food)
  • affected cycles

70
Fig. 53-20
Snowshoe hare
160
120
9
Lynx
Number of lynx (thousands)
Number of hares (thousands)
80
6
40
3
0
0
1850
1875
1900
1925
Year
71
The human population is no longer growing
exponentially but is still increasing rapidly
  • No population can grow indefinitely, and humans
    are no exception

72
Fig. 53-22
7
6
The human population increased relatively slowly
until about 1650 and then began to grow
exponentially
5
4
Human population (billions)
3
2
The Plague
1
0
8000 B.C.E.
4000 B.C.E.
3000 B.C.E.
2000 B.C.E.
1000 B.C.E.
0
1000 C.E.
2000 C.E.
73
Fig. 53-23
2.2
2.0
1.8
1.6
1.4
2005
1.2
Annual percent increase
Projected data
1.0
0.8
Though the global population is still growing,
the rate of growth began to slow during the 1960s
0.6
0.4
0.2
0
1950
1975
2000
2025
2050
Year
74
Regional Patterns of Population Change
  • To maintain population stability, a regional
    human population can exist in one of two
    configurations
  • Zero population growth High birth rate High
    death rate
  • Zero population growth Low birth rate Low
    death rate
  • The demographic transition is the move from the
    first state toward the second state

75
Fig. 53-24
The demographic transition in Sweden took about
150 years, from 1810 to 1960. It will take about
the same length of time for Mexico.
50
40
30
Birth or death rate per 1,000 people
20
10
Sweden
Mexico
Birth rate
Birth rate
Death rate
Death rate
0
1750
1800
1900
1950
2000
2050
1850
Year
76
  • The demographic transition is associated with an
    increase in the quality of health care and
    improved access to education, especially for
    women
  • Most of the current global population growth is
    concentrated in developing countries

77
Age Structure
  • One important demographic factor in present and
    future growth trends is a countrys age structure
  • Age structure is the relative number of
    individuals at each age
  • Age structure diagrams can predict a populations
    growth trends
  • They can illuminate social conditions and help us
    plan for the future

78
Fig. 53-25
Rapid growth
Slow growth
No growth
Afghanistan
United States
Italy
Male
Female
Age
Age
Male
Female
Male
Female
85
85
8084
8084
7579
7579
7074
7074
6569
6569
6064
6064
5559
5559
5054
5054
4549
4549
4044
4044
3539
3539
3034
3034
2529
2529
2024
2024
1519
1519
1014
1014
59
59
04
04
10 
10 
8
8
6
6
4
4
2
2
0
6
6
4
4
2
2
0
8
8
6
6
4
4
2
2
0
8
8
Percent of population
Percent of population
Percent of population
79
Infant Mortality and Life Expectancy
  • Infant mortality and life expectancy at birth
    vary greatly among developed and developing
    countries but do not capture the wide range of
    the human condition

80
Fig. 53-26
60
80
50
60
40
Life expectancy (years)
Infant mortality (deaths per 1,000 births)
30
40
20
20
10
0
0
Less indus- trialized countries
Indus- trialized countries
Less indus- trialized countries
Indus- trialized countries
81
Global Carrying Capacity
  • How many humans can the biosphere support?
  • The carrying capacity of Earth for humans is
    uncertain
  • The average estimate is 1015 billion

82
Limits on Human Population Size
  • The ecological footprint concept summarizes the
    aggregate land and water area needed to sustain
    the people of a nation
  • It is one measure of how close we are to the
    carrying capacity of Earth
  • Countries vary greatly in footprint size and
    available ecological capacity

83
Fig. 53-27
Log (g carbon/year)
13.4
9.8
5.8
Not analyzed
84
  • Our carrying capacity could potentially be
    limited by food, space, nonrenewable resources,
    or buildup of wastes
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